============================================================
          |                                                          |
          |            Crystallography & NMR System (CNS)            |
          |                         CNSsolve                         |
          |                                                          |
          ============================================================
           Version: 1.2
           Status: Developmental version
          ============================================================
           Written by: A.T.Brunger, P.D.Adams, G.M.Clore, W.L.DeLano,
                       P.Gros, R.W.Grosse-Kunstleve, J.-S.Jiang,
                       J.Kuszewski, M.Nilges, N.S.Pannu, R.J.Read,
                       L.M.Rice, T.Simonson, G.L.Warren.
           Copyright (c) 1997-1999 Yale University
          ============================================================
           Running on machine: hostname unknown (x86_64/Linux,64-bit)
           Program started by: gliu
           Program started at: 14:05:09 on 13-Sep-2010
          ============================================================

 FFT3C: Using FFTPACK4.1

 CNSsolve> 
 CNSsolve>{+ directory: general +} 
 CNSsolve>{+ description: Generate structure file for protein, dna/rna, water, 
 CNSsolve>                ligands and/or carbohydrate +} 
 CNSsolve>{+ comment: 
 CNSsolve>           If required generate hydrogens. Any atoms with unknown 
 CNSsolve>           coordinates can be automatically generated +} 
 CNSsolve>{+ authors: Paul Adams and Axel Brunger +} 
 CNSsolve>{+ copyright: Yale University +} 
 CNSsolve> 
 CNSsolve>{- Guidelines for using this file: 
 CNSsolve>   - all strings must be quoted by double-quotes 
 CNSsolve>   - logical variables (true/false) are not quoted 
 CNSsolve>   - do not remove any evaluate statements from the file -} 
 CNSsolve> 
 CNSsolve>{- Special patches will have to be entered manually at the relevant points 
 CNSsolve>   in the file - see comments throughout the file -} 
 CNSsolve> 
 CNSsolve>{- begin block parameter definition -} define( 
 DEFINE> 
 DEFINE>{============================== important =================================} 
 DEFINE> 
 DEFINE>{* Coordinates for molecules of the same type (eg. all protein, all 
 DEFINE>   nucleic acid etc) can be input in the same coordinate file if the 
 DEFINE>   different chains are separated by a TER card or each chain has 
 DEFINE>   a different segid or chainid. *} 
 DEFINE> 
 DEFINE>{* A break in a chain can be detected automatically or should be delimited 
 DEFINE>   by a BREAK card. In this case no patch (head, tail or link) will be 
 DEFINE>   applied between the residues that bound the chain break. *} 
 DEFINE> 
 DEFINE>{* If a segid is present in the coordinate file it will be read unless 
 DEFINE>   segid renaming is used below. If renaming is used then all chains in a 
 DEFINE>   coordinate file will be given the same segid. *} 
 DEFINE> 
 DEFINE>{* If a PDB chain identifier is present in the coordinate file then this 
 DEFINE>   can be used for the segid *} 
 DEFINE> 
 DEFINE>{* NB. All input PDB files must finish with an END statement *} 
 DEFINE> 
 DEFINE>{============================ protein files ================================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* protein coordinate file *} 
 DEFINE>{===>} prot_coordinate_infile_1="template_hr44.pdb"; 
 DEFINE> 
 DEFINE>{* rename segid *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} prot_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} prot_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} prot_convert_1=false; 
 DEFINE> 
 DEFINE>{* separate chains by segid - a new segid starts a new chain *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} prot_separate_1=true; 
 DEFINE> 
 DEFINE>{========================= nucleic acid files ==============================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* nucleic acid coordinate file *} 
 DEFINE>{===>} nucl_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} nucl_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} nucl_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} nucl_convert_1=false; 
 DEFINE> 
 DEFINE>{* separate chains by segid - a new segid starts a new chain *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} nucl_separate_1=true; 
 DEFINE> 
 DEFINE>{============================= water files =================================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* water coordinate file *} 
 DEFINE>{===>} water_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} {+ choice: true false +} 
 DEFINE>{===>} water_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} water_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} {+ choice: true false +} 
 DEFINE>{===>} water_convert_1=false; 
 DEFINE> 
 DEFINE>{========================= carbohydrate files ==============================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* carbohydrate coordinate file *} 
 DEFINE>{===>} carbo_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} {+ choice: true false +} 
 DEFINE>{===>} carbo_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} carbo_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} {+ choice: true false +} 
 DEFINE>{===>} carbo_convert_1=false; 
 DEFINE> 
 DEFINE>{======================== prosthetic group files ===========================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* prosthetic group coordinate file *} 
 DEFINE>{===>} prost_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} {+ choice: true false +} 
 DEFINE>{===>} prost_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} prost_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} {+ choice: true false +} 
 DEFINE>{===>} prost_convert_1=false; 
 DEFINE> 
 DEFINE>{============================ ligand files =================================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* ligand coordinate file *} 
 DEFINE>{===>} lig_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} {+ choice: true false +} 
 DEFINE>{===>} lig_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} lig_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} {+ choice: true false +} 
 DEFINE>{===>} lig_convert_1=false; 
 DEFINE> 
 DEFINE>{============================== ions files =================================} 
 DEFINE> 
 DEFINE>{* Multiple coordinate files of the same type can be defined by duplicating 
 DEFINE>   all of the entries below and incrementing the file number *} 
 DEFINE> 
 DEFINE>{* ion coordinate file *} 
 DEFINE>{===>} ion_coordinate_infile_1=""; 
 DEFINE> 
 DEFINE>{* rename segid *} {+ choice: true false +} 
 DEFINE>{===>} ion_rename_1=false; 
 DEFINE> 
 DEFINE>{* new segid *} 
 DEFINE>{===>} ion_segid_1=""; 
 DEFINE> 
 DEFINE>{* convert chainid to segid if chainid is non-blank *} {+ choice: true false +} 
 DEFINE>{===>} ion_convert_1=false; 
 DEFINE> 
 DEFINE>{============================ renaming atoms ===============================} 
 DEFINE> 
 DEFINE>{* some atoms may need to be renamed in the topology database to conform 
 DEFINE>   to what is present in the coordinate file *} 
 DEFINE> 
 DEFINE>{* delta carbon in isoleucine is named CD in CNS 
 DEFINE>   what is it currently called in the coordinate file? *} 
 DEFINE>{* this will not be changed if left blank *} 
 DEFINE>{===>} ile_CD_becomes="CD1"; 
 DEFINE> 
 DEFINE>{* terminal oxygens are named OT1 and OT2 in CNS 
 DEFINE>   what are they currently called in the coordinate file? *} 
 DEFINE>{* these will not be changed if left blank *} 
 DEFINE>{===>} OT1_becomes=""; 
 DEFINE>{===>} OT2_becomes=""; 
 DEFINE> 
 DEFINE>{======================= automatic mainchain breaks ========================} 
 DEFINE> 
 DEFINE>{* automatically detect mainchain breaks in proteins based on distance *} 
 DEFINE>{* the peptide link at break points will be removed *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} auto_break=true; 
 DEFINE> 
 DEFINE>{* cutoff distance in Angstroms for identification of breaks *} 
 DEFINE>{* the default of 2.5A should be reasonable for most cases. If the input 
 DEFINE>   structure has bad geometry it may be necessary to increase this distance *} 
 DEFINE>{===>} break_cutoff=2.5; 
 DEFINE> 
 DEFINE>{* file containing patches to delete peptide links *} 
 DEFINE>{===>} prot_break_infile="CNS_TOPPAR:protein_break.top"; 
 DEFINE> 
 DEFINE>{======================= automatic disulphide bonds ========================} 
 DEFINE> 
 DEFINE>{* automatically detect disulphide bonds based on distance *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} auto_ss=false; 
 DEFINE> 
 DEFINE>{* cutoff distance in Angstroms for identification of disulphides *} 
 DEFINE>{* the default of 3.0A should be reasonable for most cases. If the input 
 DEFINE>   structure has bad geometry it may be necessary to increase this distance *} 
 DEFINE>{===>} disulphide_dist=3.0; 
 DEFINE> 
 DEFINE>{========================= manual disulphide bonds =========================} 
 DEFINE> ! we will do it my way (RT), look below for disu 
 DEFINE> 
 DEFINE>{========================= RNA to DNA conversion  ==========================} 
 DEFINE> 
 DEFINE>{* All nucleic acid residues initially have ribose sugars (rather than 
 DEFINE>   deoxyribose). A patch must be applied to convert the ribose to deoxyribose 
 DEFINE>   for DNA residues. Select those residues which need to have the patch 
 DEFINE>   applied to make them DNA. *} 
 DEFINE>{* Make sure that the atom selection is specific for the nucleic acid 
 DEFINE>   residues *} 
 DEFINE>{===>} dna_sele=(none); 
 DEFINE> 
 DEFINE>{=========================== carbohydrate links  ===========================} 
 DEFINE> 
 DEFINE>{* Select pairs of residues that are linked *} 
 DEFINE>{* First entry is the name of the patch residue. *} 
 DEFINE>{* Second and third entries are the resid and segid for the atoms 
 DEFINE>   referenced by "-" in the patch. *} 
 DEFINE>{* Fourth and fifth entries are the resid and segid for the atoms 
 DEFINE>   referenced by "+" in the patch *} 
 DEFINE>{+ table: rows=6 numbered 
 DEFINE>          cols=6 "use" "patch name" "segid -" "resid -" "segid +" "resid +" +} 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_1=false; 
 DEFINE>{===>} carbo_patch_1="B1N"; 
 DEFINE>{===>} carbo_i_segid_1="BBBB"; carbo_i_resid_1=401; 
 DEFINE>{===>} carbo_j_segid_1="AAAA"; carbo_j_resid_1=56; 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_2=false; 
 DEFINE>{===>} carbo_patch_2="B1N"; 
 DEFINE>{===>} carbo_i_segid_2="BBBB"; carbo_i_resid_2=402; 
 DEFINE>{===>} carbo_j_segid_2="AAAA"; carbo_j_resid_2=182; 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_3=false; 
 DEFINE>{===>} carbo_patch_3=""; 
 DEFINE>{===>} carbo_i_segid_3=""; carbo_i_resid_3=0; 
 DEFINE>{===>} carbo_j_segid_3=""; carbo_j_resid_3=0; 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_4=false; 
 DEFINE>{===>} carbo_patch_4=""; 
 DEFINE>{===>} carbo_i_segid_4=""; carbo_i_resid_4=0; 
 DEFINE>{===>} carbo_j_segid_4=""; carbo_j_resid_4=0; 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_5=false; 
 DEFINE>{===>} carbo_patch_5=""; 
 DEFINE>{===>} carbo_i_segid_5=""; carbo_i_resid_5=0; 
 DEFINE>{===>} carbo_j_segid_5=""; carbo_j_resid_5=0; 
 DEFINE> 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} carbo_use_6=false; 
 DEFINE>{===>} carbo_patch_6=""; 
 DEFINE>{===>} carbo_i_segid_6=""; carbo_i_resid_6=0; 
 DEFINE>{===>} carbo_j_segid_6=""; carbo_j_resid_6=0; 
 DEFINE> 
 DEFINE>{========================= generate parameters =============================} 
 DEFINE> 
 DEFINE>{* hydrogen flag - determines whether hydrogens will be output *} 
 DEFINE>{* must be true for NMR, atomic resolution X-ray crystallography 
 DEFINE>   or modelling.  Set to false for most X-ray crystallographic 
 DEFINE>   applications at resolution > 1A *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} hydrogen_flag=true; 
 DEFINE> 
 DEFINE>{* which hydrogens to build *} {+ choice: "all" "unknown" +} 
 DEFINE>{===>} hydrogen_build="all"; 
 DEFINE> 
 DEFINE>{* selection of atoms other than hydrogens for which coordinates 
 DEFINE>   will be generated *} 
 DEFINE>{* to generate coordinates for all unknown atoms use: (not(known)) *} 
 DEFINE>{===>} atom_build=(not(known)); 
 DEFINE> 
 DEFINE>{* selection of atoms to be deleted *} {* to delete no atoms use: (none) *} 
 DEFINE>{===>} atom_delete=(none); 
 DEFINE> 
 DEFINE>{* set bfactor flag *} {+ choice: true false +} 
 DEFINE>{===>} set_bfactor=false; 
 DEFINE> 
 DEFINE>{* set bfactor value *} 
 DEFINE>{===>} bfactor=15.0; 
 DEFINE> 
 DEFINE>{* set occupancy flag *} {+ choice: true false +} 
 DEFINE>{===>} set_occupancy=false; 
 DEFINE> 
 DEFINE>{* set occupancy value *} 
 DEFINE>{===>} occupancy=1.0; 
 DEFINE> 
 DEFINE>{============================= output files ================================} 
 DEFINE> 
 DEFINE>{* output structure file *} 
 DEFINE>{===>} structure_outfile="cnsPDB/sa_cns_10.mtf"; 
 DEFINE> 
 DEFINE>{* output coordinate file *} 
 DEFINE>{===>} coordinate_outfile="cnsPDB/sa_cns_10.pdb"; 
 DEFINE> 
 DEFINE>{* format output coordinates for use in o *} 
 DEFINE>{* if false then the default CNS output coordinate format will be used *} 
 DEFINE>{+ choice: true false +} 
 DEFINE>{===>} pdb_o_format=true; 
 DEFINE> 
 DEFINE>{================== protein topology and parameter files ===================} 
 DEFINE> 
 DEFINE>{* protein topology file *} 
 DEFINE>{===>} prot_topology_infile="TOPOWAT:topallhdg5.3.pro"; 
 DEFINE> 
 DEFINE>{* protein linkage file *} 
 DEFINE>{===>} prot_link_infile="CNS_TOPPAR:protein.link"; 
 DEFINE> 
 DEFINE>{* protein parameter file *} 
 DEFINE>{===>} prot_parameter_infile="TOPOWAT:parallhdg5.3.pro"; 
 DEFINE> 
 DEFINE>{================ nucleic acid topology and parameter files =================} 
 DEFINE> 
 DEFINE>{* nucleic acid topology file *} 
 DEFINE>{===>} nucl_topology_infile="CNS_TOPPAR:dna-rna.top"; 
 DEFINE> 
 DEFINE>{* nucleic acid linkage file *} 
 DEFINE>{* use CNS_TOPPAR:dna-rna-pho.link for 5'-phosphate *} 
 DEFINE>{===>} nucl_link_infile="CNS_TOPPAR:dna-rna.link"; 
 DEFINE> 
 DEFINE>{* nucleic acid parameter file *} 
 DEFINE>{===>} nucl_parameter_infile="CNS_TOPPAR:dna-rna_rep.param"; 
 DEFINE> 
 DEFINE>{=================== water topology and parameter files ====================} 
 DEFINE> 
 DEFINE>{* water topology file *} 
 DEFINE>{===>} water_topology_infile="CNS_TOPPAR:water.top"; 
 DEFINE> 
 DEFINE>{* water parameter file *} 
 DEFINE>{===>} water_parameter_infile="CNS_TOPPAR:water_rep.param"; 
 DEFINE> 
 DEFINE>{================= carbohydrate topology and parameter files ===============} 
 DEFINE> 
 DEFINE>{* carbohydrate topology file *} 
 DEFINE>{===>} carbo_topology_infile="CNS_TOPPAR:carbohydrate.top"; 
 DEFINE> 
 DEFINE>{* carbohydrate parameter file *} 
 DEFINE>{===>} carbo_parameter_infile="CNS_TOPPAR:carbohydrate.param"; 
 DEFINE> 
 DEFINE>{============= prosthetic group topology and parameter files ===============} 
 DEFINE> 
 DEFINE>{* prosthetic group topology file *} 
 DEFINE>{===>} prost_topology_infile=""; 
 DEFINE> 
 DEFINE>{* prosthetic group parameter file *} 
 DEFINE>{===>} prost_parameter_infile=""; 
 DEFINE> 
 DEFINE>{=================== ligand topology and parameter files ===================} 
 DEFINE> 
 DEFINE>{* ligand topology file *} 
 DEFINE>{===>} lig_topology_infile=""; 
 DEFINE> 
 DEFINE>{* ligand parameter file *} 
 DEFINE>{===>} lig_parameter_infile=""; 
 DEFINE> 
 DEFINE>{===================== ion topology and parameter files ====================} 
 DEFINE> 
 DEFINE>{* ion topology file *} 
 DEFINE>{===>} ion_topology_infile="CNS_TOPPAR:ion.top"; 
 DEFINE> 
 DEFINE>{* ion parameter file *} 
 DEFINE>{===>} ion_parameter_infile="CNS_TOPPAR:ion.param"; 
 DEFINE> 
 DEFINE>{===========================================================================} 
 DEFINE>{         things below this line do not need to be changed unless           } 
 DEFINE>{         you need to apply patches - at the appropriate places marked      } 
 DEFINE>{===========================================================================} 
 DEFINE> 
 DEFINE> ) {- end block parameter definition -} 
 CNSsolve> 
 CNSsolve> ! checkversion has been commented as 1.1 is like 1.2 (RT) 
 CNSsolve> ! checkversion 1.1 
 CNSsolve> 
 CNSsolve> evaluate ($log_level=quiet) 
 Assuming literal string "QUIET"
 EVALUATE: symbol $LOG_LEVEL set to "QUIET" (string)
 CNSsolve> 
 CNSsolve> topology 
 RTFRDR>   if ( &BLANK%prot_topology_infile = false ) then 
 NEXTCD: condition evaluated as true
 RTFRDR>     @@&prot_topology_infile 
 ASSFIL: file /farm/software/WaterRefinement_cns/topallhdg5.3.pro opened.
 RTFRDR>remark   file topallhdg.pro  version 5.3  date 23-Sept-02 
 RTFRDR>remark      for file parallhdg.pro version 5.3 date 13-Feb-02 or later 
 RTFRDR>remark   Geometric energy function parameters for distance geometry and 
 RTFRDR>remark      simulated annealing. 
 RTFRDR>remark   Author: Michael Nilges, EMBL Heidelberg; Institut Pasteur, Paris 
 RTFRDR>remark   This file contains modifications from M. Williams, UCL London 
 RTFRDR>remark   Last modification 16-Sept-02 
 RTFRDR> 
 RTFRDR>set echo off message off end 
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%nucl_topology_infile = false ) then 
 RTFRDR>     @@&nucl_topology_infile 
 RTFRDR>remarks file toppar/dna-rna.top 
 RTFRDR>remarks   dna/rna topology for crystallographic structure determination 
 RTFRDR> 
 RTFRDR>! removed references to CA, CF, CS, MG, NH3, OS (ATB 12/30/94) 
 RTFRDR>! removed TIP3 water model (ATB 12/30/94) 
 RTFRDR>! mapped NA->NNA, CH3E->CC3E (ATB 12/30/94) 
 RTFRDR> 
 RTFRDR>! 
 RTFRDR>!Please cite the following reference when using these parameters: 
 RTFRDR>!G. Parkinson, J. Vojtechovsky, L. Clowney, A.T. Brunger, H.M. Berman, 
 RTFRDR>!  New Parameters for the Refinement of Nucleic Acid Containing Structures, 
 RTFRDR>!  Acta Cryst. D, 52, 57-64 (1996). 
 RTFRDR>! 
 RTFRDR>! Oct. 8, 1996 - Modified by Alexey Bochkarev (McMaster University) 
 RTFRDR>!                to process properly 5PHO (5'-terminus with phosphate) patch. 
 RTFRDR>!                Geometry and charges of -O5'-PO3 group were taken from 
 RTFRDR>!                Saenger W. 1984.  Principles of Nucleic Acid Structure 
 RTFRDR>!                All modifications are placed between: 
 RTFRDR>!***AB*** 
 RTFRDR>!....included fragment 
 RTFRDR>!***AB end*** 
 RTFRDR>!                New atomic types were introduced to describe 
 RTFRDR>!                -O5'-PO3 group: O5H (O5') O1PH (O1P) O2PH (O2P) 
 RTFRDR>!                                in addition to existing OH (O5T) 
 RTFRDR> 
 RTFRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 RTFRDR> 
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%water_topology_infile = false ) then 
 RTFRDR>     @@&water_topology_infile 
 RTFRDR>remarks file toppar/water.top 
 RTFRDR>remarks   water topology for crystallographic structure determination 
 RTFRDR>remarks   based on Jorgensen Tip3p water model 
 RTFRDR> 
 RTFRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%carbo_topology_infile = false ) then 
 RTFRDR>     @@&carbo_topology_infile 
 RTFRDR>REMARKS toppar/carbohydrate.top {pyranose sugar toplogoy for crystallographic 
 RTFRDR>remarks structure determination} 
 RTFRDR>REMARKS FOR USE WITH CARBOHYDRATE.PARAM AND protein_rep.param PROTEIN PARAMETERS 
 RTFRDR>REMARKS ========================================================== 
 RTFRDR>REMARKS Bill Weis 10-July-1988 
 RTFRDR>REMARKS Also see CARBOHYDRATE.PARAM for parameters. 
 RTFRDR>REMARKS Charges taken from John Brady's glucose topology file for ring, 
 RTFRDR>REMARKS   others from protein parameter file. 
 RTFRDR>REMARKS Idealized values for impropers at ring carbons to allow simple 
 RTFRDR>REMARKS   construction of various anomers/epimers. 
 RTFRDR>REMARKS Any other hexose or link can be easily constructed by analogy to these. 
 RTFRDR> 
 RTFRDR>REMARKS Additions 6-March-1992 Bill Weis for use with PARAM2.CHO 
 RTFRDR>REMARKS New atom types CCA, CCE,  OA for the C1 & O1 positions to account 
 RTFRDR>REMARKS for different bond and angle values due to the anomeric effect. 
 RTFRDR>REMARKS More accurate equilibrium values for bond angle around this oxygen 
 RTFRDR>REMARKS in glycosidic linkages.  CCE for equatorial O1, CCA for 
 RTFRDR>REMAKRS axial O1.   For free sugar, keep OH1 as O1 atomtype; changed to OA 
 RTFRDR>REMARKS for linkages. 
 RTFRDR>REMARKS References: G.A. Jeffrey (1990) Acta Cryst B46, 89-103; 
 RTFRDR>REMARKS K. Hirotsu & A.Shimada, (1974) Bull. Chem. Soc. Japan, 47, 1872-1879. 
 RTFRDR> 
 RTFRDR>REMARKS Additional CC6 atomtype for exocyclic carbon 5/11/92 
 RTFRDR> 
 RTFRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 RTFRDR> 
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%prost_topology_infile = false ) then 
 RTFRDR>     @@&prost_topology_infile 
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%lig_topology_infile = false ) then 
 RTFRDR>     @@&lig_topology_infile 
 RTFRDR>   end if 
 RTFRDR>   if ( &BLANK%ion_topology_infile = false ) then 
 RTFRDR>     @@&ion_topology_infile 
 RTFRDR>remarks file toppar/ion.top 
 RTFRDR>remarks topology and masses for common ions 
 RTFRDR>remarks Dingle atom ion residues are given the name of the element. 
 RTFRDR>remarks By default the atom will be uncharged (eg. the residue MG will 
 RTFRDR>remarks contain the atom called MG with zero charge). 
 RTFRDR>remarks To use the charged species the charge state is appended to 
 RTFRDR>remarks the atom name (eg to use MG2+ the residue name is MG2, and the 
 RTFRDR>remarks atom name is MG+2 and has charge +2.0). 
 RTFRDR>remarks NOTE: not all ionic species are represented 
 RTFRDR>remarks PDA 02/09/99 
 RTFRDR> 
 RTFRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 RTFRDR>   end if 
 RTFRDR> end 
 CNSsolve> 
 CNSsolve> topology 
 RTFRDR>   if ( &BLANK%prot_break_infile = false ) then 
 RTFRDR>     @@&prot_break_infile 
 RTFRDR>remarks file toppar/protein_break.top 
 RTFRDR>remarks   patches to remove peptide linkages 
 RTFRDR> 
 RTFRDR>! Paul Adams 28th June 1999 
 RTFRDR>! Yale University 
 RTFRDR> 
 RTFRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 RTFRDR> 
 RTFRDR>   end if 
 RTFRDR> end 
 CNSsolve> 
 CNSsolve> parameter 
 PARRDR>   if ( &BLANK%prot_parameter_infile = false ) then 
 PARRDR>     @@&prot_parameter_infile 
 PARRDR>remark   file protein-allhdg-ucl.param  version UCL  date 07-JUL-01 
 PARRDR>remark   for file protein-allhdg-ucl.top  version UCL  date 14-MAR-00 
 PARRDR>remark   for file protein-allhdg-dih-ucl.top  version UCL  date 07-JUL-01 
 PARRDR>remark   Geometric energy function parameters for distance geometry and 
 PARRDR>remark   simulated annealing. 
 PARRDR>remark   Original author: Michael Nilges, EMBL Heidelberg 
 PARRDR>remark   Modifications: Mark A. Williams, UCL London 
 PARRDR> 
 PARRDR>set echo off message off end 
 %NEXTCD-ERR: Symbol not found:
  if ($par_nonbonded 
      ^^^^^^^^^^^^^^
 %NEXTCD-ERR: Symbol not found:
  elseif ($par_nonbonded 
          ^^^^^^^^^^^^^^
 %NEXTCD-ERR: Symbol not found:
   elseif ($par_nonbonded 
           ^^^^^^^^^^^^^^
 %NEXTCD-ERR: Symbol not found:
  elseif ($par_nonbonded 
          ^^^^^^^^^^^^^^
 %NEXTCD-ERR: Symbol not found:
  elseif ($par_nonbonded 
          ^^^^^^^^^^^^^^
 Program version= 1.2 File version= 1.2
 PARRDR>   end if 
 PARRDR>   if ( &BLANK%water_parameter_infile = false ) then 
 NEXTCD: condition evaluated as true
 PARRDR>     @@&water_parameter_infile 
 ASSFIL: file /farm/software/cns_solve_1.2/libraries/toppar/water_rep.param opened.
 PARRDR>remarks file toppar/water.param 
 PARRDR>remarks   water parameters for structure determination 
 PARRDR>remarks 
 PARRDR> 
 PARRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 EVALUATE: symbol $VDW_RADIUS_O set to    2.90000     (real)
 EVALUATE: symbol $VDW_RADIUS_HH set to    1.60000     (real)
 EVALUATE: symbol $VDW_RADIUS_O set to    2.58361     (real)
 EVALUATE: symbol $VDW_RADIUS_HH set to    1.42544     (real)
 EVALUATE: symbol $VDW_RADIUS14_O set to    2.31634     (real)
 EVALUATE: symbol $VDW_RADIUS14_HH set to    1.15817     (real)
 EVALUATE: symbol $VDW_EPS set to   0.100000     (real)
 PARRDR> 
 PARRDR>   end if 
 PARRDR>   if ( &BLANK%carbo_parameter_infile = false ) then 
 NEXTCD: condition evaluated as true
 PARRDR>     @@&carbo_parameter_infile 
 ASSFIL: file /farm/software/cns_solve_1.2/libraries/toppar/carbohydrate.param opened.
 PARRDR>remarks file toppar/carbohydrate.param 
 PARRDR>REMARKS Parameter file for pyranose sugars for crystallographic 
 PARRDR>remarks structure determination. 
 PARRDR>remarks 
 PARRDR> 
 PARRDR>REMARKS Bill Weis 10-July-1988 
 PARRDR>REMARKS Additions for atom type combinations not covered in PARAM19X.PRO. 
 PARRDR>REMARKS Needed additions are for ether oxygen and aliphatic carbon in all-atom 
 PARRDR>REMARKS representation used for sugars (type CC).  Ditto for type HA. 
 PARRDR>REMARKS Values from J. Brady glucose parameters unless noted. 
 PARRDR>REMARKS These should be sufficient for refinement. 
 PARRDR> 
 PARRDR>REMARKS Additions 6-March-1992 Bill Weis 
 PARRDR>REMARKS New atom types CCA, CCE,  OA for the C1 & O1 positions to account 
 PARRDR>REMARKS for different bond and angle values due to the anomeric effect. 
 PARRDR>REMARKS More accurate equilibrium values for bond angle around this oxygen 
 PARRDR>REMARKS in glycosidic linkages.  CCE for equatorial O1, CCA for 
 PARRDR>REMAKRS axial O1.   For free sugar, keep OH1 as O1 atomtype; changed to OA 
 PARRDR>REMARKS for linkages. 
 PARRDR>REMARKS References: G.A. Jeffrey (1990) Acta Cryst B46, 89-103; 
 PARRDR>REMARKS K. Hirotsu & A.Shimada, (1974) Bull. Chem. Soc. Japan, 47, 1872-1879. 
 PARRDR> 
 PARRDR>REMARKS  This set has been modified to be roughly consistent with 
 PARRDR>REMARKS  the csd-derived protein parameters of Engh and Huber. 
 PARRDR>REMARKS  New atom type CC6 for exocyclic 6 carbon 
 PARRDR>REMARKS  Bill Weis 5/11/92 
 PARRDR> 
 PARRDR>set echo=false end 
 Program version= 1.2 File version= 1.2
 PARRDR> 
 PARRDR>   end if 
 PARRDR>   if ( &BLANK%prost_parameter_infile = false ) then 
 NEXTCD: condition evaluated as false
 PARRDR>     @@&prost_parameter_infile 
 PARRDR>   end if 
 PARRDR>   if ( &BLANK%lig_parameter_infile = false ) then 
 NEXTCD: condition evaluated as false
 PARRDR>     @@&lig_parameter_infile 
 PARRDR>   end if 
 PARRDR>   if ( &BLANK%ion_parameter_infile = false ) then 
 NEXTCD: condition evaluated as true
 PARRDR>     @@&ion_parameter_infile 
 ASSFIL: file /farm/software/cns_solve_1.2/libraries/toppar/ion.param opened.
 PARRDR>remarks file toppar/ion.param 
 PARRDR>remarks nonbonded parameters for common ions 
 PARRDR>remarks new parameters derived from literature for single atom species 
 PARRDR>remarks PDA 02/09/99 
 PARRDR> 
 PARRDR>set echo=off end 
 Program version= 1.2 File version= 1.2
 PARRDR>   end if 
 PARRDR> end 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:      0 atoms have been selected out of      0
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>       do (refx=0) (all) 
 SELRPN:      0 atoms have been selected out of      0
 CNSsolve>       segment 
 SEGMENT>         chain 
 CHAIN>           if ( &prot_convert_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CHAIN>             convert=true 
 CHAIN>           end if 
 CHAIN>           if ( &prot_separate_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CHAIN>             separate=true 
 CHAIN>           end if 
 CHAIN>           @@&prot_link_infile 
 ASSFIL: file /farm/software/cns_solve_1.2/libraries/toppar/protein.link opened.
 CHAIN>remarks file toppar/protein.link 
 CHAIN>remarks 
 CHAIN>remarks this is a macro to define standard protein peptide bonds 
 CHAIN>remarks and termini to generate a protein sequence. 
 CHAIN> 
 CHAIN>set echo=false end 
 Program version= 1.2 File version= 1.2
 CHAIN>           coordinates @@&prot_coordinate_infile_$counter 
 SEGMNT: sequence read from coordinate file
 ASSFIL: file /farm/data/gliu/projects/HR4495E/cns/calc15/template_hr44.pdb opened.
 COOR>ATOM      1  N   MET A   1       6.974 -17.941  -5.441  1.00 75.15 
 MAPIC: Atom numbers being modified
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -C    +N    +CA   +CB   not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    +N    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 %PATCH-ERR: to be deleted dihedral -CB   -CA   -C    -O    not found in molecular structure.
 MAPIC: Atom numbers being modified
 SEGMNT:   126 residues were inserted into segment "    "
 CHAIN>         end 
 SEGMENT>       end 
 Status of internal molecular topology database:
 -> NATOM=       1980(MAXA=      200000)  NBOND=       1999(MAXB=      200000)
 -> NTHETA=      3620(MAXT=      400000)  NGRP=         128(MAXGRP=    200000)
 -> NPHI=        3098(MAXP=      400000)  NIMPHI=      1021(MAXIMP=    200000)
 -> NNB=          852(MAXNB=     200000) 
 CNSsolve>       if ( &BLANK%ile_CD_becomes = false ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>         do (name=&ile_CD_becomes) (resname ILE and name CD) 
 SELRPN:      0 atoms have been selected out of   1980
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT1_becomes = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         do (name=&OT1_becomes) (name OT1) 
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT2_becomes = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         do (name=&OT2_becomes) (name OT2) 
 CNSsolve>       end if 
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &prot_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           if ( &prot_separate_$counter = true ) then 
 CNSsolve>             separate=true 
 CNSsolve>           end if 
 CNSsolve>           @@&prot_link_infile 
 CNSsolve>           coordinates @@&prot_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &BLANK%ile_CD_becomes = false ) then 
 CNSsolve>         do (name=&ile_CD_becomes) (resname ILE and name CD) 
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT1_becomes = false ) then 
 CNSsolve>         do (name=&OT1_becomes) (name OT1) 
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT2_becomes = false ) then 
 CNSsolve>         do (name=&OT2_becomes) (name OT2) 
 CNSsolve>       end if 
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &prot_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           if ( &prot_separate_$counter = true ) then 
 CNSsolve>             separate=true 
 CNSsolve>           end if 
 CNSsolve>           @@&prot_link_infile 
 CNSsolve>           coordinates @@&prot_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &BLANK%ile_CD_becomes = false ) then 
 CNSsolve>         do (name=&ile_CD_becomes) (resname ILE and name CD) 
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT1_becomes = false ) then 
 CNSsolve>         do (name=&OT1_becomes) (name OT1) 
 CNSsolve>       end if 
 CNSsolve>       if ( &BLANK%OT2_becomes = false ) then 
 CNSsolve>         do (name=&OT2_becomes) (name OT2) 
 CNSsolve>       end if 
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> 
 CNSsolve> {* any special protein patches can be applied here *} {* doing it my way (RT) *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve> evaluate ($HaveCis = "no")       {* --- Apply possible CIS peptide patches --- *} 
 EVALUATE: symbol $HAVECIS set to "no" (string)
 CNSsolve> if ( $HaveCis = "yes" ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         !CISpep info 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> evaluate ($HaveHisd = "no")       {* --- Apply possible HISD peptide patches --- *} 
 EVALUATE: symbol $HAVEHISD set to "no" (string)
 CNSsolve> if ( $HaveHisd = "yes" ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         !HISDpep info 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> evaluate ($HaveHise = "no")       {* --- Apply possible HISE peptide patches --- *} 
 EVALUATE: symbol $HAVEHISE set to "no" (string)
 CNSsolve> if ( $HaveHise = "yes" ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         !HISEpep info 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> evaluate ($HaveDisu = "no")           {* --- Getting ready for S-S bridges --- *} 
 EVALUATE: symbol $HAVEDISU set to "no" (string)
 CNSsolve> if ( $HaveDisu = "yes" ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         !SSBridge  info 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>       coor 
 COOR>         if ( &prot_convert_$counter = true ) then 
 NEXTCD: condition evaluated as false
 COOR>           convert=true 
 COOR>         end if 
 COOR>         @@&prot_coordinate_infile_$counter 
 ASSFIL: file /farm/data/gliu/projects/HR4495E/cns/calc15/template_hr44.pdb opened.
 COOR>ATOM      1  N   MET A   1       6.974 -17.941  -5.441  1.00 75.15 
 COOR>ATOM      2  H   MET A   1       6.422 -18.301  -4.716  1.00 32.31 
 %READC-ERR: atom      1    MET  H    not found in molecular structure
 %READC-ERR: atom      1    MET  HB3  not found in molecular structure
 %READC-ERR: atom      1    MET  HG3  not found in molecular structure
 %READC-ERR: atom      2    GLY  H    not found in molecular structure
 %READC-ERR: atom      2    GLY  HA3  not found in molecular structure
 %READC-ERR: atom      3    HIS  H    not found in molecular structure
 %READC-ERR: atom      3    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      4    HIS  H    not found in molecular structure
 %READC-ERR: atom      4    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      5    HIS  H    not found in molecular structure
 %READC-ERR: atom      5    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      6    HIS  H    not found in molecular structure
 %READC-ERR: atom      6    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      7    HIS  H    not found in molecular structure
 %READC-ERR: atom      7    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      8    HIS  H    not found in molecular structure
 %READC-ERR: atom      8    HIS  HB3  not found in molecular structure
 %READC-ERR: atom      9    SER  H    not found in molecular structure
 %READC-ERR: atom      9    SER  HB3  not found in molecular structure
 %READC-ERR: atom      10   HIS  H    not found in molecular structure
 %READC-ERR: atom      10   HIS  HB3  not found in molecular structure
 %READC-ERR: atom      11   MET  H    not found in molecular structure
 %READC-ERR: atom      11   MET  HB3  not found in molecular structure
 %READC-ERR: atom      11   MET  HG3  not found in molecular structure
 %READC-ERR: atom      12   ASN  H    not found in molecular structure
 %READC-ERR: atom      12   ASN  HB3  not found in molecular structure
 %READC-ERR: atom      13   SER  H    not found in molecular structure
 %READC-ERR: atom      13   SER  HB3  not found in molecular structure
 %READC-ERR: atom      14   ALA  H    not found in molecular structure
 %READC-ERR: atom      15   GLU  H    not found in molecular structure
 %READC-ERR: atom      15   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      15   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      16   GLN  H    not found in molecular structure
 %READC-ERR: atom      16   GLN  HB3  not found in molecular structure
 %READC-ERR: atom      16   GLN  HG3  not found in molecular structure
 %READC-ERR: atom      17   THR  H    not found in molecular structure
 %READC-ERR: atom      18   VAL  H    not found in molecular structure
 %READC-ERR: atom      19   THR  H    not found in molecular structure
 %READC-ERR: atom      20   TRP  H    not found in molecular structure
 %READC-ERR: atom      20   TRP  HB3  not found in molecular structure
 %READC-ERR: atom      21   LEU  H    not found in molecular structure
 %READC-ERR: atom      21   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      22   ILE  H    not found in molecular structure
 %READC-ERR: atom      22   ILE  HG13 not found in molecular structure
 %READC-ERR: atom      23   THR  H    not found in molecular structure
 %READC-ERR: atom      24   LEU  H    not found in molecular structure
 %READC-ERR: atom      24   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      25   GLY  H    not found in molecular structure
 %READC-ERR: atom      25   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      26   VAL  H    not found in molecular structure
 %READC-ERR: atom      27   LEU  H    not found in molecular structure
 %READC-ERR: atom      27   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      28   GLU  H    not found in molecular structure
 %READC-ERR: atom      28   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      28   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      29   SER  H    not found in molecular structure
 %READC-ERR: atom      29   SER  HB3  not found in molecular structure
 %READC-ERR: atom      30   PRO  HB3  not found in molecular structure
 %READC-ERR: atom      30   PRO  HG3  not found in molecular structure
 %READC-ERR: atom      30   PRO  HD3  not found in molecular structure
 %READC-ERR: atom      31   LYS  H    not found in molecular structure
 %READC-ERR: atom      31   LYS  HB3  not found in molecular structure
 %READC-ERR: atom      31   LYS  HG3  not found in molecular structure
 %READC-ERR: atom      31   LYS  HD3  not found in molecular structure
 %READC-ERR: atom      31   LYS  HE3  not found in molecular structure
 %READC-ERR: atom      32   LYS  H    not found in molecular structure
 %READC-ERR: atom      32   LYS  HB3  not found in molecular structure
 %READC-ERR: atom      32   LYS  HG3  not found in molecular structure
 %READC-ERR: atom      32   LYS  HD3  not found in molecular structure
 %READC-ERR: atom      32   LYS  HE3  not found in molecular structure
 %READC-ERR: atom      33   THR  H    not found in molecular structure
 %READC-ERR: atom      34   ILE  H    not found in molecular structure
 %READC-ERR: atom      34   ILE  HG13 not found in molecular structure
 %READC-ERR: atom      35   SER  H    not found in molecular structure
 %READC-ERR: atom      35   SER  HB3  not found in molecular structure
 %READC-ERR: atom      36   ASP  H    not found in molecular structure
 %READC-ERR: atom      36   ASP  HB3  not found in molecular structure
 %READC-ERR: atom      37   PRO  HB3  not found in molecular structure
 %READC-ERR: atom      37   PRO  HG3  not found in molecular structure
 %READC-ERR: atom      37   PRO  HD3  not found in molecular structure
 %READC-ERR: atom      38   GLU  H    not found in molecular structure
 %READC-ERR: atom      38   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      38   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      39   GLY  H    not found in molecular structure
 %READC-ERR: atom      39   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      40   PHE  H    not found in molecular structure
 %READC-ERR: atom      40   PHE  HB3  not found in molecular structure
 %READC-ERR: atom      41   LEU  H    not found in molecular structure
 %READC-ERR: atom      41   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      42   GLN  H    not found in molecular structure
 %READC-ERR: atom      42   GLN  HB3  not found in molecular structure
 %READC-ERR: atom      42   GLN  HG3  not found in molecular structure
 %READC-ERR: atom      43   ALA  H    not found in molecular structure
 %READC-ERR: atom      44   SER  H    not found in molecular structure
 %READC-ERR: atom      44   SER  HB3  not found in molecular structure
 %READC-ERR: atom      45   LEU  H    not found in molecular structure
 %READC-ERR: atom      45   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      46   LYS  H    not found in molecular structure
 %READC-ERR: atom      46   LYS  HB3  not found in molecular structure
 %READC-ERR: atom      46   LYS  HG3  not found in molecular structure
 %READC-ERR: atom      46   LYS  HD3  not found in molecular structure
 %READC-ERR: atom      46   LYS  HE3  not found in molecular structure
 %READC-ERR: atom      47   ASP  H    not found in molecular structure
 %READC-ERR: atom      47   ASP  HB3  not found in molecular structure
 %READC-ERR: atom      48   GLY  H    not found in molecular structure
 %READC-ERR: atom      48   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      49   VAL  H    not found in molecular structure
 %READC-ERR: atom      50   VAL  H    not found in molecular structure
 %READC-ERR: atom      51   LEU  H    not found in molecular structure
 %READC-ERR: atom      51   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      52   CYS  H    not found in molecular structure
 %READC-ERR: atom      52   CYS  HB3  not found in molecular structure
 %READC-ERR: atom      53   ARG  H    not found in molecular structure
 %READC-ERR: atom      53   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      53   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      53   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      54   LEU  H    not found in molecular structure
 %READC-ERR: atom      54   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      55   LEU  H    not found in molecular structure
 %READC-ERR: atom      55   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      56   GLU  H    not found in molecular structure
 %READC-ERR: atom      56   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      56   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      57   ARG  H    not found in molecular structure
 %READC-ERR: atom      57   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      57   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      57   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      58   LEU  H    not found in molecular structure
 %READC-ERR: atom      58   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      59   LEU  H    not found in molecular structure
 %READC-ERR: atom      59   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      60   PRO  HB3  not found in molecular structure
 %READC-ERR: atom      60   PRO  HG3  not found in molecular structure
 %READC-ERR: atom      60   PRO  HD3  not found in molecular structure
 %READC-ERR: atom      61   GLY  H    not found in molecular structure
 %READC-ERR: atom      61   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      62   THR  H    not found in molecular structure
 %READC-ERR: atom      63   ILE  H    not found in molecular structure
 %READC-ERR: atom      63   ILE  HG13 not found in molecular structure
 %READC-ERR: atom      64   GLU  H    not found in molecular structure
 %READC-ERR: atom      64   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      64   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      65   LYS  H    not found in molecular structure
 %READC-ERR: atom      65   LYS  HB3  not found in molecular structure
 %READC-ERR: atom      65   LYS  HG3  not found in molecular structure
 %READC-ERR: atom      65   LYS  HD3  not found in molecular structure
 %READC-ERR: atom      65   LYS  HE3  not found in molecular structure
 %READC-ERR: atom      66   VAL  H    not found in molecular structure
 %READC-ERR: atom      67   TYR  H    not found in molecular structure
 %READC-ERR: atom      67   TYR  HB3  not found in molecular structure
 %READC-ERR: atom      68   PRO  HB3  not found in molecular structure
 %READC-ERR: atom      68   PRO  HG3  not found in molecular structure
 %READC-ERR: atom      68   PRO  HD3  not found in molecular structure
 %READC-ERR: atom      69   GLU  H    not found in molecular structure
 %READC-ERR: atom      69   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      69   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      70   PRO  HB3  not found in molecular structure
 %READC-ERR: atom      70   PRO  HG3  not found in molecular structure
 %READC-ERR: atom      70   PRO  HD3  not found in molecular structure
 %READC-ERR: atom      71   ARG  H    not found in molecular structure
 %READC-ERR: atom      71   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      71   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      71   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      72   SER  H    not found in molecular structure
 %READC-ERR: atom      72   SER  HB3  not found in molecular structure
 %READC-ERR: atom      73   GLU  H    not found in molecular structure
 %READC-ERR: atom      73   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      73   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      74   SER  H    not found in molecular structure
 %READC-ERR: atom      74   SER  HB3  not found in molecular structure
 %READC-ERR: atom      75   GLU  H    not found in molecular structure
 %READC-ERR: atom      75   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      75   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      76   CYS  H    not found in molecular structure
 %READC-ERR: atom      76   CYS  HB3  not found in molecular structure
 %READC-ERR: atom      77   LEU  H    not found in molecular structure
 %READC-ERR: atom      77   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      78   SER  H    not found in molecular structure
 %READC-ERR: atom      78   SER  HB3  not found in molecular structure
 %READC-ERR: atom      79   ASN  H    not found in molecular structure
 %READC-ERR: atom      79   ASN  HB3  not found in molecular structure
 %READC-ERR: atom      80   ILE  H    not found in molecular structure
 %READC-ERR: atom      80   ILE  HG13 not found in molecular structure
 %READC-ERR: atom      81   ARG  H    not found in molecular structure
 %READC-ERR: atom      81   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      81   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      81   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      82   GLU  H    not found in molecular structure
 %READC-ERR: atom      82   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      82   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      83   PHE  H    not found in molecular structure
 %READC-ERR: atom      83   PHE  HB3  not found in molecular structure
 %READC-ERR: atom      84   LEU  H    not found in molecular structure
 %READC-ERR: atom      84   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      85   ARG  H    not found in molecular structure
 %READC-ERR: atom      85   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      85   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      85   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      86   GLY  H    not found in molecular structure
 %READC-ERR: atom      86   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      87   CYS  H    not found in molecular structure
 %READC-ERR: atom      87   CYS  HB3  not found in molecular structure
 %READC-ERR: atom      88   GLY  H    not found in molecular structure
 %READC-ERR: atom      88   GLY  HA3  not found in molecular structure
 %READC-ERR: atom      89   ALA  H    not found in molecular structure
 %READC-ERR: atom      90   SER  H    not found in molecular structure
 %READC-ERR: atom      90   SER  HB3  not found in molecular structure
 %READC-ERR: atom      91   LEU  H    not found in molecular structure
 %READC-ERR: atom      91   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      92   ARG  H    not found in molecular structure
 %READC-ERR: atom      92   ARG  HB3  not found in molecular structure
 %READC-ERR: atom      92   ARG  HG3  not found in molecular structure
 %READC-ERR: atom      92   ARG  HD3  not found in molecular structure
 %READC-ERR: atom      93   LEU  H    not found in molecular structure
 %READC-ERR: atom      93   LEU  HB3  not found in molecular structure
 %READC-ERR: atom      94   GLU  H    not found in molecular structure
 %READC-ERR: atom      94   GLU  HB3  not found in molecular structure
 %READC-ERR: atom      94   GLU  HG3  not found in molecular structure
 %READC-ERR: atom      95   THR  H    not found in molecular structure
 %READC-ERR: atom      96   PHE  H    not found in molecular structure
 %READC-ERR: atom      96   PHE  HB3  not found in molecular structure
 %READC-ERR: atom      97   ASP  H    not found in molecular structure
 %READC-ERR: atom      97   ASP  HB3  not found in molecular structure
 %READC-ERR: atom      98   ALA  H    not found in molecular structure
 %READC-ERR: atom      99   ASN  H    not found in molecular structure
 %READC-ERR: atom      99   ASN  HB3  not found in molecular structure
 %READC-ERR: atom      100  ASP  H    not found in molecular structure
 %READC-ERR: atom      100  ASP  HB3  not found in molecular structure
 %READC-ERR: atom      101  LEU  H    not found in molecular structure
 %READC-ERR: atom      101  LEU  HB3  not found in molecular structure
 %READC-ERR: atom      102  TYR  H    not found in molecular structure
 %READC-ERR: atom      102  TYR  HB3  not found in molecular structure
 %READC-ERR: atom      103  GLN  H    not found in molecular structure
 %READC-ERR: atom      103  GLN  HB3  not found in molecular structure
 %READC-ERR: atom      103  GLN  HG3  not found in molecular structure
 %READC-ERR: atom      104  GLY  H    not found in molecular structure
 %READC-ERR: atom      104  GLY  HA3  not found in molecular structure
 %READC-ERR: atom      105  GLN  H    not found in molecular structure
 %READC-ERR: atom      105  GLN  HB3  not found in molecular structure
 %READC-ERR: atom      105  GLN  HG3  not found in molecular structure
 %READC-ERR: atom      106  ASN  H    not found in molecular structure
 %READC-ERR: atom      106  ASN  HB3  not found in molecular structure
 %READC-ERR: atom      107  PHE  H    not found in molecular structure
 %READC-ERR: atom      107  PHE  HB3  not found in molecular structure
 %READC-ERR: atom      108  ASN  H    not found in molecular structure
 %READC-ERR: atom      108  ASN  HB3  not found in molecular structure
 %READC-ERR: atom      109  LYS  H    not found in molecular structure
 %READC-ERR: atom      109  LYS  HB3  not found in molecular structure
 %READC-ERR: atom      109  LYS  HG3  not found in molecular structure
 %READC-ERR: atom      109  LYS  HD3  not found in molecular structure
 %READC-ERR: atom      109  LYS  HE3  not found in molecular structure
 %READC-ERR: atom      110  VAL  H    not found in molecular structure
 %READC-ERR: atom      111  LEU  H    not found in molecular structure
 %READC-ERR: atom      111  LEU  HB3  not found in molecular structure
 %READC-ERR: atom      112  SER  H    not found in molecular structure
 %READC-ERR: atom      112  SER  HB3  not found in molecular structure
 %READC-ERR: atom      113  SER  H    not found in molecular structure
 %READC-ERR: atom      113  SER  HB3  not found in molecular structure
 %READC-ERR: atom      114  LEU  H    not found in molecular structure
 %READC-ERR: atom      114  LEU  HB3  not found in molecular structure
 %READC-ERR: atom      115  VAL  H    not found in molecular structure
 %READC-ERR: atom      116  THR  H    not found in molecular structure
 %READC-ERR: atom      117  LEU  H    not found in molecular structure
 %READC-ERR: atom      117  LEU  HB3  not found in molecular structure
 %READC-ERR: atom      118  ASN  H    not found in molecular structure
 %READC-ERR: atom      118  ASN  HB3  not found in molecular structure
 %READC-ERR: atom      119  LYS  H    not found in molecular structure
 %READC-ERR: atom      119  LYS  HB3  not found in molecular structure
 %READC-ERR: atom      119  LYS  HG3  not found in molecular structure
 %READC-ERR: atom      119  LYS  HD3  not found in molecular structure
 %READC-ERR: atom      119  LYS  HE3  not found in molecular structure
 %READC-ERR: atom      120  VAL  H    not found in molecular structure
 %READC-ERR: atom      121  THR  H    not found in molecular structure
 %READC-ERR: atom      122  ALA  H    not found in molecular structure
 %READC-ERR: atom      123  ASP  H    not found in molecular structure
 %READC-ERR: atom      123  ASP  HB3  not found in molecular structure
 %READC-ERR: atom      124  ILE  H    not found in molecular structure
 %READC-ERR: atom      124  ILE  HG13 not found in molecular structure
 %READC-ERR: atom      125  GLY  H    not found in molecular structure
 %READC-ERR: atom      125  GLY  HA3  not found in molecular structure
 %READC-ERR: atom      126  LEU  H    not found in molecular structure
 %READC-ERR: atom      126  LEU  HB3  not found in molecular structure
 %READC-ERR: atom      126  LEU  O    not found in molecular structure
 CNSsolve>         set echo=off end 
 SELRPN:      2 atoms have been selected out of   1980
 SHOW: sum over selected elements =       2.000000
 NEXTCD: condition evaluated as false
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>         do (segid=capitalize(&prot_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &prot_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&prot_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&prot_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> while ( $done = false ) loop prot 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_prot_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%prot_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &prot_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&prot_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &prot_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&prot_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prot 
 CNSsolve> 
 CNSsolve> if ( $log_level = verbose ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>   set message=normal echo=on end 
 CNSsolve> else 
 CNSsolve>   set message=off echo=off end 
 (      MET  1    C    )      
 (      MET  1    C    )  1   
 (      MET  1    C    )  MET 
 SHOW: sum over selected elements =       1.000000
 (      GLY  2    N    )    20.000    
 (      GLY  2    N    )      
 (      GLY  2    N    )  2   
 (      GLY  2    N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  2    C    )      
 (      GLY  2    C    )  2   
 (      GLY  2    C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      HIS  3    N    )    27.000    
 (      HIS  3    N    )      
 (      HIS  3    N    )  3   
 (      HIS  3    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  3    C    )      
 (      HIS  3    C    )  3   
 (      HIS  3    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  4    N    )    45.000    
 (      HIS  4    N    )      
 (      HIS  4    N    )  4   
 (      HIS  4    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  4    C    )      
 (      HIS  4    C    )  4   
 (      HIS  4    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  5    N    )    63.000    
 (      HIS  5    N    )      
 (      HIS  5    N    )  5   
 (      HIS  5    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  5    C    )      
 (      HIS  5    C    )  5   
 (      HIS  5    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  6    N    )    81.000    
 (      HIS  6    N    )      
 (      HIS  6    N    )  6   
 (      HIS  6    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  6    C    )      
 (      HIS  6    C    )  6   
 (      HIS  6    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  7    N    )    99.000    
 (      HIS  7    N    )      
 (      HIS  7    N    )  7   
 (      HIS  7    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  7    C    )      
 (      HIS  7    C    )  7   
 (      HIS  7    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  8    N    )    117.00    
 (      HIS  8    N    )      
 (      HIS  8    N    )  8   
 (      HIS  8    N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  8    C    )      
 (      HIS  8    C    )  8   
 (      HIS  8    C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      SER  9    N    )    135.00    
 (      SER  9    N    )      
 (      SER  9    N    )  9   
 (      SER  9    N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  9    C    )      
 (      SER  9    C    )  9   
 (      SER  9    C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      HIS  10   N    )    146.00    
 (      HIS  10   N    )      
 (      HIS  10   N    )  10  
 (      HIS  10   N    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      HIS  10   C    )      
 (      HIS  10   C    )  10  
 (      HIS  10   C    )  HIS 
 SHOW: sum over selected elements =       1.000000
 (      MET  11   N    )    164.00    
 (      MET  11   N    )      
 (      MET  11   N    )  11  
 (      MET  11   N    )  MET 
 SHOW: sum over selected elements =       1.000000
 (      MET  11   C    )      
 (      MET  11   C    )  11  
 (      MET  11   C    )  MET 
 SHOW: sum over selected elements =       1.000000
 (      ASN  12   N    )    181.00    
 (      ASN  12   N    )      
 (      ASN  12   N    )  12  
 (      ASN  12   N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  12   C    )      
 (      ASN  12   C    )  12  
 (      ASN  12   C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      SER  13   N    )    195.00    
 (      SER  13   N    )      
 (      SER  13   N    )  13  
 (      SER  13   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  13   C    )      
 (      SER  13   C    )  13  
 (      SER  13   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      ALA  14   N    )    206.00    
 (      ALA  14   N    )      
 (      ALA  14   N    )  14  
 (      ALA  14   N    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ALA  14   C    )      
 (      ALA  14   C    )  14  
 (      ALA  14   C    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      GLU  15   N    )    216.00    
 (      GLU  15   N    )      
 (      GLU  15   N    )  15  
 (      GLU  15   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  15   C    )      
 (      GLU  15   C    )  15  
 (      GLU  15   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLN  16   N    )    231.00    
 (      GLN  16   N    )      
 (      GLN  16   N    )  16  
 (      GLN  16   N    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      GLN  16   C    )      
 (      GLN  16   C    )  16  
 (      GLN  16   C    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      THR  17   N    )    248.00    
 (      THR  17   N    )      
 (      THR  17   N    )  17  
 (      THR  17   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  17   C    )      
 (      THR  17   C    )  17  
 (      THR  17   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      VAL  18   N    )    262.00    
 (      VAL  18   N    )      
 (      VAL  18   N    )  18  
 (      VAL  18   N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  18   C    )      
 (      VAL  18   C    )  18  
 (      VAL  18   C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      THR  19   N    )    278.00    
 (      THR  19   N    )      
 (      THR  19   N    )  19  
 (      THR  19   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  19   C    )      
 (      THR  19   C    )  19  
 (      THR  19   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      TRP  20   N    )    292.00    
 (      TRP  20   N    )      
 (      TRP  20   N    )  20  
 (      TRP  20   N    )  TRP 
 SHOW: sum over selected elements =       1.000000
 (      TRP  20   C    )      
 (      TRP  20   C    )  20  
 (      TRP  20   C    )  TRP 
 SHOW: sum over selected elements =       1.000000
 (      LEU  21   N    )    316.00    
 (      LEU  21   N    )      
 (      LEU  21   N    )  21  
 (      LEU  21   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  21   C    )      
 (      LEU  21   C    )  21  
 (      LEU  21   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      ILE  22   N    )    335.00    
 (      ILE  22   N    )      
 (      ILE  22   N    )  22  
 (      ILE  22   N    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ILE  22   C    )      
 (      ILE  22   C    )  22  
 (      ILE  22   C    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      THR  23   N    )    354.00    
 (      THR  23   N    )      
 (      THR  23   N    )  23  
 (      THR  23   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  23   C    )      
 (      THR  23   C    )  23  
 (      THR  23   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      LEU  24   N    )    368.00    
 (      LEU  24   N    )      
 (      LEU  24   N    )  24  
 (      LEU  24   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  24   C    )      
 (      LEU  24   C    )  24  
 (      LEU  24   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      GLY  25   N    )    387.00    
 (      GLY  25   N    )      
 (      GLY  25   N    )  25  
 (      GLY  25   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  25   C    )      
 (      GLY  25   C    )  25  
 (      GLY  25   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      VAL  26   N    )    394.00    
 (      VAL  26   N    )      
 (      VAL  26   N    )  26  
 (      VAL  26   N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  26   C    )      
 (      VAL  26   C    )  26  
 (      VAL  26   C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      LEU  27   N    )    410.00    
 (      LEU  27   N    )      
 (      LEU  27   N    )  27  
 (      LEU  27   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  27   C    )      
 (      LEU  27   C    )  27  
 (      LEU  27   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  28   N    )    429.00    
 (      GLU  28   N    )      
 (      GLU  28   N    )  28  
 (      GLU  28   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  28   C    )      
 (      GLU  28   C    )  28  
 (      GLU  28   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      SER  29   N    )    444.00    
 (      SER  29   N    )      
 (      SER  29   N    )  29  
 (      SER  29   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  29   C    )      
 (      SER  29   C    )  29  
 (      SER  29   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      PRO  30   N    )    455.00    
 (      PRO  30   N    )      
 (      PRO  30   N    )  30  
 (      PRO  30   N    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      PRO  30   C    )      
 (      PRO  30   C    )  30  
 (      PRO  30   C    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      LYS  31   N    )    469.00    
 (      LYS  31   N    )      
 (      LYS  31   N    )  31  
 (      LYS  31   N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  31   C    )      
 (      LYS  31   C    )  31  
 (      LYS  31   C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  32   N    )    491.00    
 (      LYS  32   N    )      
 (      LYS  32   N    )  32  
 (      LYS  32   N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  32   C    )      
 (      LYS  32   C    )  32  
 (      LYS  32   C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      THR  33   N    )    513.00    
 (      THR  33   N    )      
 (      THR  33   N    )  33  
 (      THR  33   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  33   C    )      
 (      THR  33   C    )  33  
 (      THR  33   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      ILE  34   N    )    527.00    
 (      ILE  34   N    )      
 (      ILE  34   N    )  34  
 (      ILE  34   N    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ILE  34   C    )      
 (      ILE  34   C    )  34  
 (      ILE  34   C    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      SER  35   N    )    546.00    
 (      SER  35   N    )      
 (      SER  35   N    )  35  
 (      SER  35   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  35   C    )      
 (      SER  35   C    )  35  
 (      SER  35   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      ASP  36   N    )    557.00    
 (      ASP  36   N    )      
 (      ASP  36   N    )  36  
 (      ASP  36   N    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ASP  36   C    )      
 (      ASP  36   C    )  36  
 (      ASP  36   C    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      PRO  37   N    )    569.00    
 (      PRO  37   N    )      
 (      PRO  37   N    )  37  
 (      PRO  37   N    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      PRO  37   C    )      
 (      PRO  37   C    )  37  
 (      PRO  37   C    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      GLU  38   N    )    583.00    
 (      GLU  38   N    )      
 (      GLU  38   N    )  38  
 (      GLU  38   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  38   C    )      
 (      GLU  38   C    )  38  
 (      GLU  38   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLY  39   N    )    598.00    
 (      GLY  39   N    )      
 (      GLY  39   N    )  39  
 (      GLY  39   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  39   C    )      
 (      GLY  39   C    )  39  
 (      GLY  39   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      PHE  40   N    )    605.00    
 (      PHE  40   N    )      
 (      PHE  40   N    )  40  
 (      PHE  40   N    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      PHE  40   C    )      
 (      PHE  40   C    )  40  
 (      PHE  40   C    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      LEU  41   N    )    625.00    
 (      LEU  41   N    )      
 (      LEU  41   N    )  41  
 (      LEU  41   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  41   C    )      
 (      LEU  41   C    )  41  
 (      LEU  41   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      GLN  42   N    )    644.00    
 (      GLN  42   N    )      
 (      GLN  42   N    )  42  
 (      GLN  42   N    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      GLN  42   C    )      
 (      GLN  42   C    )  42  
 (      GLN  42   C    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      ALA  43   N    )    661.00    
 (      ALA  43   N    )      
 (      ALA  43   N    )  43  
 (      ALA  43   N    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ALA  43   C    )      
 (      ALA  43   C    )  43  
 (      ALA  43   C    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      SER  44   N    )    671.00    
 (      SER  44   N    )      
 (      SER  44   N    )  44  
 (      SER  44   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  44   C    )      
 (      SER  44   C    )  44  
 (      SER  44   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      LEU  45   N    )    682.00    
 (      LEU  45   N    )      
 (      LEU  45   N    )  45  
 (      LEU  45   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  45   C    )      
 (      LEU  45   C    )  45  
 (      LEU  45   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LYS  46   N    )    701.00    
 (      LYS  46   N    )      
 (      LYS  46   N    )  46  
 (      LYS  46   N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  46   C    )      
 (      LYS  46   C    )  46  
 (      LYS  46   C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      ASP  47   N    )    723.00    
 (      ASP  47   N    )      
 (      ASP  47   N    )  47  
 (      ASP  47   N    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ASP  47   C    )      
 (      ASP  47   C    )  47  
 (      ASP  47   C    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      GLY  48   N    )    735.00    
 (      GLY  48   N    )      
 (      GLY  48   N    )  48  
 (      GLY  48   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  48   C    )      
 (      GLY  48   C    )  48  
 (      GLY  48   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      VAL  49   N    )    742.00    
 (      VAL  49   N    )      
 (      VAL  49   N    )  49  
 (      VAL  49   N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  49   C    )      
 (      VAL  49   C    )  49  
 (      VAL  49   C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  50   N    )    758.00    
 (      VAL  50   N    )      
 (      VAL  50   N    )  50  
 (      VAL  50   N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  50   C    )      
 (      VAL  50   C    )  50  
 (      VAL  50   C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      LEU  51   N    )    774.00    
 (      LEU  51   N    )      
 (      LEU  51   N    )  51  
 (      LEU  51   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  51   C    )      
 (      LEU  51   C    )  51  
 (      LEU  51   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      CYS  52   N    )    793.00    
 (      CYS  52   N    )      
 (      CYS  52   N    )  52  
 (      CYS  52   N    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      CYS  52   C    )      
 (      CYS  52   C    )  52  
 (      CYS  52   C    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      ARG  53   N    )    804.00    
 (      ARG  53   N    )      
 (      ARG  53   N    )  53  
 (      ARG  53   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  53   C    )      
 (      ARG  53   C    )  53  
 (      ARG  53   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      LEU  54   N    )    828.00    
 (      LEU  54   N    )      
 (      LEU  54   N    )  54  
 (      LEU  54   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  54   C    )      
 (      LEU  54   C    )  54  
 (      LEU  54   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  55   N    )    847.00    
 (      LEU  55   N    )      
 (      LEU  55   N    )  55  
 (      LEU  55   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  55   C    )      
 (      LEU  55   C    )  55  
 (      LEU  55   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  56   N    )    866.00    
 (      GLU  56   N    )      
 (      GLU  56   N    )  56  
 (      GLU  56   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  56   C    )      
 (      GLU  56   C    )  56  
 (      GLU  56   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      ARG  57   N    )    881.00    
 (      ARG  57   N    )      
 (      ARG  57   N    )  57  
 (      ARG  57   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  57   C    )      
 (      ARG  57   C    )  57  
 (      ARG  57   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      LEU  58   N    )    905.00    
 (      LEU  58   N    )      
 (      LEU  58   N    )  58  
 (      LEU  58   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  58   C    )      
 (      LEU  58   C    )  58  
 (      LEU  58   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  59   N    )    924.00    
 (      LEU  59   N    )      
 (      LEU  59   N    )  59  
 (      LEU  59   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  59   C    )      
 (      LEU  59   C    )  59  
 (      LEU  59   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      PRO  60   N    )    943.00    
 (      PRO  60   N    )      
 (      PRO  60   N    )  60  
 (      PRO  60   N    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      PRO  60   C    )      
 (      PRO  60   C    )  60  
 (      PRO  60   C    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      GLY  61   N    )    957.00    
 (      GLY  61   N    )      
 (      GLY  61   N    )  61  
 (      GLY  61   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  61   C    )      
 (      GLY  61   C    )  61  
 (      GLY  61   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      THR  62   N    )    964.00    
 (      THR  62   N    )      
 (      THR  62   N    )  62  
 (      THR  62   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  62   C    )      
 (      THR  62   C    )  62  
 (      THR  62   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      ILE  63   N    )    978.00    
 (      ILE  63   N    )      
 (      ILE  63   N    )  63  
 (      ILE  63   N    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ILE  63   C    )      
 (      ILE  63   C    )  63  
 (      ILE  63   C    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      GLU  64   N    )    997.00    
 (      GLU  64   N    )      
 (      GLU  64   N    )  64  
 (      GLU  64   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  64   C    )      
 (      GLU  64   C    )  64  
 (      GLU  64   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      LYS  65   N    )    1012.0    
 (      LYS  65   N    )      
 (      LYS  65   N    )  65  
 (      LYS  65   N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  65   C    )      
 (      LYS  65   C    )  65  
 (      LYS  65   C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      VAL  66   N    )    1034.0    
 (      VAL  66   N    )      
 (      VAL  66   N    )  66  
 (      VAL  66   N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  66   C    )      
 (      VAL  66   C    )  66  
 (      VAL  66   C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      TYR  67   N    )    1050.0    
 (      TYR  67   N    )      
 (      TYR  67   N    )  67  
 (      TYR  67   N    )  TYR 
 SHOW: sum over selected elements =       1.000000
 (      TYR  67   C    )      
 (      TYR  67   C    )  67  
 (      TYR  67   C    )  TYR 
 SHOW: sum over selected elements =       1.000000
 (      PRO  68   N    )    1071.0    
 (      PRO  68   N    )      
 (      PRO  68   N    )  68  
 (      PRO  68   N    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      PRO  68   C    )      
 (      PRO  68   C    )  68  
 (      PRO  68   C    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      GLU  69   N    )    1085.0    
 (      GLU  69   N    )      
 (      GLU  69   N    )  69  
 (      GLU  69   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  69   C    )      
 (      GLU  69   C    )  69  
 (      GLU  69   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      PRO  70   N    )    1100.0    
 (      PRO  70   N    )      
 (      PRO  70   N    )  70  
 (      PRO  70   N    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      PRO  70   C    )      
 (      PRO  70   C    )  70  
 (      PRO  70   C    )  PRO 
 SHOW: sum over selected elements =       1.000000
 (      ARG  71   N    )    1114.0    
 (      ARG  71   N    )      
 (      ARG  71   N    )  71  
 (      ARG  71   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  71   C    )      
 (      ARG  71   C    )  71  
 (      ARG  71   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      SER  72   N    )    1138.0    
 (      SER  72   N    )      
 (      SER  72   N    )  72  
 (      SER  72   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  72   C    )      
 (      SER  72   C    )  72  
 (      SER  72   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      GLU  73   N    )    1149.0    
 (      GLU  73   N    )      
 (      GLU  73   N    )  73  
 (      GLU  73   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  73   C    )      
 (      GLU  73   C    )  73  
 (      GLU  73   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      SER  74   N    )    1164.0    
 (      SER  74   N    )      
 (      SER  74   N    )  74  
 (      SER  74   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  74   C    )      
 (      SER  74   C    )  74  
 (      SER  74   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      GLU  75   N    )    1175.0    
 (      GLU  75   N    )      
 (      GLU  75   N    )  75  
 (      GLU  75   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  75   C    )      
 (      GLU  75   C    )  75  
 (      GLU  75   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      CYS  76   N    )    1190.0    
 (      CYS  76   N    )      
 (      CYS  76   N    )  76  
 (      CYS  76   N    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      CYS  76   C    )      
 (      CYS  76   C    )  76  
 (      CYS  76   C    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      LEU  77   N    )    1201.0    
 (      LEU  77   N    )      
 (      LEU  77   N    )  77  
 (      LEU  77   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  77   C    )      
 (      LEU  77   C    )  77  
 (      LEU  77   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      SER  78   N    )    1220.0    
 (      SER  78   N    )      
 (      SER  78   N    )  78  
 (      SER  78   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  78   C    )      
 (      SER  78   C    )  78  
 (      SER  78   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      ASN  79   N    )    1231.0    
 (      ASN  79   N    )      
 (      ASN  79   N    )  79  
 (      ASN  79   N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  79   C    )      
 (      ASN  79   C    )  79  
 (      ASN  79   C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ILE  80   N    )    1245.0    
 (      ILE  80   N    )      
 (      ILE  80   N    )  80  
 (      ILE  80   N    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ILE  80   C    )      
 (      ILE  80   C    )  80  
 (      ILE  80   C    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ARG  81   N    )    1264.0    
 (      ARG  81   N    )      
 (      ARG  81   N    )  81  
 (      ARG  81   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  81   C    )      
 (      ARG  81   C    )  81  
 (      ARG  81   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      GLU  82   N    )    1288.0    
 (      GLU  82   N    )      
 (      GLU  82   N    )  82  
 (      GLU  82   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  82   C    )      
 (      GLU  82   C    )  82  
 (      GLU  82   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      PHE  83   N    )    1303.0    
 (      PHE  83   N    )      
 (      PHE  83   N    )  83  
 (      PHE  83   N    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      PHE  83   C    )      
 (      PHE  83   C    )  83  
 (      PHE  83   C    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      LEU  84   N    )    1323.0    
 (      LEU  84   N    )      
 (      LEU  84   N    )  84  
 (      LEU  84   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  84   C    )      
 (      LEU  84   C    )  84  
 (      LEU  84   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      ARG  85   N    )    1342.0    
 (      ARG  85   N    )      
 (      ARG  85   N    )  85  
 (      ARG  85   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  85   C    )      
 (      ARG  85   C    )  85  
 (      ARG  85   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      GLY  86   N    )    1366.0    
 (      GLY  86   N    )      
 (      GLY  86   N    )  86  
 (      GLY  86   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  86   C    )      
 (      GLY  86   C    )  86  
 (      GLY  86   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      CYS  87   N    )    1373.0    
 (      CYS  87   N    )      
 (      CYS  87   N    )  87  
 (      CYS  87   N    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      CYS  87   C    )      
 (      CYS  87   C    )  87  
 (      CYS  87   C    )  CYS 
 SHOW: sum over selected elements =       1.000000
 (      GLY  88   N    )    1384.0    
 (      GLY  88   N    )      
 (      GLY  88   N    )  88  
 (      GLY  88   N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  88   C    )      
 (      GLY  88   C    )  88  
 (      GLY  88   C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      ALA  89   N    )    1391.0    
 (      ALA  89   N    )      
 (      ALA  89   N    )  89  
 (      ALA  89   N    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ALA  89   C    )      
 (      ALA  89   C    )  89  
 (      ALA  89   C    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      SER  90   N    )    1401.0    
 (      SER  90   N    )      
 (      SER  90   N    )  90  
 (      SER  90   N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  90   C    )      
 (      SER  90   C    )  90  
 (      SER  90   C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      LEU  91   N    )    1412.0    
 (      LEU  91   N    )      
 (      LEU  91   N    )  91  
 (      LEU  91   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  91   C    )      
 (      LEU  91   C    )  91  
 (      LEU  91   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      ARG  92   N    )    1431.0    
 (      ARG  92   N    )      
 (      ARG  92   N    )  92  
 (      ARG  92   N    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      ARG  92   C    )      
 (      ARG  92   C    )  92  
 (      ARG  92   C    )  ARG 
 SHOW: sum over selected elements =       1.000000
 (      LEU  93   N    )    1455.0    
 (      LEU  93   N    )      
 (      LEU  93   N    )  93  
 (      LEU  93   N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  93   C    )      
 (      LEU  93   C    )  93  
 (      LEU  93   C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  94   N    )    1474.0    
 (      GLU  94   N    )      
 (      GLU  94   N    )  94  
 (      GLU  94   N    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      GLU  94   C    )      
 (      GLU  94   C    )  94  
 (      GLU  94   C    )  GLU 
 SHOW: sum over selected elements =       1.000000
 (      THR  95   N    )    1489.0    
 (      THR  95   N    )      
 (      THR  95   N    )  95  
 (      THR  95   N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  95   C    )      
 (      THR  95   C    )  95  
 (      THR  95   C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      PHE  96   N    )    1503.0    
 (      PHE  96   N    )      
 (      PHE  96   N    )  96  
 (      PHE  96   N    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      PHE  96   C    )      
 (      PHE  96   C    )  96  
 (      PHE  96   C    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      ASP  97   N    )    1523.0    
 (      ASP  97   N    )      
 (      ASP  97   N    )  97  
 (      ASP  97   N    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ASP  97   C    )      
 (      ASP  97   C    )  97  
 (      ASP  97   C    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ALA  98   N    )    1535.0    
 (      ALA  98   N    )      
 (      ALA  98   N    )  98  
 (      ALA  98   N    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ALA  98   C    )      
 (      ALA  98   C    )  98  
 (      ALA  98   C    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ASN  99   N    )    1545.0    
 (      ASN  99   N    )      
 (      ASN  99   N    )  99  
 (      ASN  99   N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  99   C    )      
 (      ASN  99   C    )  99  
 (      ASN  99   C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASP  100  N    )    1559.0    
 (      ASP  100  N    )      
 (      ASP  100  N    )  100 
 (      ASP  100  N    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ASP  100  C    )      
 (      ASP  100  C    )  100 
 (      ASP  100  C    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      LEU  101  N    )    1571.0    
 (      LEU  101  N    )      
 (      LEU  101  N    )  101 
 (      LEU  101  N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  101  C    )      
 (      LEU  101  C    )  101 
 (      LEU  101  C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      TYR  102  N    )    1590.0    
 (      TYR  102  N    )      
 (      TYR  102  N    )  102 
 (      TYR  102  N    )  TYR 
 SHOW: sum over selected elements =       1.000000
 (      TYR  102  C    )      
 (      TYR  102  C    )  102 
 (      TYR  102  C    )  TYR 
 SHOW: sum over selected elements =       1.000000
 (      GLN  103  N    )    1611.0    
 (      GLN  103  N    )      
 (      GLN  103  N    )  103 
 (      GLN  103  N    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      GLN  103  C    )      
 (      GLN  103  C    )  103 
 (      GLN  103  C    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      GLY  104  N    )    1628.0    
 (      GLY  104  N    )      
 (      GLY  104  N    )  104 
 (      GLY  104  N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  104  C    )      
 (      GLY  104  C    )  104 
 (      GLY  104  C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLN  105  N    )    1635.0    
 (      GLN  105  N    )      
 (      GLN  105  N    )  105 
 (      GLN  105  N    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      GLN  105  C    )      
 (      GLN  105  C    )  105 
 (      GLN  105  C    )  GLN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  106  N    )    1652.0    
 (      ASN  106  N    )      
 (      ASN  106  N    )  106 
 (      ASN  106  N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  106  C    )      
 (      ASN  106  C    )  106 
 (      ASN  106  C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      PHE  107  N    )    1666.0    
 (      PHE  107  N    )      
 (      PHE  107  N    )  107 
 (      PHE  107  N    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      PHE  107  C    )      
 (      PHE  107  C    )  107 
 (      PHE  107  C    )  PHE 
 SHOW: sum over selected elements =       1.000000
 (      ASN  108  N    )    1686.0    
 (      ASN  108  N    )      
 (      ASN  108  N    )  108 
 (      ASN  108  N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  108  C    )      
 (      ASN  108  C    )  108 
 (      ASN  108  C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      LYS  109  N    )    1700.0    
 (      LYS  109  N    )      
 (      LYS  109  N    )  109 
 (      LYS  109  N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  109  C    )      
 (      LYS  109  C    )  109 
 (      LYS  109  C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      VAL  110  N    )    1722.0    
 (      VAL  110  N    )      
 (      VAL  110  N    )  110 
 (      VAL  110  N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  110  C    )      
 (      VAL  110  C    )  110 
 (      VAL  110  C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      LEU  111  N    )    1738.0    
 (      LEU  111  N    )      
 (      LEU  111  N    )  111 
 (      LEU  111  N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  111  C    )      
 (      LEU  111  C    )  111 
 (      LEU  111  C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      SER  112  N    )    1757.0    
 (      SER  112  N    )      
 (      SER  112  N    )  112 
 (      SER  112  N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  112  C    )      
 (      SER  112  C    )  112 
 (      SER  112  C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  113  N    )    1768.0    
 (      SER  113  N    )      
 (      SER  113  N    )  113 
 (      SER  113  N    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      SER  113  C    )      
 (      SER  113  C    )  113 
 (      SER  113  C    )  SER 
 SHOW: sum over selected elements =       1.000000
 (      LEU  114  N    )    1779.0    
 (      LEU  114  N    )      
 (      LEU  114  N    )  114 
 (      LEU  114  N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  114  C    )      
 (      LEU  114  C    )  114 
 (      LEU  114  C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      VAL  115  N    )    1798.0    
 (      VAL  115  N    )      
 (      VAL  115  N    )  115 
 (      VAL  115  N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  115  C    )      
 (      VAL  115  C    )  115 
 (      VAL  115  C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      THR  116  N    )    1814.0    
 (      THR  116  N    )      
 (      THR  116  N    )  116 
 (      THR  116  N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  116  C    )      
 (      THR  116  C    )  116 
 (      THR  116  C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      LEU  117  N    )    1828.0    
 (      LEU  117  N    )      
 (      LEU  117  N    )  117 
 (      LEU  117  N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      LEU  117  C    )      
 (      LEU  117  C    )  117 
 (      LEU  117  C    )  LEU 
 SHOW: sum over selected elements =       1.000000
 (      ASN  118  N    )    1847.0    
 (      ASN  118  N    )      
 (      ASN  118  N    )  118 
 (      ASN  118  N    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      ASN  118  C    )      
 (      ASN  118  C    )  118 
 (      ASN  118  C    )  ASN 
 SHOW: sum over selected elements =       1.000000
 (      LYS  119  N    )    1861.0    
 (      LYS  119  N    )      
 (      LYS  119  N    )  119 
 (      LYS  119  N    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      LYS  119  C    )      
 (      LYS  119  C    )  119 
 (      LYS  119  C    )  LYS 
 SHOW: sum over selected elements =       1.000000
 (      VAL  120  N    )    1883.0    
 (      VAL  120  N    )      
 (      VAL  120  N    )  120 
 (      VAL  120  N    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      VAL  120  C    )      
 (      VAL  120  C    )  120 
 (      VAL  120  C    )  VAL 
 SHOW: sum over selected elements =       1.000000
 (      THR  121  N    )    1899.0    
 (      THR  121  N    )      
 (      THR  121  N    )  121 
 (      THR  121  N    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      THR  121  C    )      
 (      THR  121  C    )  121 
 (      THR  121  C    )  THR 
 SHOW: sum over selected elements =       1.000000
 (      ALA  122  N    )    1913.0    
 (      ALA  122  N    )      
 (      ALA  122  N    )  122 
 (      ALA  122  N    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ALA  122  C    )      
 (      ALA  122  C    )  122 
 (      ALA  122  C    )  ALA 
 SHOW: sum over selected elements =       1.000000
 (      ASP  123  N    )    1923.0    
 (      ASP  123  N    )      
 (      ASP  123  N    )  123 
 (      ASP  123  N    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ASP  123  C    )      
 (      ASP  123  C    )  123 
 (      ASP  123  C    )  ASP 
 SHOW: sum over selected elements =       1.000000
 (      ILE  124  N    )    1935.0    
 (      ILE  124  N    )      
 (      ILE  124  N    )  124 
 (      ILE  124  N    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      ILE  124  C    )      
 (      ILE  124  C    )  124 
 (      ILE  124  C    )  ILE 
 SHOW: sum over selected elements =       1.000000
 (      GLY  125  N    )    1954.0    
 (      GLY  125  N    )      
 (      GLY  125  N    )  125 
 (      GLY  125  N    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      GLY  125  C    )      
 (      GLY  125  C    )  125 
 (      GLY  125  C    )  GLY 
 SHOW: sum over selected elements =       1.000000
 (      LEU  126  N    )    1961.0    
 (      LEU  126  N    )      
 (      LEU  126  N    )  126 
 (      LEU  126  N    )  LEU 
 SHOW: sum over selected elements =       1.000000
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &nucl_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           if ( &nucl_separate_$counter = true ) then 
 CNSsolve>             separate=true 
 CNSsolve>           end if 
 CNSsolve>           @@&nucl_link_infile 
 CNSsolve>           coordinates @@&nucl_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &nucl_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           if ( &nucl_separate_$counter = true ) then 
 CNSsolve>             separate=true 
 CNSsolve>           end if 
 CNSsolve>           @@&nucl_link_infile 
 CNSsolve>           coordinates @@&nucl_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &nucl_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           if ( &nucl_separate_$counter = true ) then 
 CNSsolve>             separate=true 
 CNSsolve>           end if 
 CNSsolve>           @@&nucl_link_infile 
 CNSsolve>           coordinates @@&nucl_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> 
 CNSsolve> {* any special nucleic acid patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &nucl_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&nucl_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&nucl_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &nucl_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&nucl_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&nucl_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> while ( $done = false ) loop nucl 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_nucl_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%nucl_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &nucl_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&nucl_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &nucl_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&nucl_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop nucl 
 CNSsolve> 
 CNSsolve> {- patching of RNA to DNA -} 
 CNSsolve> evaluate ($counter=0) 
 EVALUATE: symbol $COUNTER set to    0.00000     (real)
 CNSsolve> for $id in id ( tag and (&dna_sele) ) loop dna 
 SELRPN:      0 atoms have been selected out of   1980
 CNSsolve>   evaluate ($counter=$counter+1) 
 CNSsolve>   show (segid) (id $id) 
 CNSsolve>   evaluate ($dna.segid.$counter=$result) 
 CNSsolve>   show (resid) (id $id) 
 CNSsolve>   evaluate ($dna.resid.$counter=$result) 
 CNSsolve> end loop dna 
 CNSsolve> evaluate ($dna.num=$counter) 
 EVALUATE: symbol $DNA.NUM set to    0.00000     (real)
 CNSsolve> 
 CNSsolve> evaluate ($counter=0) 
 EVALUATE: symbol $COUNTER set to    0.00000     (real)
 CNSsolve> while ($counter < $dna.num) loop dnap 
 NEXTCD: condition evaluated as false
 CNSsolve>   evaluate ($counter=$counter+1) 
 CNSsolve>   patch deox reference=nil=(segid $dna.segid.$counter and 
 CNSsolve>                             resid $dna.resid.$counter) end 
 CNSsolve> end loop dnap 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &water_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&water_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &water_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&water_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &water_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&water_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> 
 CNSsolve> {* any special water patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &water_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&water_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&water_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &water_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&water_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&water_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> while ( $done = false ) loop water 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_water_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%water_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &water_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&water_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &water_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&water_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop water 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &carbo_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&carbo_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &carbo_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&carbo_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &carbo_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&carbo_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &carbo_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&carbo_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&carbo_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &carbo_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&carbo_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&carbo_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> while ( $done = false ) loop carbo 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_carbo_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%carbo_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &carbo_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&carbo_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &carbo_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&carbo_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop carbo 
 CNSsolve> 
 CNSsolve> evaluate ($carc=1) 
 EVALUATE: symbol $CARC set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    3.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    4.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    5.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    6.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 EVALUATE: symbol $CARC set to    7.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> while ( $done = false ) loop cabr 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_carbo_use_$carc = true ) then 
 CNSsolve>     if ( &carbo_use_$carc = true ) then 
 CNSsolve>       evaluate ($segidtmp1=capitalize(&carbo_i_segid_$carc)) 
 CNSsolve>       evaluate ($segidtmp2=capitalize(&carbo_j_segid_$carc)) 
 CNSsolve>       patch &carbo_patch_$carc 
 CNSsolve>         reference=-=(segid $QUOTE%segidtmp1 and 
 CNSsolve>                      resid &carbo_i_resid_$carc) 
 CNSsolve>         reference=+=(segid $QUOTE%segidtmp2 and 
 CNSsolve>                      resid &carbo_j_resid_$carc) 
 CNSsolve>       end 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($carc=$carc+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop cabr 
 CNSsolve> 
 CNSsolve> {* any special carbohydrate patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &prost_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&prost_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &prost_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&prost_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &prost_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&prost_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> 
 CNSsolve> {* any special prosthetic group patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &prost_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&prost_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&prost_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &prost_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&prost_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&prost_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> while ( $done = false ) loop prost 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_prost_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%prost_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &prost_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&prost_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &prost_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&prost_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop prost 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &lig_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&lig_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &lig_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&lig_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &lig_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&lig_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> 
 CNSsolve> {* any special ligand patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &lig_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&lig_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&lig_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &lig_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&lig_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&lig_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> while ( $done = false ) loop liga 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_lig_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%lig_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &lig_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&lig_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &lig_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&lig_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop liga 
 CNSsolve> 
 CNSsolve> do (refy=0) (all) 
 SELRPN:   1980 atoms have been selected out of   1980
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &ion_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&ion_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &ion_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&ion_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 CNSsolve>       do (refx=0) (all) 
 CNSsolve>       segment 
 CNSsolve>         chain 
 CNSsolve>           if ( &ion_convert_$counter = true ) then 
 CNSsolve>             convert=true 
 CNSsolve>           end if 
 CNSsolve>           coordinates @@&ion_coordinate_infile_$counter 
 CNSsolve>         end 
 CNSsolve>       end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (refy=$counter) (attr refx=9999) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> 
 CNSsolve> {* any special ion patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> evaluate ($counter=1) 
 EVALUATE: symbol $COUNTER set to    1.00000     (real)
 CNSsolve> evaluate ($done=false) 
 EVALUATE: symbol $DONE set to FALSE (logical)
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>       coor 
 CNSsolve>         if ( &ion_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&ion_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&ion_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 EVALUATE: symbol $COUNTER set to    2.00000     (real)
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as true
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 NEXTCD: condition evaluated as false
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &ion_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&ion_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&ion_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 EVALUATE: symbol $DONE set to TRUE (logical)
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> while ( $done = false ) loop ion 
 NEXTCD: condition evaluated as false
 CNSsolve>   if ( &exist_ion_coordinate_infile_$counter = true ) then 
 CNSsolve>     if ( &BLANK%ion_coordinate_infile_$counter = false ) then 
 CNSsolve>       coor 
 CNSsolve>         if ( &ion_convert_$counter = true ) then 
 CNSsolve>           convert=true 
 CNSsolve>         end if 
 CNSsolve>         @@&ion_coordinate_infile_$counter 
 CNSsolve>         set echo=off end 
 CNSsolve>         show sum(1) ( not(hydrogen) and not(known) ) 
 CNSsolve>         if ( $select = 0 ) then 
 CNSsolve>           display  %INFO: There are no coordinates missing for non-hydrogen atoms 
 CNSsolve>         end if 
 CNSsolve>         set echo=on end 
 CNSsolve>       if ( &ion_rename_$counter = true ) then 
 CNSsolve>         do (segid=capitalize(&ion_segid_$counter)) (attr refy=$counter) 
 CNSsolve>       end if 
 CNSsolve>     end if 
 CNSsolve>     evaluate ($counter=$counter+1) 
 CNSsolve>   else 
 CNSsolve>     evaluate ($done=true) 
 CNSsolve>   end if 
 CNSsolve> end loop ion 
 CNSsolve> 
 CNSsolve> {* any final patches can be applied here *} 
 CNSsolve>{===>} 
 CNSsolve> 
 CNSsolve>{<===} 
 CNSsolve> 
 CNSsolve> if (&hydrogen_flag=false) then 
 NEXTCD: condition evaluated as false
 CNSsolve>   delete selection=( hydrogen ) end 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> delete selection=( &atom_delete ) end 
 SELRPN:      0 atoms have been selected out of   1980
 SCRATC-warning: STORe selections erased.
 Status of internal molecular topology database:
 -> NATOM=       1980(MAXA=      200000)  NBOND=       1999(MAXB=      200000)
 -> NTHETA=      3620(MAXT=      400000)  NGRP=         128(MAXGRP=    200000)
 -> NPHI=        3098(MAXP=      400000)  NIMPHI=      1021(MAXIMP=    200000)
 -> NNB=          852(MAXNB=     200000) 
 CNSsolve> 
 CNSsolve> identity (store1) (none) 
 SELRPN:      0 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve> identity (store1) (&atom_build) 
 SELRPN:    293 atoms have been selected out of   1980
 CNSsolve> if ( &hydrogen_build = "all" ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>   identity (store1) (store1 or hydrogen) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> elseif ( &hydrogen_build = "unknown" ) then 
 CNSsolve>   identity (store1) (store1 or (not(known) and hydrogen)) 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> show sum(1) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 SHOW: sum over selected elements =     995.000000
 CNSsolve> evaluate ($tobuild=$result) 
 EVALUATE: symbol $TOBUILD set to    995.000     (real)
 CNSsolve> 
 CNSsolve> if ( $tobuild > 0 ) then 
 NEXTCD: condition evaluated as true
 CNSsolve> 
 CNSsolve>   fix selection=(not(store1)) end 
 SELRPN:    985 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>   show sum(1) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 SHOW: sum over selected elements =     995.000000
 CNSsolve>   evaluate ($moving=$result) 
 EVALUATE: symbol $MOVING set to    995.000     (real)
 CNSsolve> 
 CNSsolve>   if ( $moving > 0 ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 SELRPN:    126 atoms have been selected out of   1980
 FOR ID LOOP: symbol ID set to    1.00000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.952214
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.95221     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.586643
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.5866     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.467071
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   -4.46707     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    20.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.527600
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.5276     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.929400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.9294     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.964400
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   -4.96440     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    27.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.284733
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.2847     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.401533
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.4015     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      -8.892533
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   -8.89253     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    45.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.449400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.4494     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -11.032667
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -11.0327     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      -7.997867
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   -7.99787     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    63.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.525133
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.5251     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -11.174067
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -11.1741     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      -2.248467
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   -2.24847     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    81.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      17.929733
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    17.9297     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -14.968600
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -14.9686     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       0.138333
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to   0.138333     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    99.0000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.930467
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.9305     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.710467
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.7105     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       1.991533
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    1.99153     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    117.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.228600
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    18.2286     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -16.671133
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -16.6711     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.287067
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    5.28707     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    135.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.733333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.7333     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -18.483111
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -18.4831     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =       8.428889
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    8.42889     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    146.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.984133
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.9841     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -13.786867
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -13.7869     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       7.867200
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    7.86720     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    164.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.955714
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.9557     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.232500
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.2325     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.939214
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    12.9392     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    181.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.341500
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.3415     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -20.810583
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -20.8106     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.248750
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    14.2487     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    195.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.416222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.4162     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.465778
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.4658     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.347222
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    15.3472     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    206.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.809000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.8090     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.366444
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.3664     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.542333
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.5423     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    216.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.958000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.9580     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -17.627583
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -17.6276     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.130917
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.1309     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    231.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =       9.145143
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    9.14514     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.560929
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.5609     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.159571
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.1596     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    248.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.752154
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.7522     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.787462
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.7875     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.516846
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    21.5168     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    262.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.991133
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.9911     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.930933
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.9309     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.235467
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.2355     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    278.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.352846
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.3528     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.997846
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.9978     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.433077
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.4331     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    292.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     22 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.806409
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.80641     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     22 atoms have been selected out of   1980
 SHOW: average of selected elements =     -21.912182
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -21.9122     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     22 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.914455
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    23.9145     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     10 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     10 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     10 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    316.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       9.379882
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    9.37988     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.993529
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.9935     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.153588
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.1536     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    335.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.823529
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.8235     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -17.108294
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -17.1083     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      29.119118
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    29.1191     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    354.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.614615
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.61462     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -16.177538
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -16.1775     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.510692
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.5107     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    368.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       3.918824
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    3.91882     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -20.638412
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -20.6384     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.603118
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.6031     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    387.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =       6.201000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    6.20100     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.372600
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.3726     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.408400
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.4084     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    394.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       7.065200
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    7.06520     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -23.035000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -23.0350     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.478000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.4780     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    410.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.670882
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    12.6709     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.306118
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.3061     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      31.037706
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    31.0377     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    429.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.892083
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.8921     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.309083
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.3091     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.948333
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.9483     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    444.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.583111
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.5831     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.773556
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.7736     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      30.897667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    30.8977     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    455.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      17.918000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    17.9180     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =     -15.542727
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -15.5427     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      29.131455
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    29.1315     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    469.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.941941
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    22.9419     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -12.213647
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -12.2136     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.210235
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.2102     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    491.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.601176
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    23.6012     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -12.047353
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -12.0474     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      25.842353
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    25.8424     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    513.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.125615
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    21.1256     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -12.043615
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -12.0436     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.489692
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.4897     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    527.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.906118
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.9061     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -17.155529
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -17.1555     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.437059
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    23.4371     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    546.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.258222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    24.2582     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -16.803000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -16.8030     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.809778
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.8098     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    557.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.043500
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    23.0435     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =     -21.609300
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -21.6093     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.749600
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.7496     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    569.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.890000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    18.8900     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =     -21.215273
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -21.2153     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.910273
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    19.9103     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    583.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.466417
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.4664     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -25.155833
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -25.1558     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      17.872250
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    17.8723     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    598.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.958400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    20.9584     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -26.001400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -26.0014     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.628400
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.6284     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    605.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.648722
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    18.6487     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.055667
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.0557     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      26.365667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    26.3657     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    625.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.211941
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.2119     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -24.875235
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -24.8752     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.277412
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    23.2774     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    644.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.179143
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.1791     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -30.585357
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -30.5854     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.218214
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.2182     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    661.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.932556
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.9326     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -28.450556
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -28.4506     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.871889
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.8719     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    671.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.939222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.9392     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -26.573778
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -26.5738     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.659444
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.6594     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    682.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.621765
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.6218     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -29.245824
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -29.2458     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      26.133000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    26.1330     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    701.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.260059
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.2601     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -33.240647
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -33.2406     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      29.863765
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    29.8638     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    723.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.338100
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.3381     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.018100
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.0181     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.695200
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.6952     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    735.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.055400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    12.0554     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.352600
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.3526     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      31.423800
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    31.4238     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    742.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.889600
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.8896     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -30.631867
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -30.6319     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      35.516467
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    35.5165     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    758.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.045867
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.0459     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -26.931733
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -26.9317     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      31.684067
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    31.6841     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    774.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       9.419706
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    9.41971     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.120882
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.1209     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.168294
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.1683     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    793.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =       6.181556
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    6.18156     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.995778
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.9958     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.432222
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.4322     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    804.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =       8.069500
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    8.06950     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -27.013750
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -27.0137     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      35.590350
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    35.5903     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    828.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       4.903765
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    4.90376     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -26.382647
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -26.3826     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.943647
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.9436     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    847.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       1.268706
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    1.26871     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.249824
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.2498     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      29.247059
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    29.2471     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    866.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =       0.755083
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   0.755083     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -28.690083
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -28.6901     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      34.226250
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    34.2263     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    881.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =       0.789400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   0.789400     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.438500
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.4385     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.256850
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.2569     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    905.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      -0.803529
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to  -0.803529     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -25.170294
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -25.1703     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.012294
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.0123     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    924.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      -3.561471
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -3.56147     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -29.946529
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -29.9465     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.256294
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.2563     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    943.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.435091
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -4.43509     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =     -27.801364
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -27.8014     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.225545
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.2255     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    957.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.251400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -4.25140     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.123200
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.1232     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      35.055200
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    35.0552     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    964.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      -2.430538
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -2.43054     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -34.292077
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -34.2921     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      31.795462
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    31.7955     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    978.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       1.867941
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    1.86794     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -34.005588
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -34.0056     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      34.551647
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    34.5516     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    997.000     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      -0.518083
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to  -0.518083     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.205333
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.2053     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      38.489000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    38.4890     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1012.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       4.669353
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    4.66935     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -39.596588
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -39.5966     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      39.928294
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    39.9283     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1034.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       7.182667
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    7.18267     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -34.355000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -34.3550     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      37.608067
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    37.6081     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1050.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.450526
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.4505     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.451000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.4510     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =      38.296789
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    38.2968     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1071.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.340000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.3400     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.429455
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.4295     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      40.259000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    40.2590     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1085.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.431833
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    14.4318     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -33.794417
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -33.7944     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      42.736667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    42.7367     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1100.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.445818
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.4458     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =     -35.736364
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -35.7364     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     11 atoms have been selected out of   1980
 SHOW: average of selected elements =      38.576273
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    38.5763     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1114.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.464750
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.4647     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -36.823900
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -36.8239     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      43.038750
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    43.0388     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1138.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.915222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    18.9152     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -41.735222
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -41.7352     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      38.246889
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    38.2469     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1149.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.793833
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.7938     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -42.097917
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -42.0979     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      32.887000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    32.8870     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1164.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.625889
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.6259     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -44.019556
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -44.0196     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      34.541778
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    34.5418     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1175.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.792167
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.7922     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -40.429833
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -40.4298     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      37.574750
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    37.5748     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1190.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.438889
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.4389     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -37.793556
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -37.7936     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.712444
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.7124     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1201.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.427059
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.4271     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -40.845941
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -40.8459     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      29.774118
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    29.7741     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1220.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.503333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.5033     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -40.589111
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -40.5891     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.047778
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.0478     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1231.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.078000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.0780     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -35.788750
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -35.7888     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      33.467083
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    33.4671     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1245.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.696824
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.6968     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -36.472235
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -36.4722     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.755176
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.7552     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1264.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =       9.100700
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    9.10070     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -43.034400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -43.0344     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.186500
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.1865     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1288.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.366500
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.36650     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.578083
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.5781     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      31.863500
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    31.8635     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1303.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.623333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.62333     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.972833
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.9728     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.169056
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.1691     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1323.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       6.809059
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    6.80906     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -37.289118
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -37.2891     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.646824
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.6468     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1342.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =       2.882850
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    2.88285     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -41.986250
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -41.9862     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.371300
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.3713     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1366.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      -0.118400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to  -0.118400     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -36.305000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -36.3050     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      27.188200
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    27.1882     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1373.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =       0.825111
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   0.825111     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -33.629667
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -33.6297     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.479222
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.4792     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1384.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      -0.273400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to  -0.273400     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -37.536400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -37.5364     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.635800
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.6358     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1391.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      -2.979333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -2.97933     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.523111
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.5231     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      25.118889
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    25.1189     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1401.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      -5.585333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -5.58533     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -34.952000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -34.9520     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.656667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.6567     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1412.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      -3.086824
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -3.08682     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.666176
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.6662     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.833235
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    21.8332     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1431.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.221250
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -4.22125     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.919400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.9194     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     20 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.849100
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    19.8491     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1455.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       1.225588
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    1.22559     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -33.134941
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -33.1349     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.629824
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    19.6298     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1474.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =       3.275750
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    3.27575     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -34.960250
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -34.9602     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.870583
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    15.8706     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1489.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =       5.297538
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    5.29754     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -37.244615
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -37.2446     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.250692
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.2507     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1503.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      10.145667
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    10.1457     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =     -35.670667
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -35.6707     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.400222
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    21.4002     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1523.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.151400
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    12.1514     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =     -40.691400
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -40.6914     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.747300
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.7473     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1535.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      13.151333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    13.1513     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -39.335778
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -39.3358     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      25.328667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    25.3287     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1545.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.417333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.4173     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -41.749083
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -41.7491     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      23.941500
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    23.9415     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1559.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.260800
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.2608     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.352800
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.3528     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.048400
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.0484     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1571.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.495706
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.4957     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -33.942176
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -33.9422     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.338941
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.3389     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1590.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.146263
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    19.1463     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =     -37.718895
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -37.7189     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     19 atoms have been selected out of   1980
 SHOW: average of selected elements =      28.534579
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    28.5346     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1611.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.841714
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    21.8417     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -39.006000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -39.0060     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.348143
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.3481     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1628.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.543600
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    20.5436     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -35.048600
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -35.0486     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.906800
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.9068     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1635.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.278357
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    21.2784     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =     -38.827500
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -38.8275     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     14 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.759714
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.7597     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      8 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1652.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      17.195500
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    17.1955     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -36.668500
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -36.6685     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.874500
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    15.8745     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1666.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.891333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    16.8913     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =     -29.726556
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -29.7266     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     18 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.935944
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.9359     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1686.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.120000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    15.1200     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -32.392250
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -32.3922     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.349250
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    14.3492     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1700.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      11.841765
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    11.8418     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -36.341529
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -36.3415     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.232353
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    16.2324     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1722.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.761333
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    12.7613     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.891467
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.8915     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.784200
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.7842     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1738.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      12.856529
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    12.8565     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -26.960353
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -26.9604     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      17.580588
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    17.5806     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1757.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =       8.689222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    8.68922     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -30.307111
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -30.3071     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      15.474000
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    15.4740     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1768.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =       7.089222
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    7.08922     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -31.279667
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -31.2797     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      19.373889
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    19.3739     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1779.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       8.854176
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    8.85418     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -27.744412
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -27.7444     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.008765
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.0088     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1798.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =       7.117200
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    7.11720     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -25.330267
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -25.3303     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.559133
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    16.5591     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1814.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =       2.977000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    2.97700     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -28.967000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -28.9670     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.837308
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    16.8373     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1828.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       2.323588
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    2.32359     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -28.126000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -28.1260     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.775059
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.7751     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1847.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =       2.295750
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    2.29575     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =     -22.751833
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -22.7518     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     12 atoms have been selected out of   1980
 SHOW: average of selected elements =      20.576667
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    20.5767     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      6 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1861.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =       1.418765
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to    1.41876     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -24.538824
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -24.5388     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      14.785176
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    14.7852     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1883.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      -1.706267
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -1.70627     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =     -27.996867
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -27.9969     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     15 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.463733
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.4637     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      9 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1899.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      -2.416846
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -2.41685     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =     -25.010692
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -25.0107     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     13 atoms have been selected out of   1980
 SHOW: average of selected elements =      22.090692
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    22.0907     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      7 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1913.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      -3.002000
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -3.00200     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =     -21.298000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -21.2980     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      9 atoms have been selected out of   1980
 SHOW: average of selected elements =      18.927556
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    18.9276     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      5 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1923.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      -6.728700
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -6.72870     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =     -23.222800
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -23.2228     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     10 atoms have been selected out of   1980
 SHOW: average of selected elements =      16.576800
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    16.5768     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      4 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1935.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      -7.632294
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -7.63229     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =     -24.706412
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -24.7064     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     17 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.798824
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    21.7988     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     11 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1954.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      -7.735200
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -7.73520     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =     -19.430000
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -19.4300     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:      5 atoms have been selected out of   1980
 SHOW: average of selected elements =      21.100400
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    21.1004     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:      3 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 FOR ID LOOP: symbol ID set to    1961.00     (real)
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 SELRPN:     16 atoms have been selected out of   1980
 SHOW: average of selected elements =      -4.620063
 CNSsolve>       evaluate ($ave_x=$result) 
 EVALUATE: symbol $AVE_X set to   -4.62006     (real)
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 SELRPN:     16 atoms have been selected out of   1980
 SHOW: average of selected elements =     -20.320063
 CNSsolve>       evaluate ($ave_y=$result) 
 EVALUATE: symbol $AVE_Y set to   -20.3201     (real)
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 SELRPN:     16 atoms have been selected out of   1980
 SHOW: average of selected elements =      24.172438
 CNSsolve>       evaluate ($ave_z=$result) 
 EVALUATE: symbol $AVE_Z set to    24.1724     (real)
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 SELRPN:     13 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve>     for $id in id (tag and byres(store1)) loop avco 
 CNSsolve> 
 CNSsolve>       show ave(x) (byres(id $id) and known) 
 CNSsolve>       evaluate ($ave_x=$result) 
 CNSsolve>       show ave(y) (byres(id $id) and known) 
 CNSsolve>       evaluate ($ave_y=$result) 
 CNSsolve>       show ave(z) (byres(id $id) and known) 
 CNSsolve>       evaluate ($ave_z=$result) 
 CNSsolve> 
 CNSsolve>       do (x=$ave_x) (byres(id $id) and store1) 
 CNSsolve>       do (y=$ave_y) (byres(id $id) and store1) 
 CNSsolve>       do (z=$ave_z) (byres(id $id) and store1) 
 CNSsolve> 
 CNSsolve>     end loop avco 
 CNSsolve> 
 CNSsolve>     do (x=x+random(2.0)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (y=y+random(2.0)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (z=z+random(2.0)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     {- start parameter for the side chain building -} 
 CNSsolve>     parameter 
 PARRDR>       nbonds 
 NBDSET>         rcon=20. nbxmod=-2 repel=0.9  wmin=0.1 tolerance=1. 
 NBDSET>         rexp=2 irexp=2 inhibit=0.25 
 NBDSET>       end 
 PARRDR>     end 
 CNSsolve> 
 CNSsolve>     {- Friction coefficient, in 1/ps. -} 
 CNSsolve>     do (fbeta=100) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     evaluate ($bath=300.0) 
 EVALUATE: symbol $BATH set to    300.000     (real)
 CNSsolve>     evaluate ($nstep=500) 
 EVALUATE: symbol $NSTEP set to    500.000     (real)
 CNSsolve>     evaluate ($timestep=0.0005) 
 EVALUATE: symbol $TIMESTEP set to   0.500000E-03 (real)
 CNSsolve> 
 CNSsolve>     do (refy=mass) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     do (mass=20) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     igroup interaction 
 SELRPN>       (store1) (store1 or known) 
 SELRPN:    995 atoms have been selected out of   1980
 SELRPN:   1980 atoms have been selected out of   1980
 IGROup>     end 
 CNSsolve> 
 CNSsolve>     {- turn on initial energy terms -} 
 CNSsolve>     flags exclude * include bond angle vdw end 
 CNSsolve> 
 CNSsolve>     minimize powell nstep=50  nprint=10 end 
 POWELL: number of degrees of freedom=  2985
 NBONDS: generating intra-molecular exclusion list with mode=-2
 MAKINB: mode  -2 found    995 exclusions and      0 interactions(1-4)
 %atoms "    -27  -LEU -HA  " and "    -27  -LEU -HD21" only  0.09 A apart
 %atoms "    -30  -PRO -HB1 " and "    -30  -PRO -HD2 " only  0.05 A apart
 %atoms "    -40  -PHE -HN  " and "    -40  -PHE -HB2 " only  0.04 A apart
 %atoms "    -41  -LEU -HD11" and "    -41  -LEU -HD23" only  0.06 A apart
 %atoms "    -60  -PRO -HB1 " and "    -60  -PRO -HD2 " only  0.08 A apart
 %atoms "    -65  -LYS -HG2 " and "    -65  -LYS -HE2 " only  0.07 A apart
 %atoms "    -86  -GLY -HN  " and "    -86  -GLY -CA  " only  0.04 A apart
 %atoms "    -102 -TYR -HA  " and "    -102 -TYR -HE1 " only  0.06 A apart
 %atoms "    -109 -LYS -HG2 " and "    -109 -LYS -HE1 " only  0.07 A apart
 NBONDS: found    82353 intra-atom interactions
 NBONDS: found        9 nonbonded violations
 %atoms "    -26  -VAL -HN  " and "    -26  -VAL -HG13" only  0.06 A apart
 %atoms "    -58  -LEU -HN  " and "    -58  -LEU -HB2 " only  0.05 A apart
 %atoms "    -91  -LEU -HB1 " and "    -91  -LEU -HD12" only  0.08 A apart
 NBONDS: found    80874 intra-atom interactions
 NBONDS: found        3 nonbonded violations
 NBONDS: found    75019 intra-atom interactions
 %atoms "    -52  -CYS -HN  " and "    -52  -CYS -HA  " only  0.10 A apart
 NBONDS: found    77370 intra-atom interactions
 NBONDS: found        1 nonbonded violations
 NBONDS: found    74371 intra-atom interactions
 NBONDS: found    75029 intra-atom interactions
 --------------- cycle=    10 ------ stepsize=    0.0004 -----------------------
 | Etotal =0.11E+07   grad(E)=868.518    E(BOND)=281879.408 E(ANGL)=297420.694 |
 | E(VDW )=526726.307                                                          |
 -------------------------------------------------------------------------------
 NBONDS: found    75167 intra-atom interactions
 NBONDS: found    75075 intra-atom interactions
 NBONDS: found    75056 intra-atom interactions
 NBONDS: found    75301 intra-atom interactions
 NBONDS: found    75409 intra-atom interactions
 --------------- cycle=    20 ------ stepsize=    0.0004 -----------------------
 | Etotal =459183.418 grad(E)=516.446    E(BOND)=110581.442 E(ANGL)=65730.390  |
 | E(VDW )=282871.586                                                          |
 -------------------------------------------------------------------------------
 NBONDS: found    75518 intra-atom interactions
 NBONDS: found    75592 intra-atom interactions
 --------------- cycle=    30 ------ stepsize=    0.0004 -----------------------
 | Etotal =412200.910 grad(E)=491.646    E(BOND)=111378.668 E(ANGL)=50484.443  |
 | E(VDW )=250337.798                                                          |
 -------------------------------------------------------------------------------
 NBONDS: found    75634 intra-atom interactions
 NBONDS: found    75647 intra-atom interactions
 --------------- cycle=    40 ------ stepsize=    0.0006 -----------------------
 | Etotal =407105.514 grad(E)=491.812    E(BOND)=112154.453 E(ANGL)=49103.324  |
 | E(VDW )=245847.737                                                          |
 -------------------------------------------------------------------------------
 NBONDS: found    75614 intra-atom interactions
 --------------- cycle=    50 ------ stepsize=    0.0005 -----------------------
 | Etotal =404652.451 grad(E)=490.059    E(BOND)=111313.458 E(ANGL)=48553.991  |
 | E(VDW )=244785.001                                                          |
 -------------------------------------------------------------------------------
 POWELL: STEP number limit. Normal termination
 POWELL: Current coordinates set to last minimum
 CNSsolve> 
 CNSsolve>     do (vx=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vy=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vz=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     flags exclude vdw include impr end 
 CNSsolve> 
 CNSsolve>     dynamics cartesian 
 Cartesian Dynamics>       nstep=50 
 Cartesian Dynamics>       timestep=$timestep 
 Cartesian Dynamics>       tcoupling=true temperature=$bath 
 DCART: temperature coupling (TCOUpling) enabled
 Cartesian Dynamics>       nprint=$nstep 
 Cartesian Dynamics>       cmremove=false 
 Cartesian Dynamics>     end 
 -------------------------- Cartesian dynamics start ---------------------------
 | E(kin)+E(total)=691884.271      E(kin)=908.766       temperature=306.406    |
 | Etotal =690975.505 grad(E)=649.003    E(BOND)=111313.458 E(ANGL)=48553.991  |
 | E(IMPR)=531108.055                                                          |
 -------------------------------------------------------------------------------
 -------------------- final step=    50 at      0.02500 ps ---------------------
 | E(kin)+E(total)=409681.811      E(kin)=69955.308     temperature=23586.675  |
 | Etotal =339726.503 grad(E)=368.808    E(BOND)=49536.173  E(ANGL)=122359.711 |
 | E(IMPR)=167830.618                                                          |
 -------------------------------------------------------------------------------
 CENMAS: Information about center of free masses
         position [A]          :      9.80719    -28.12266     24.22615
         velocity [A/ps]       :      1.23481      0.66370      1.74293
         ang. mom. [amu A/ps]  :-181260.71542  63419.14966-320356.64002
         kin. ener. [Kcal/mol] :    118.97844
 CNSsolve> 
 CNSsolve>     flags include vdw end 
 CNSsolve> 
 CNSsolve>     minimize powell nstep=50 nprint=10 end 
 POWELL: number of degrees of freedom=  2985
 NBONDS: found    75839 intra-atom interactions
 NBONDS: found    74742 intra-atom interactions
 NBONDS: found    75014 intra-atom interactions
 NBONDS: found    74878 intra-atom interactions
 --------------- cycle=    10 ------ stepsize=   -0.0002 -----------------------
 | Etotal =591599.938 grad(E)=541.461    E(BOND)=135866.802 E(ANGL)=72828.484  |
 | E(IMPR)=190700.790 E(VDW )=192203.862                                       |
 -------------------------------------------------------------------------------
 NBONDS: found    75220 intra-atom interactions
 NBONDS: found    75202 intra-atom interactions
 --------------- cycle=    20 ------ stepsize=   -0.0001 -----------------------
 | Etotal =500798.180 grad(E)=458.290    E(BOND)=99874.151  E(ANGL)=31299.916  |
 | E(IMPR)=169892.737 E(VDW )=199731.376                                       |
 -------------------------------------------------------------------------------
 NBONDS: found    75220 intra-atom interactions
 --------------- cycle=    30 ------ stepsize=    0.0000 -----------------------
 | Etotal =496717.335 grad(E)=456.240    E(BOND)=99103.140  E(ANGL)=29290.173  |
 | E(IMPR)=170364.290 E(VDW )=197959.732                                       |
 -------------------------------------------------------------------------------
 NBONDS: found    75189 intra-atom interactions
 NBONDS: found    75196 intra-atom interactions
 --------------- cycle=    40 ------ stepsize=    0.0001 -----------------------
 | Etotal =495061.351 grad(E)=457.099    E(BOND)=99585.609  E(ANGL)=28617.423  |
 | E(IMPR)=169710.956 E(VDW )=197147.363                                       |
 -------------------------------------------------------------------------------
 --------------- cycle=    50 ------ stepsize=    0.0002 -----------------------
 | Etotal =494278.927 grad(E)=456.166    E(BOND)=99232.659  E(ANGL)=28597.617  |
 | E(IMPR)=169026.071 E(VDW )=197422.580                                       |
 -------------------------------------------------------------------------------
 POWELL: STEP number limit. Normal termination
 POWELL: Current coordinates set to last minimum
 CNSsolve> 
 CNSsolve>     do (vx=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vy=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vz=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     dynamics cartesian 
 Cartesian Dynamics>       nstep=50 
 Cartesian Dynamics>       timestep=$timestep 
 Cartesian Dynamics>       tcoupling=true temperature=$bath 
 DCART: temperature coupling (TCOUpling) enabled
 Cartesian Dynamics>       nprint=$nstep 
 Cartesian Dynamics>       cmremove=false 
 Cartesian Dynamics>     end 
 -------------------------- Cartesian dynamics start ---------------------------
 | E(kin)+E(total)=495189.328      E(kin)=910.401       temperature=306.958    |
 | Etotal =494278.927 grad(E)=456.166    E(BOND)=99232.659  E(ANGL)=28597.617  |
 | E(IMPR)=169026.071 E(VDW )=197422.580                                       |
 -------------------------------------------------------------------------------
 NBONDS: found    75192 intra-atom interactions
 -------------------- final step=    50 at      0.02500 ps ---------------------
 | E(kin)+E(total)=495480.262      E(kin)=1300.807      temperature=438.590    |
 | Etotal =494179.455 grad(E)=456.980    E(BOND)=99622.883  E(ANGL)=29123.681  |
 | E(IMPR)=167936.147 E(VDW )=197496.744                                       |
 -------------------------------------------------------------------------------
 CENMAS: Information about center of free masses
         position [A]          :      9.81844    -28.11402     24.23216
         velocity [A/ps]       :     -0.04446     -0.07959      0.07209
         ang. mom. [amu A/ps]  :  -8528.09155   3514.94864  33914.93964
         kin. ener. [Kcal/mol] :      0.32124
 CNSsolve> 
 CNSsolve>     parameter 
 PARRDR>       nbonds 
 NBDSET>         rcon=2. nbxmod=-3 repel=0.75 
 NBDSET>       end 
 PARRDR>     end 
 CNSsolve> 
 CNSsolve>     minimize powell nstep=100 nprint=25 end 
 POWELL: number of degrees of freedom=  2985
 NBONDS: generating intra-molecular exclusion list with mode=-3
 MAKINB: mode  -3 found   3256 exclusions and      0 interactions(1-4)
 NBONDS: found    72948 intra-atom interactions
 NBONDS: found    74325 intra-atom interactions
 NBONDS: found    74259 intra-atom interactions
 NBONDS: found    74362 intra-atom interactions
 NBONDS: found    74491 intra-atom interactions
 NBONDS: found    74504 intra-atom interactions
 NBONDS: found    74439 intra-atom interactions
 --------------- cycle=    25 ------ stepsize=    0.0005 -----------------------
 | Etotal =93771.459  grad(E)=106.864    E(BOND)=2649.001   E(ANGL)=31817.449  |
 | E(IMPR)=59169.308  E(VDW )=135.701                                          |
 -------------------------------------------------------------------------------
 NBONDS: found    74359 intra-atom interactions
 NBONDS: found    74343 intra-atom interactions
 NBONDS: found    74335 intra-atom interactions
 NBONDS: found    74433 intra-atom interactions
 NBONDS: found    74442 intra-atom interactions
 --------------- cycle=    50 ------ stepsize=    0.0001 -----------------------
 | Etotal =37175.116  grad(E)=57.431     E(BOND)=1480.706   E(ANGL)=13720.704  |
 | E(IMPR)=21899.274  E(VDW )=74.432                                           |
 -------------------------------------------------------------------------------
 NBONDS: found    74408 intra-atom interactions
 NBONDS: found    74402 intra-atom interactions
 NBONDS: found    74407 intra-atom interactions
 NBONDS: found    74470 intra-atom interactions
 NBONDS: found    74439 intra-atom interactions
 --------------- cycle=    75 ------ stepsize=    0.0007 -----------------------
 | Etotal =4714.527   grad(E)=58.054     E(BOND)=449.390    E(ANGL)=3343.861   |
 | E(IMPR)=891.935    E(VDW )=29.340                                           |
 -------------------------------------------------------------------------------
 NBONDS: found    74374 intra-atom interactions
 NBONDS: found    74400 intra-atom interactions
 NBONDS: found    74396 intra-atom interactions
 --------------- cycle=   100 ------ stepsize=    0.0000 -----------------------
 | Etotal =37.896     grad(E)=3.077      E(BOND)=0.118      E(ANGL)=35.355     |
 | E(IMPR)=0.939      E(VDW )=1.484                                            |
 -------------------------------------------------------------------------------
 POWELL: STEP number limit. Normal termination
 POWELL: Current coordinates set to last minimum
 CNSsolve> 
 CNSsolve>     do (vx=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vy=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vz=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     dynamics cartesian 
 Cartesian Dynamics>       nstep=$nstep 
 Cartesian Dynamics>       timestep=$timestep 
 Cartesian Dynamics>       tcoupling=true temperature=$bath 
 DCART: temperature coupling (TCOUpling) enabled
 Cartesian Dynamics>       nprint=$nstep 
 Cartesian Dynamics>       cmremove=false 
 Cartesian Dynamics>     end 
 -------------------------- Cartesian dynamics start ---------------------------
 | E(kin)+E(total)=936.329         E(kin)=898.433       temperature=302.923    |
 | Etotal =37.896     grad(E)=3.077      E(BOND)=0.118      E(ANGL)=35.355     |
 | E(IMPR)=0.939      E(VDW )=1.484                                            |
 -------------------------------------------------------------------------------
 NBONDS: found    74379 intra-atom interactions
 NBONDS: found    74379 intra-atom interactions
 NBONDS: found    74383 intra-atom interactions
 NBONDS: found    74313 intra-atom interactions
 NBONDS: found    74349 intra-atom interactions
 -------------------- final step=   500 at      0.25000 ps ---------------------
 | E(kin)+E(total)=1580.819        E(kin)=1002.162      temperature=337.897    |
 | Etotal =578.657    grad(E)=27.936     E(BOND)=136.620    E(ANGL)=352.065    |
 | E(IMPR)=74.867     E(VDW )=15.105                                           |
 -------------------------------------------------------------------------------
 CENMAS: Information about center of free masses
         position [A]          :      9.80031    -28.10907     24.22891
         velocity [A/ps]       :     -0.04680      0.09022     -0.02428
         ang. mom. [amu A/ps]  :  28141.23027 -20266.03897 -24106.38838
         kin. ener. [Kcal/mol] :      0.25968
 CNSsolve> 
 CNSsolve>     {- turn on all energy terms -} 
 CNSsolve>     flags include dihe ? end 
 EFLAGS: the following energy flags are set
 EFLAGS: BOND ANGL DIHE IMPR VDW 
 CNSsolve> 
 CNSsolve>     {- set repel to ~vdw radii -} 
 CNSsolve>     parameter 
 PARRDR>       nbonds 
 NBDSET>         repel=0.89 
 NBDSET>       end 
 PARRDR>     end 
 CNSsolve> 
 CNSsolve>     minimize powell nstep=500 nprint=50 end 
 POWELL: number of degrees of freedom=  2985
 NBONDS: generating intra-molecular exclusion list with mode=-3
 MAKINB: mode  -3 found   3256 exclusions and      0 interactions(1-4)
 NBONDS: found    74333 intra-atom interactions
 NBONDS: found    74255 intra-atom interactions
 --------------- cycle=    50 ------ stepsize=    0.0000 -----------------------
 | Etotal =2567.094   grad(E)=15.023     E(BOND)=18.520     E(ANGL)=139.694    |
 | E(DIHE)=32.997     E(IMPR)=21.318     E(VDW )=2354.565                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   100 ------ stepsize=   -0.0002 -----------------------
 | Etotal =2481.598   grad(E)=14.567     E(BOND)=16.566     E(ANGL)=129.971    |
 | E(DIHE)=24.728     E(IMPR)=20.425     E(VDW )=2289.907                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   150 ------ stepsize=    0.0002 -----------------------
 | Etotal =2472.403   grad(E)=14.490     E(BOND)=16.416     E(ANGL)=128.795    |
 | E(DIHE)=22.869     E(IMPR)=19.917     E(VDW )=2284.406                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   200 ------ stepsize=    0.0003 -----------------------
 | Etotal =2472.258   grad(E)=14.489     E(BOND)=16.437     E(ANGL)=128.735    |
 | E(DIHE)=22.917     E(IMPR)=19.856     E(VDW )=2284.312                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   250 ------ stepsize=    0.0001 -----------------------
 | Etotal =2472.254   grad(E)=14.490     E(BOND)=16.438     E(ANGL)=128.749    |
 | E(DIHE)=22.896     E(IMPR)=19.873     E(VDW )=2284.298                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   300 ------ stepsize=   -0.0002 -----------------------
 | Etotal =2472.254   grad(E)=14.490     E(BOND)=16.437     E(ANGL)=128.748    |
 | E(DIHE)=22.903     E(IMPR)=19.866     E(VDW )=2284.301                      |
 -------------------------------------------------------------------------------
 POWELL: Gradient converged. Normal termination
 POWELL: Current coordinates set to last minimum
 CNSsolve> 
 CNSsolve>     flags exclude * include bond angl impr dihe vdw end 
 CNSsolve> 
 CNSsolve>     {- return masses to something sensible -} 
 CNSsolve>     do (mass=refy) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     do (vx=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vy=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve>     do (vz=maxwell($bath)) (store1) 
 SELRPN:    995 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve>     dynamics cartesian 
 Cartesian Dynamics>       nstep=$nstep 
 Cartesian Dynamics>       timestep=$timestep 
 Cartesian Dynamics>       tcoupling=true temperature=$bath 
 DCART: temperature coupling (TCOUpling) enabled
 Cartesian Dynamics>       nprint=$nstep 
 Cartesian Dynamics>       cmremove=false 
 Cartesian Dynamics>     end 
 -------------------------- Cartesian dynamics start ---------------------------
 | E(kin)+E(total)=3382.812        E(kin)=910.558       temperature=307.011    |
 | Etotal =2472.254   grad(E)=14.490     E(BOND)=16.437     E(ANGL)=128.747    |
 | E(DIHE)=22.903     E(IMPR)=19.866     E(VDW )=2284.301                      |
 -------------------------------------------------------------------------------
 NBONDS: found    74225 intra-atom interactions
 NBONDS: found    74269 intra-atom interactions
 NBONDS: found    74256 intra-atom interactions
 NBONDS: found    74185 intra-atom interactions
 NBONDS: found    74263 intra-atom interactions
 NBONDS: found    74193 intra-atom interactions
 NBONDS: found    74184 intra-atom interactions
 NBONDS: found    74189 intra-atom interactions
 NBONDS: found    74246 intra-atom interactions
 NBONDS: found    74268 intra-atom interactions
 NBONDS: found    74258 intra-atom interactions
 NBONDS: found    74218 intra-atom interactions
 -------------------- final step=   500 at      0.25000 ps ---------------------
 | E(kin)+E(total)=4259.610        E(kin)=898.292       temperature=302.875    |
 | Etotal =3361.318   grad(E)=37.068     E(BOND)=257.171    E(ANGL)=590.104    |
 | E(DIHE)=29.028     E(IMPR)=125.269    E(VDW )=2359.746                      |
 -------------------------------------------------------------------------------
 CENMAS: Information about center of free masses
         position [A]          :      9.40817    -27.82012     24.13526
         velocity [A/ps]       :     -1.22895      0.09319      0.57564
         ang. mom. [amu A/ps]  :   1866.44362   3321.27137  -5182.92498
         kin. ener. [Kcal/mol] :      2.28408
 CNSsolve> 
 CNSsolve>     {- some final minimisation -} 
 CNSsolve>     minimize powell 
 POWELL>       nstep=500 
 POWELL>       drop=40.0 
 POWELL>       nprint=50 
 POWELL>     end 
 POWELL: number of degrees of freedom=  2985
 --------------- cycle=    50 ------ stepsize=   -0.0004 -----------------------
 | Etotal =2480.659   grad(E)=14.526     E(BOND)=16.672     E(ANGL)=129.495    |
 | E(DIHE)=24.236     E(IMPR)=19.993     E(VDW )=2290.261                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   100 ------ stepsize=   -0.0002 -----------------------
 | Etotal =2476.668   grad(E)=14.524     E(BOND)=16.580     E(ANGL)=129.132    |
 | E(DIHE)=22.912     E(IMPR)=19.859     E(VDW )=2288.185                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   150 ------ stepsize=    0.0003 -----------------------
 | Etotal =2475.748   grad(E)=14.516     E(BOND)=16.637     E(ANGL)=129.109    |
 | E(DIHE)=22.982     E(IMPR)=19.851     E(VDW )=2287.169                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   200 ------ stepsize=   -0.0002 -----------------------
 | Etotal =2475.268   grad(E)=14.515     E(BOND)=16.596     E(ANGL)=129.065    |
 | E(DIHE)=22.918     E(IMPR)=19.896     E(VDW )=2286.793                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   250 ------ stepsize=    0.0006 -----------------------
 | Etotal =2475.231   grad(E)=14.513     E(BOND)=16.603     E(ANGL)=129.046    |
 | E(DIHE)=22.911     E(IMPR)=19.842     E(VDW )=2286.828                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   300 ------ stepsize=   -0.0001 -----------------------
 | Etotal =2475.226   grad(E)=14.513     E(BOND)=16.602     E(ANGL)=129.045    |
 | E(DIHE)=22.901     E(IMPR)=19.863     E(VDW )=2286.814                      |
 -------------------------------------------------------------------------------
 --------------- cycle=   350 ------ stepsize=   -0.0001 -----------------------
 | Etotal =2475.226   grad(E)=14.513     E(BOND)=16.602     E(ANGL)=129.046    |
 | E(DIHE)=22.903     E(IMPR)=19.863     E(VDW )=2286.812                      |
 -------------------------------------------------------------------------------
 POWELL: Gradient converged. Normal termination
 POWELL: Current coordinates set to last minimum
 CNSsolve> 
 CNSsolve>     print thres=0.02 bonds 
 (atom-i        |atom-j        )    dist.   equil.   delta    energy   const. 

 (     23   CG2 |     23   HG23)    1.059    1.080   -0.021    0.439 1000.000
 (     68   CD  |     68   HD1 )    1.058    1.080   -0.022    0.493 1000.000
 Number of violations greater    0.020:     2
 RMS deviation=   0.004
 CNSsolve>     print thres=5. angles 
 (atom-i        |atom-j        |atom-k        )  angle    equil.     delta    energy  const. 

 Number of violations greater    5.000:     0
 RMS deviation=   0.612
 CNSsolve> 
 CNSsolve>   end if 
 CNSsolve> 
 CNSsolve>   fix selection=( none ) end 
 SELRPN:      0 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> set echo=false end 
 SELRPN:      0 atoms have been selected out of   1980
 SHOW: zero atoms selected
 NEXTCD: condition evaluated as true
 SELRPN:      0 atoms have been selected out of   1980
 CNSsolve> 
 CNSsolve> if (&set_bfactor=true) then 
 NEXTCD: condition evaluated as false
 CNSsolve>   do (b=&bfactor) ( all ) 
 CNSsolve> else 
 CNSsolve>   show ave(b) (known and not(store1)) 
 SELRPN:    985 atoms have been selected out of   1980
 SHOW: average of selected elements =      37.602142
 CNSsolve>   do (b=$result) (store1 and (attr b < 0.01)) 
 SELRPN:    293 atoms have been selected out of   1980
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> if (&set_occupancy=true) then 
 NEXTCD: condition evaluated as false
 CNSsolve>   do (q=&occupancy) ( all ) 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> set echo=false end 
 SELRPN:    995 atoms have been selected out of   1980
 SHOW: sum over selected elements =     995.000000
 NEXTCD: condition evaluated as false
 CNSsolve> 
 CNSsolve> set remarks=reset end 
 CNSsolve> set remarks=accumulate end 
 CNSsolve> 
 CNSsolve> buffer message 
 BUFFER>   to=remarks 
 BUFFER>   dump 
 BUFFER> end 
 CNSsolve> 
 CNSsolve> !write structure output=&structure_outfile end 
 CNSsolve> 
 CNSsolve> if ( &pdb_o_format = true ) then 
 NEXTCD: condition evaluated as true
 CNSsolve>   write coordinates format=PDBO output=&coordinate_outfile end 
 ASSFIL: file /farm/data/gliu/projects/HR4495E/cns/calc15/cnsPDB/sa_cns_10.pdb opened.
 CNSsolve> else 
 CNSsolve>   write coordinates output=&coordinate_outfile end 
 CNSsolve> end if 
 CNSsolve> 
 CNSsolve> stop 
 HEAP: maximum use      =     3477424 current use      =           0 bytes
 HEAP: maximum overhead =        1552 current overhead =         128 bytes
          ============================================================
           Maximum dynamic memory allocation:     3477424 bytes
           Maximum dynamic memory overhead:          1552 bytes
           Program started at: 14:05:09 on 13-Sep-2010
           Program stopped at: 14:05:14 on 13-Sep-2010
           CPU time used:       4.8003 seconds
          ============================================================