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SUBROUTINE GPNDV |
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************************************************************************ |
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* * |
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* Volumes definition for the neutron detector * |
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* Called by: GPGEOM * |
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* Author: Francesco Cafagna, 05-sep-05 * |
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* * |
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************************************************************************ |
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#include "gpgeo.inc" |
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#include "gpmed.inc" |
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#include "gpkey.inc" |
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* |
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INTEGER IROT,IVOLU,N,NMED |
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REAL X,Y,Z |
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|
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* |
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* Define the NDBO volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDBO','BOX ',NMED,NDBO, 3,IVOLU) |
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* |
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* Define the NDBX volume |
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* |
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NMED= MAL |
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CALL GSVOLU('NDBX','BOX ',NMED,NDBX, 3,IVOLU) |
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* |
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* Define the NDCD volume |
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* |
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NMED= MCAD |
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CALL GSVOLU('NDCD','BOX ',NMED,NDCD, 3,IVOLU) |
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* |
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* Define the NDBI volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDBI','BOX ',NMED,NDBI, 3,IVOLU) |
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* |
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* Define the NDTU volume |
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* |
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NMED= MIRON |
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NMED= MSCIN |
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CALL GSVOLU('NDTU','TUBE',NMED,NDTU, 3,IVOLU) |
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* |
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* Define the NDTI volume |
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* |
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NMED= MHE3 |
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CALL GSVOLU('NDTI','TUBE',NMED,NDTI, 3,IVOLU) |
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* |
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* Define the NDPB volume |
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* |
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NMED= MCH2 |
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CALL GSVOLU('NDPB','BOX ',NMED,NDPB, 3,IVOLU) |
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* |
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* Define the NDCO volume |
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* |
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NMED= MAL |
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CALL GSVOLU('NDCO','BOX ',NMED,NDCO, 3,IVOLU) |
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* |
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* Define the NDBS volume |
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* |
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NMED= MAL |
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CALL GSVOLU('NDBS','BOX ',NMED,NDBS, 3,IVOLU) |
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* |
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* Define the NDSS volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDSS','BOX ',NMED,NDSS, 3,IVOLU) |
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* |
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* Define the NDCI volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDCI','BOX ',NMED,NDCI, 3,IVOLU) |
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* |
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* Define the NDCM volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDCM','BOX ',NMED,NDCM, 3,IVOLU) |
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* |
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* Define the NDCE volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDCE','BOX ',NMED,NDCE, 3,IVOLU) |
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* |
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* Define the NDSI volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDSI','BOX ',NMED,NDSI, 3,IVOLU) |
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* |
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* Define the NDSM volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDSM','BOX ',NMED,NDSM, 3,IVOLU) |
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* |
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* Define the NDSE volume |
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* |
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NMED= MN2 |
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CALL GSVOLU('NDSE','BOX ',NMED,NDSE, 3,IVOLU) |
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* |
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* Positioning volumes NDTI inside NDTU. |
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* |
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N = 1 |
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X = 0. |
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Y = 0. |
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Z = 0. |
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CALL GSPOS('NDTI',N,'NDTU',X,Y,Z,0,'ONLY') |
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* |
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* Positioning volume NDTU inside the mother NDPB |
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* |
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N = 0 |
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Y = 0. |
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C # |
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C # Start to put tube on top of a cmd and 3 pholyetilene planes |
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C # |
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DO I=1,2 |
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C # |
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cC # Place a tube layer at a 4 mm distance each |
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C # Place a tube layer at a 5 mm distance each |
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C # |
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c X = -NDBI(2) + 0.2 + 1.1 |
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X = -NDBI(1) + 0.3 + NDTU(2) |
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C Z = -NDBI(3) + 2.*NDCD(3) + 3.*(2.*NDPB(3)) + NDTU(2) |
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C + + (I-1)*4*NDPB(3) |
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Z = -NDBI(3)+3.*(2.*NDPB(3))+NDTU(2) |
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+ + (I-1)*2*NDPB(3)+(I-1)*2*NDTU(2) |
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DO II=1,18 |
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N= N + 1 |
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C CALL GSPOS('NDTU',N,'NDBI',X,Y,Z,2,'MANY') |
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CALL GSPOS('NDTU',N,'NDBI',X,Y,Z,2,'ONLY') |
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C X = X + 2.2 |
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X=X+2*NDTU(2)+GNDTU |
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ENDDO |
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ENDDO |
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* |
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* Positioning volume NDPB inside the mother NDBI |
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* |
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N = 0 |
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X = 0. |
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Y = 0. |
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C # |
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C # Stack 3 planes then leave the tube gap between the last two |
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C # |
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DO I=1,3 |
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N= N + 1 |
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c Z = -NDBI(3) + 2.*NDCD(3) + (I-1)*2.*NDPB(3) + NDPB(3) |
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Z=-NDBI(3)+(I-1)*2.*NDPB(3)+NDPB(3) |
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C CALL GSPOS('NDPB',N,'NDBI',X,Y,Z,0,'MANY') |
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CALL GSPOS('NDPB',N,'NDBI',X,Y,Z,0,'ONLY') |
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ENDDO |
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DO I=1,2 |
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C Z = -NDBI(3) + 2.*NDCD(3) + 4.*2.*NDPB(3) + NDPB(3) |
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C + + (I-1)*4.*NDPB(3) |
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Z = -NDBI(3) + 3.*2.*NDPB(3) + NDPB(3) |
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+ + (I-1)*2.*NDPB(3)+I*2*NDTU(2) |
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N= N + 1 |
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C CALL GSPOS('NDPB',N,'NDBI',X,Y,Z,0,'MANY') |
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CALL GSPOS('NDPB',N,'NDBI',X,Y,Z,0,'ONLY') |
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ENDDO |
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C # |
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C # Now put the internal volume inside the cadmium box |
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C # * |
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N = 1 |
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X = 0. |
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Y = 0. |
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Z=-NDCD(3)+NDBI(3)+TNDCD |
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CALL GSPOS('NDBI',N,'NDCD',X,Y,Z,0,'ONLY') |
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C # |
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C # Positioning the NDCD inside NDBX |
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C # |
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N=1 |
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X = 0 |
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Y = 0 |
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Z=-NDBX(3)+NDCD(3)+TNDBX |
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CALL GSPOS('NDCD',N,'NDBX',X,Y,Z,0,'ONLY') |
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C # |
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C # Positioning the NDBX inside NDBO |
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C # |
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N=1 |
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X = 0 |
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Y = 0 |
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Z=-NDBO(3)+NDBX(3) |
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CALL GSPOS('NDBX',N,'NDBO',X,Y,Z,0,'ONLY') |
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C # |
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C # Positioning the NDCM inside NDCO |
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C # |
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N=0 |
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X = 0 |
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Z=NDCO(3)-NDCM(3) |
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DO I=-1,1,2 |
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N=N+1 |
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Y = I*(NDCI(2)+1.4+NDCM(2)) |
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CALL GSPOS('NDCM',N,'NDCO',X,Y,Z,0,'ONLY') |
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ENDDO |
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C # |
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C # Positioning the NDCI inside NDCO |
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C # |
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N=1 |
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X = 0 |
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Y = 0 |
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Z=NDCO(3)-NDCI(3) |
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CALL GSPOS('NDCI',N,'NDCO',X,Y,Z,0,'ONLY') |
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C # |
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C # Positioning the NDCE inside NDCO |
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C # |
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N=0 |
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X = 0 |
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Z=NDCO(3)-NDCE(3) |
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DO I=-1,1,2 |
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N=N+1 |
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Y = I*(NDCI(2)+1.4+2*NDCM(2)+1.4+NDCE(2)) |
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CALL GSPOS('NDCE',N,'NDCO',X,Y,Z,0,'ONLY') |
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ENDDO |
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C # |
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C # Positioning the NDSM inside NDCO |
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C # |
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N=0 |
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Z=NDCO(3)-NDSM(3) |
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DO I=-1,1,2 |
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Y = I*(NDCO(2)-9.6-NDSM(2)) |
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DO j=-1,1,2 |
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N=N+1 |
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X=J*(NDCO(1)-2.9-NDSM(1)) |
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CALL GSPOS('NDSM',N,'NDCO',X,Y,Z,0,'ONLY') |
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ENDDO |
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ENDDO |
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C # |
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C # Positioning the NDSI inside NDCO |
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C # |
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N=0 |
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Z=NDCO(3)-NDSI(3) |
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Y=0. |
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DO j=-1,1,2 |
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N=N+1 |
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X=J*(NDCO(1)-2.9-NDSI(1)) |
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CALL GSPOS('NDSI',N,'NDCO',X,Y,Z,0,'ONLY') |
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ENDDO |
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C # |
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C # Positioning the NDSE inside NDCO |
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C # |
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N=0 |
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Z=NDCO(3)-NDSE(3) |
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DO I=-1,1,2 |
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Y = I*(NDCI(2)+1.4+2*NDCM(2)+1.4+NDSE(2)) |
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DO j=-1,1,2 |
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N=N+1 |
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X=J*(NDCE(1)+1.6+NDSE(1)) |
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CALL GSPOS('NDSE',N,'NDCO',X,Y,Z,0,'ONLY') |
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ENDDO |
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ENDDO |
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C # |
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C # Positioning the NDCO inside NDBO |
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C # |
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N=1 |
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X = 0 |
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Y = 0 |
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Z=NDBO(3)-NDCO(3) |
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CALL GSPOS('NDCO',N,'NDBO',X,Y,Z,0,'ONLY') |
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C # |
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C # Positioning the NDBS inside NDBO |
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C # |
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N=0 |
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DO I=-1,1,2 |
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N=N+1 |
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X = 0. |
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Y = I*NDBO(2)-I*NDBS(2) |
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Z=-NDBO(3)+NDBS(3) |
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CALL GSPOS('NDBS',N,'NDBO',X,Y,Z,0,'ONLY') |
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ENDDO |
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N=1 |
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X = 0. |
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Y = 0. |
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Z=0. |
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CALL GSPOS('NDSS',N,'NDBS',X,Y,Z,0,'ONLY') |
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RETURN |
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END |