Trailing-Edge
-
PDP-10 Archives
-
decuslib20-02
-
decus/20-0026/dlbvp.ssp
There are 2 other files named dlbvp.ssp in the archive. Click here to see a list.
C DLBV 10
C ..................................................................DLBV 20
C DLBV 30
C SUBROUTINE DLBVP DLBV 40
C DLBV 50
C PURPOSE DLBV 60
C TO SOLVE A LINEAR BOUNDARY VALUE PROBLEM, WHICH CONSISTS OF DLBV 70
C A SYSTEM OF NDIM LINEAR FIRST ORDER DIFFERENTIAL EQUATIONS DLBV 80
C DY/DX=A(X)*Y(X)+F(X) DLBV 90
C AND NDIM LINEAR BOUNDARY CONDITIONS DLBV 100
C B*Y(XL)+C*Y(XU)=R. DLBV 110
C DLBV 120
C USAGE DLBV 130
C CALL DLBVP (PRMT,B,C,R,Y,DERY,NDIM,IHLF,AFCT,FCT,DFCT,OUTP, DLBV 140
C AUX,A) DLBV 150
C PARAMETERS AFCT,FCT,DFCT,OUTP REQUIRE AN EXTERNAL STATEMENT.DLBV 160
C DLBV 170
C DESCRIPTION OF PARAMETERS DLBV 180
C PRMT - DOUBLE PRECISION INPUT AND OUTPUT VECTOR WITH DLBV 190
C DIMENSION GREATER THAN OR EQUAL TO 5, WHICH DLBV 200
C SPECIFIES THE PARAMETERS OF THE INTERVAL AND OF DLBV 210
C ACCURACY AND WHICH SERVES FOR COMMUNICATION BETWEENDLBV 220
C OUTPUT SUBROUTINE (FURNISHED BY THE USER) AND DLBV 230
C SUBROUTINE DLBVP. EXCEPT PRMT(5) THE COMPONENTS DLBV 240
C ARE NOT DESTROYED BY SUBROUTINE DLBVP AND THEY ARE DLBV 250
C PRMT(1)- LOWER BOUND XL OF THE INTERVAL (INPUT), DLBV 260
C PRMT(1)- UPPER BOUND XU OF THE INTERVAL (INPUT), DLBV 270
C PRMT(3)- INITIAL INCREMENT OF THE INDEPENDENT VARIABLE DLBV 280
C (INPUT), DLBV 290
C PRMT(4)- UPPER ERROR BOUND (INPUT). IF RELATIVE ERROR IS DLBV 300
C GREATER THAN PRMT(4), INCREMENT GETS HALVED. DLBV 310
C IF INCREMENT IS LESS THAN PRMT(3) AND RELATIVE DLBV 320
C ERROR LESS THAN PRMT(4)/50, INCREMENT GETS DOUBLED.DLBV 330
C THE USER MAY CHANGE PRMT(4) BY MEANS OF HIS DLBV 340
C OUTPUT SUBROUTINE. DLBV 350
C PRMT(5)- NO INPUT PARAMETER. SUBROUTINE DLBVP INITIALIZES DLBV 360
C PRMT(5)=0. IF THE USER WANTS TO TERMINATE DLBV 370
C SUBROUTINE DLBVP AT ANY OUTPUT POINT, HE HAS TO DLBV 380
C CHANGE PRMT(5) TO NON-ZERO BY MEANS OF SUBROUTINE DLBV 390
C OUTP. FURTHER COMPONENTS OF VECTOR PRMT ARE DLBV 400
C FEASIBLE IF ITS DIMENSION IS DEFINED GREATER DLBV 410
C THAN 5. HOWEVER SUBROUTINE DLBVP DOES NOT REQUIRE DLBV 420
C AND CHANGE THEM. NEVERTHELESS THEY MAY BE USEFUL DLBV 430
C FOR HANDING RESULT VALUES TO THE MAIN PROGRAM DLBV 440
C (CALLING DLBVP) WHICH ARE OBTAINED BY SPECIAL DLBV 450
C MANIPULATIONS WITH OUTPUT DATA IN SUBROUTINE OUTP. DLBV 460
C B - DOUBLE PRECISION NDIM BY NDIM INPUT MATRIX DLBV 470
C (DESTROYED). IT IS THE COEFFICIENT MATRIX OF Y(XL) DLBV 480
C IN THE BOUNDARY CONDITIONS. DLBV 490
C C - DOUBLE PRECISION NDIM BY NDIM INPUT MATRIX DLBV 500
C (POSSIBLY DESTROYED). IT IS THE COEFFICIENT MATRIX DLBV 510
C OF Y(XU) IN THE BOUNDARY CONDITIONS. DLBV 520
C R - DOUBLE PRECISION INPUT VECTOR WITH DIMENSION NDIM DLBV 530
C (DESTROYED). IT SPECIFIES THE RIGHT HAND SIDE OF DLBV 540
C THE BOUNDARY CONDITIONS. DLBV 550
C Y - DOUBLE PRECISION AUXILIARY VECTOR WITH DLBV 560
C DIMENSION NDIM. IT IS USED AS STORAGE LOCATION DLBV 570
C FOR THE RESULTING VALUES OF DEPENDENT VARIABLES DLBV 580
C COMPUTED AT INTERMEDIATE POINTS X. DLBV 590
C DERY - DOUBLE PRECISION INPUT VECTOR OF ERROR WEIGHTS DLBV 600
C (DESTROYED). ITS MAXIMAL COMPONENT SHOULD BE DLBV 610
C EQUAL TO 1. LATERON DERY IS THE VECTOR OF DLBV 620
C DERIVATIVES, WHICH BELONG TO FUNCTION VALUES Y AT DLBV 630
C INTERMEDIATE POINTS X. DLBV 640
C NDIM - AN INPUT VALUE, WHICH SPECIFIES THE NUMBER OF DLBV 650
C DIFFERENTIAL EQUATIONS IN THE SYSTEM. DLBV 660
C IHLF - AN OUTPUT VALUE, WHICH SPECIFIES THE NUMBER OF DLBV 670
C BISECTIONS OF THE INITIAL INCREMENT. IF IHLF GETS DLBV 680
C GREATER THAN 10, SUBROUTINE DLBVP RETURNS WITH DLBV 690
C ERROR MESSAGE IHLF=11 INTO MAIN PROGRAM. DLBV 700
C ERROR MESSAGE IHLF=12 OR IHLF=13 APPEARS IN CASE DLBV 710
C PRMT(3)=0 OR IN CASE SIGN(PRMT(3)).NE.SIGN(PRMT(2)-DLBV 720
C PRMT(1)) RESPECTIVELY. FINALLY ERROR MESSAGE DLBV 730
C IHLF=14 INDICATES, THAT THERE IS NO SOLUTION OR DLBV 740
C THAT THERE ARE MORE THAN ONE SOLUTION OF THE DLBV 750
C PROBLEM. DLBV 760
C A NEGATIVE VALUE OF IHLF HANDED TO SUBROUTINE OUTP DLBV 770
C TOGETHER WITH INITIAL VALUES OF FINALLY GENERATED DLBV 780
C INITIAL VALUE PROBLEM INDICATES, THAT THERE WAS DLBV 790
C POSSIBLE LOSS OF SIGNIFICANCE IN THE SOLUTION OF DLBV 800
C THE SYSTEM OF SIMULTANEOUS LINEAR EQUATIONS FOR DLBV 810
C THESE INITIAL VALUES. THE ABSOLUTE VALUE OF IHLF DLBV 820
C SHOWS, AFTER WHICH ELIMINATION STEP OF GAUSS DLBV 830
C ALGORITHM POSSIBLE LOSS OF SIGNIFICANCE WAS DLBV 840
C DETECTED. DLBV 850
C AFCT - THE NAME OF AN EXTERNAL SUBROUTINE USED. IT DLBV 860
C COMPUTES THE COEFFICIENT MATRIX A OF VECTOR Y ON DLBV 870
C THE RIGHT HAND SIDE OF THE SYSTEM OF DIFFERENTIAL DLBV 880
C EQUATIONS FOR A GIVEN X-VALUE. ITS PARAMETER LIST DLBV 890
C MUST BE X,A. SUBROUTINE AFCT SHOULD NOT DESTROY X. DLBV 900
C FCT - THE NAME OF AN EXTERNAL SUBROUTINE USED. IT DLBV 910
C COMPUTES VECTOR F (INHOMOGENEOUS PART OF THE DLBV 920
C RIGHT HAND SIDE OF THE SYSTEM OF DIFFERENTIAL DLBV 930
C EQUATIONS) FOR A GIVEN X-VALUE. ITS PARAMETER LIST DLBV 940
C MUST BE X,F. SUBROUTINE FCT SHOULD NOT DESTROY X. DLBV 950
C DFCT - THE NAME OF AN EXTERNAL SUBROUTINE USED. IT DLBV 960
C COMPUTES VECTOR DF (DERIVATIVE OF THE INHOMOGENEOUSDLBV 970
C PART ON THE RIGHT HAND SIDE OF THE SYSTEM OF DLBV 980
C DIFFERENTIAL EQUATIONS) FOR A GIVEN X-VALUE. ITS DLBV 990
C PARAMETER LIST MUST BE X,DF. SUBROUTINE DFCT DLBV1000
C SHOULD NOT DESTROY X. DLBV1010
C OUTP - THE NAME OF AN EXTERNAL OUTPUT SUBROUTINE USED. DLBV1020
C ITS PARAMETER LIST MUST BE X,Y,DERY,IHLF,NDIM,PRMT.DLBV1030
C NONE OF THESE PARAMETERS (EXCEPT, IF NECESSARY, DLBV1040
C PRMT(4),PRMT(5),...) SHOULD BE CHANGED BY DLBV1050
C SUBROUTINE OUTP. IF PRMT(5) IS CHANGED TO NON-ZERO,DLBV1060
C SUBROUTINE DLBVP IS TERMINATED. DLBV1070
C AUX - DOUBLE PRECISION AUXILIARY STORAGE ARRAY WITH 20 DLBV1080
C ROWS AND NDIM COLUMNS. DLBV1090
C A - DOUBLE PRECISION NDIM BY NDIM MATRIX, WHICH IS USEDDLBV1100
C AS AUXILIARY STORAGE ARRAY. DLBV1110
C DLBV1120
C REMARKS DLBV1130
C THE PROCEDURE TERMINATES AND RETURNS TO CALLING PROGRAM, IF DLBV1140
C (1) MORE THAN 10 BISECTIONS OF THE INITIAL INCREMENT ARE DLBV1150
C NECESSARY TO GET SATISFACTORY ACCURACY (ERROR MESSAGE DLBV1160
C IHLF=11), DLBV1170
C (2) INITIAL INCREMENT IS EQUAL TO 0 OR IF IT HAS WRONG SIGN DLBV1180
C (ERROR MESSAGES IHLF=12 OR IHLF=13), DLBV1190
C (3) THERE IS NO OR MORE THAN ONE SOLUTION OF THE PROBLEM DLBV1200
C (ERROR MESSAGE IHLF=14), DLBV1210
C (4) THE WHOLE INTEGRATION INTERVAL IS WORKED THROUGH, DLBV1220
C (5) SUBROUTINE OUTP HAS CHANGED PRMT(5) TO NON-ZERO. DLBV1230
C DLBV1240
C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED DLBV1250
C SUBROUTINE DGELG SYSTEM OF LINEAR EQUATIONS. DLBV1260
C THE EXTERNAL SUBROUTINES AFCT(X,A), FCT(X,F), DFCT(X,DF), DLBV1270
C AND OUTP(X,Y,DERY,IHLF,NDIM,PRMT) MUST BE FURNISHED DLBV1280
C BY THE USER. DLBV1290
C DLBV1300
C METHOD DLBV1310
C EVALUATION IS DONE USING THE METHOD OF ADJOINT EQUATIONS. DLBV1320
C HAMMINGS FOURTH ORDER MODIFIED PREDICTOR-CORRECTOR METHOD DLBV1330
C IS USED TO SOLVE THE ADJOINT INITIAL VALUE PROBLEMS AND FI- DLBV1340
C NALLY TO SOLVE THE GENERATED INITIAL VALUE PROBLEM FOR Y(X).DLBV1350
C THE INITIAL INCREMENT PRMT(3) IS AUTOMATICALLY ADJUSTED. DLBV1360
C FOR COMPUTATION OF INTEGRAL SUM, A FOURTH ORDER HERMITEAN DLBV1370
C INTEGRATION FORMULA IS USED. DLBV1380
C FOR REFERENCE, SEE DLBV1390
C (1) LANCE, NUMERICAL METHODS FOR HIGH SPEED COMPUTERS, DLBV1400
C ILIFFE, LONDON, 1960, PP.64-67. DLBV1410
C (2) RALSTON/WILF, MATHEMATICAL METHODS FOR DIGITAL DLBV1420
C COMPUTERS, WILEY, NEW YORK/LONDON, 1960, PP.95-109. DLBV1430
C (3) RALSTON, RUNGE-KUTTA METHODS WITH MINIMUM ERROR BOUNDS, DLBV1440
C MTAC, VOL.16, ISS.80 (1962), PP.431-437. DLBV1450
C (4) ZURMUEHL, PRAKTISCHE MATHEMATIK FUER INGENIEURE UND DLBV1460
C PHYSIKER, SPRINGER, BERLIN/GOETTINGEN/HEIDELBERG, 1963, DLBV1470
C PP.227-232. DLBV1480
C DLBV1490
C ..................................................................DLBV1500
C DLBV1510
0SUBROUTINE DLBVP(PRMT,B,C,R,Y,DERY,NDIM,IHLF,AFCT,FCT,DFCT,OUTP, DLBV1520
1AUX,A) DLBV1530
C DLBV1540
C DLBV1550
DIMENSION PRMT(1),B(1),C(1),R(1),Y(1),DERY(1),AUX(20,1),A(1) DLBV1560
DOUBLE PRECISION PRMT,B,C,R,Y,DERY,AUX,A,H,X,Z,GL,HS,GU,SUM, DLBV1570
1DGL,DGU,XST,XEND,DELT DLBV1580
C DLBV1590
C ERROR TEST DLBV1600
IF(PRMT(3)*(PRMT(2)-PRMT(1)))2,1,3 DLBV1610
1 IHLF=12 DLBV1620
RETURN DLBV1630
2 IHLF=13 DLBV1640
RETURN DLBV1650
C DLBV1660
C SEARCH FOR ZERO-COLUMNS IN MATRICES B AND C DLBV1670
3 KK=-NDIM DLBV1680
IB=0 DLBV1690
IC=0 DLBV1700
DO 7 K=1,NDIM DLBV1710
AUX(15,K)=DERY(K) DLBV1720
AUX(1,K)=1.D0 DLBV1730
AUX(17,K)=1.D0 DLBV1740
KK=KK+NDIM DLBV1750
DO 4 I=1,NDIM DLBV1760
II=KK+I DLBV1770
IF(B(II))5,4,5 DLBV1780
4 CONTINUE DLBV1790
IB=IB+1 DLBV1800
AUX(1,K)=0.D0 DLBV1810
5 DO 6 I=1,NDIM DLBV1820
II=KK+I DLBV1830
IF(C(II))7,6,7 DLBV1840
6 CONTINUE DLBV1850
IC=IC+1 DLBV1860
AUX(17,K)=0.D0 DLBV1870
7 CONTINUE DLBV1880
C DLBV1890
C DETERMINATION OF LOWER AND UPPER BOUND DLBV1900
IF(IC-IB)8,11,11 DLBV1910
8 H=PRMT(2) DLBV1920
PRMT(2)=PRMT(1) DLBV1930
PRMT(1)=H DLBV1940
PRMT(3)=-PRMT(3) DLBV1950
DO 9 I=1,NDIM DLBV1960
9 AUX(17,I)=AUX(1,I) DLBV1970
II=NDIM*NDIM DLBV1980
DO 10 I=1,II DLBV1990
H=B(I) DLBV2000
B(I)=C(I) DLBV2010
10 C(I)=H DLBV2020
C DLBV2030
C PREPARATIONS FOR CONSTRUCTION OF ADJOINT INITIAL VALUE PROBLEMS DLBV2040
11 X=PRMT(2) DLBV2050
CALL FCT(X,Y) DLBV2060
CALL DFCT(X,DERY) DLBV2070
DO 12 I=1,NDIM DLBV2080
AUX(18,I)=Y(I) DLBV2090
12 AUX(19,I)=DERY(I) DLBV2100
C DLBV2110
C POSSIBLE BREAK-POINT FOR LINKAGE DLBV2120
C DLBV2130
C THE FOLLOWING PART OF SUBROUTINE DLBVP UNTIL NEXT BREAK-POINT FOR DLBV2140
C LINKAGE HAS TO REMAIN IN CORE DURING THE WHOLE REST OF THE DLBV2150
C COMPUTATIONS DLBV2160
C DLBV2170
C START LOOP FOR GENERATING ADJOINT INITIAL VALUE PROBLEMS DLBV2180
K=0 DLBV2190
KK=0 DLBV2200
100 K=K+1 DLBV2210
IF(AUX(17,K))108,108,101 DLBV2220
C DLBV2230
C INITIALIZATION OF ADJOINT INITIAL VALUE PROBLEM DLBV2240
101 X=PRMT(2) DLBV2250
CALL AFCT(X,A) DLBV2260
SUM=0.D0 DLBV2270
GL=AUX(18,K) DLBV2280
DGL=AUX(19,K) DLBV2290
II=K DLBV2300
DO 104 I=1,NDIM DLBV2310
H=-A(II) DLBV2320
DERY(I)=H DLBV2330
AUX(20,I)=R(I) DLBV2340
Y(I)=0.D0 DLBV2350
IF(I-K)103,102,103 DLBV2360
102 Y(I)=1.D0 DLBV2370
103 DGL=DGL+H*AUX(18,I) DLBV2380
104 II=II+NDIM DLBV2390
XEND=PRMT(1) DLBV2400
H=.0625D0*(XEND-X) DLBV2410
ISW=0 DLBV2420
GOTO 400 DLBV2430
C THIS IS BRANCH TO ADJOINT LINEAR INITIAL VALUE PROBLEM DLBV2440
C DLBV2450
C THIS IS RETURN FROM ADJOINT LINEAR INITIAL VALUE PROBLEM DLBV2460
105 IF(IHLF-10)106,106,117 DLBV2470
C DLBV2480
C UPDATING OF COEFFICIENT MATRIX B AND VECTOR R DLBV2490
106 DO 107 I=1,NDIM DLBV2500
KK=KK+1 DLBV2510
H=C(KK) DLBV2520
R(I)=AUX(20,I)+H*SUM DLBV2530
II=I DLBV2540
DO 107 J=1,NDIM DLBV2550
B(II)=B(II)+H*Y(J) DLBV2560
107 II=II+NDIM DLBV2570
GOTO 109 DLBV2580
108 KK=KK+NDIM DLBV2590
109 IF(K-NDIM)100,110,110 DLBV2600
C DLBV2610
C DLBV2620
C GENERATION OF LAST INITIAL VALUE PROBLEM DLBV2630
110 EPS=PRMT(4) DLBV2640
CALL DGELG(R,B,NDIM,1,EPS,I) DLBV2650
IF(I)111,112,112 DLBV2660
111 IHLF=14 DLBV2670
RETURN DLBV2680
C DLBV2690
112 PRMT(5)=0.D0 DLBV2700
IHLF=-I DLBV2710
X=PRMT(1) DLBV2720
XEND=PRMT(2) DLBV2730
H=PRMT(3) DLBV2740
DO 113 I=1,NDIM DLBV2750
113 Y(I)=R(I) DLBV2760
ISW=1 DLBV2770
114 ISW2=12 DLBV2780
GOTO 200 DLBV2790
115 ISW3=-1 DLBV2800
GOTO 300 DLBV2810
116 IF(IHLF)400,400,117 DLBV2820
C THIS WAS BRANCH INTO INITIAL VALUE PROBLEM DLBV2830
C DLBV2840
C THIS IS RETURN FROM INITIAL VALUE PROBLEM DLBV2850
117 RETURN DLBV2860
C DLBV2870
C THIS PART OF LINEAR BOUNDARY VALUE PROBLEM COMPUTES THE RIGHT DLBV2880
C HAND SIDE DERY OF THE SYSTEM OF ADJOINT LINEAR DIFFERENTIAL DLBV2890
C EQUATIONS (IN CASE ISW=0) OR OF THE GIVEN SYSTEM (IN CASE ISW=1). DLBV2900
200 CALL AFCT(X,A) DLBV2910
IF(ISW)201,201,205 DLBV2920
C DLBV2930
C ADJOINT SYSTEM DLBV2940
201 LL=0 DLBV2950
DO 203 M=1,NDIM DLBV2960
HS=0.D0 DLBV2970
DO 202 L=1,NDIM DLBV2980
LL=LL+1 DLBV2990
202 HS=HS-A(LL)*Y(L) DLBV3000
203 DERY(M)=HS DLBV3010
204 GOTO(502,504,506,407,415,418,608,617,632,634,421,115),ISW2 DLBV3020
C DLBV3030
C GIVEN SYSTEM DLBV3040
205 CALL FCT(X,DERY) DLBV3050
DO 207 M=1,NDIM DLBV3060
LL=M-NDIM DLBV3070
HS=0.D0 DLBV3080
DO 206 L=1,NDIM DLBV3090
LL=LL+NDIM DLBV3100
206 HS=HS+A(LL)*Y(L) DLBV3110
207 DERY(M)=HS+DERY(M) DLBV3120
GOTO 204 DLBV3130
C DLBV3140
C THIS PART OF LINEAR BOUNDARY VALUE PROBLEM COMPUTES THE VALUE OF DLBV3150
C INTEGRAL SUM, WHICH IS A PART OF THE OUTPUT OF ADJOINT INITIAL DLBV3160
C VALUE PROBLEM (IN CASE ISW=0) OR RECORDS RESULT VALUES OF THE DLBV3170
C FINAL INITIAL VALUE PROBLEM (IN CASE ISW=1). DLBV3180
300 IF(ISW)301,301,305 DLBV3190
C DLBV3200
C ADJOINT PROBLEM DLBV3210
301 CALL FCT(X,R) DLBV3220
GU=0.D0 DLBV3230
DGU=0.D0 DLBV3240
DO 302 L=1,NDIM DLBV3250
GU=GU+Y(L)*R(L) DLBV3260
302 DGU=DGU+DERY(L)*R(L) DLBV3270
CALL DFCT(X,R) DLBV3280
DO 303 L=1,NDIM DLBV3290
303 DGU=DGU+Y(L)*R(L) DLBV3300
SUM=SUM+.5D0*H*((GL+GU)+.16666666666666667D0*H*(DGL-DGU)) DLBV3310
GL=GU DLBV3320
DGL=DGU DLBV3330
304 IF(ISW3)116,422,618 DLBV3340
C DLBV3350
C GIVEN PROBLEM DLBV3360
305 CALL OUTP(X,Y,DERY,IHLF,NDIM,PRMT) DLBV3370
IF(PRMT(5))117,304,117 DLBV3380
C DLBV3390
C POSSIBLE BREAK-POINT FOR LINKAGE DLBV3400
C DLBV3410
C THE FOLLOWING PART OF SUBROUTINE DLBVP SOLVES IN CASE ISW=0 THE DLBV3420
C ADJOINT INITIAL VALUE PROBLEM. IT COMPUTES INTEGRAL SUM AND DLBV3430
C THE VECTOR Y OF DEPENDENT VARIABLES AT THE LOWER BOUND PRMT(1). DLBV3440
C IN CASE ISW=1 IT SOLVES FINALLY GENERATED INITIAL VALUE PROBLEM. DLBV3450
400 N=1 DLBV3460
XST=X DLBV3470
IHLF=0 DLBV3480
DO 401 I=1,NDIM DLBV3490
AUX(16,I)=0.D0 DLBV3500
AUX(1,I)=Y(I) DLBV3510
401 AUX(8,I)=DERY(I) DLBV3520
ISW1=1 DLBV3530
GOTO 500 DLBV3540
C DLBV3550
402 X=X+H DLBV3560
DO 403 I=1,NDIM DLBV3570
403 AUX(2,I)=Y(I) DLBV3580
C DLBV3590
C INCREMENT H IS TESTED BY MEANS OF BISECTION DLBV3600
404 IHLF=IHLF+1 DLBV3610
X=X-H DLBV3620
DO 405 I=1,NDIM DLBV3630
405 AUX(4,I)=AUX(2,I) DLBV3640
H=.5D0*H DLBV3650
N=1 DLBV3660
ISW1=2 DLBV3670
GOTO 500 DLBV3680
C DLBV3690
406 X=X+H DLBV3700
ISW2=4 DLBV3710
GOTO 200 DLBV3720
407 N=2 DLBV3730
DO 408 I=1,NDIM DLBV3740
AUX(2,I)=Y(I) DLBV3750
408 AUX(9,I)=DERY(I) DLBV3760
ISW1=3 DLBV3770
GOTO 500 DLBV3780
C DLBV3790
C TEST ON SATISFACTORY ACCURACY DLBV3800
409 DO 414 I=1,NDIM DLBV3810
Z=DABS(Y(I)) DLBV3820
IF(Z-1.D0)410,411,411 DLBV3830
410 Z=1.D0 DLBV3840
411 DELT=.066666666666666667D0*DABS(Y(I)-AUX(4,I)) DLBV3850
IF(ISW)413,413,412 DLBV3860
412 DELT=AUX(15,I)*DELT DLBV3870
413 IF(DELT-Z*PRMT(4))414,414,429 DLBV3880
414 CONTINUE DLBV3890
C DLBV3900
C SATISFACTORY ACCURACY AFTER LESS THAN 11 BISECTIONS DLBV3910
X=X+H DLBV3920
ISW2=5 DLBV3930
GOTO 200 DLBV3940
415 DO 416 I=1,NDIM DLBV3950
AUX(3,I)=Y(I) DLBV3960
416 AUX(10,I)=DERY(I) DLBV3970
N=3 DLBV3980
ISW1=4 DLBV3990
GOTO 500 DLBV4000
C DLBV4010
417 N=1 DLBV4020
X=X+H DLBV4030
ISW2=6 DLBV4040
GOTO 200 DLBV4050
418 X=XST DLBV4060
DO 419 I=1,NDIM DLBV4070
AUX(11,I)=DERY(I) DLBV4080
4190Y(I)=AUX(1,I)+H*(.375D0*AUX(8,I)+.7916666666666667D0*AUX(9,I) DLBV4090
1-.20833333333333333D0*AUX(10,I)+.041666666666666667D0*DERY(I)) DLBV4100
420 X=X+H DLBV4110
N=N+1 DLBV4120
ISW2=11 DLBV4130
GOTO 200 DLBV4140
421 ISW3=0 DLBV4150
GOTO 300 DLBV4160
422 IF(N-4)423,600,600 DLBV4170
423 DO 424 I=1,NDIM DLBV4180
AUX(N,I)=Y(I) DLBV4190
424 AUX(N+7,I)=DERY(I) DLBV4200
IF(N-3)425,427,600 DLBV4210
C DLBV4220
425 DO 426 I=1,NDIM DLBV4230
DELT=AUX(9,I)+AUX(9,I) DLBV4240
DELT=DELT+DELT DLBV4250
426 Y(I)=AUX(1,I)+.33333333333333333D0*H*(AUX(8,I)+DELT+AUX(10,I)) DLBV4260
GOTO 420 DLBV4270
C DLBV4280
427 DO 428 I=1,NDIM DLBV4290
DELT=AUX(9,I)+AUX(10,I) DLBV4300
DELT=DELT+DELT+DELT DLBV4310
428 Y(I)=AUX(1,I)+.375D0*H*(AUX(8,I)+DELT+AUX(11,I)) DLBV4320
GOTO 420 DLBV4330
C DLBV4340
C NO SATISFACTORY ACCURACY. H MUST BE HALVED. DLBV4350
429 IF(IHLF-10)404,430,430 DLBV4360
C DLBV4370
C NO SATISFACTORY ACCURACY AFTER 10 BISECTIONS. ERROR MESSAGE. DLBV4380
430 IHLF=11 DLBV4390
X=X+H DLBV4400
IF(ISW)105,105,114 DLBV4410
C DLBV4420
C THIS PART OF LINEAR INITIAL VALUE PROBLEM COMPUTES DLBV4430
C STARTING VALUES BY MEANS OF RUNGE-KUTTA METHOD. DLBV4440
500 Z=X DLBV4450
DO 501 I=1,NDIM DLBV4460
X=H*AUX(N+7,I) DLBV4470
AUX(5,I)=X DLBV4480
501 Y(I)=AUX(N,I)+.4D0*X DLBV4490
C DLBV4500
X=Z+.4D0*H DLBV4510
ISW2=1 DLBV4520
GOTO 200 DLBV4530
502 DO 503 I=1,NDIM DLBV4540
X=H*DERY(I) DLBV4550
AUX(6,I)=X DLBV4560
503 Y(I)=AUX(N,I)+.29697760924775360D0*AUX(5,I)+.15875964497103583D0*XDLBV4570
C DLBV4580
X=Z+.45573725421878943D0*H DLBV4590
ISW2=2 DLBV4600
GOTO 200 DLBV4610
504 DO 505 I=1,NDIM DLBV4620
X=H*DERY(I) DLBV4630
AUX(7,I)=X DLBV4640
505 Y(I)=AUX(N,I)+.21810038822592047D0*AUX(5,I)-3.0509651486929308D0* DLBV4650
1AUX(6,I)+3.8328647604670103D0*X DLBV4660
C DLBV4670
X=Z+H DLBV4680
ISW2=3 DLBV4690
GOTO 200 DLBV4700
506 DO 507 I=1,NDIM DLBV4710
5070Y(I)=AUX(N,I)+.17476028226269037D0*AUX(5,I)-.55148066287873294D0* DLBV4720
1AUX(6,I)+1.2055355993965235D0*AUX(7,I)+.17118478121951903D0* DLBV4730
2H*DERY(I) DLBV4740
X=Z DLBV4750
GOTO(402,406,409,417),ISW1 DLBV4760
C DLBV4770
C POSSIBLE BREAK-POINT FOR LINKAGE DLBV4780
C DLBV4790
C STARTING VALUES ARE COMPUTED. DLBV4800
C NOW START HAMMINGS MODIFIED PREDICTOR-CORRECTOR METHOD. DLBV4810
600 ISTEP=3 DLBV4820
601 IF(N-8)604,602,604 DLBV4830
C DLBV4840
C N=8 CAUSES THE ROWS OF AUX TO CHANGE THEIR STORAGE LOCATIONS DLBV4850
602 DO 603 N=2,7 DLBV4860
DO 603 I=1,NDIM DLBV4870
AUX(N-1,I)=AUX(N,I) DLBV4880
603 AUX(N+6,I)=AUX(N+7,I) DLBV4890
N=7 DLBV4900
C DLBV4910
C N LESS THAN 8 CAUSES N+1 TO GET N DLBV4920
604 N=N+1 DLBV4930
C DLBV4940
C COMPUTATION OF NEXT VECTOR Y DLBV4950
DO 605 I=1,NDIM DLBV4960
AUX(N-1,I)=Y(I) DLBV4970
605 AUX(N+6,I)=DERY(I) DLBV4980
X=X+H DLBV4990
606 ISTEP=ISTEP+1 DLBV5000
DO 607 I=1,NDIM DLBV5010
0DELT=AUX(N-4,I)+1.3333333333333333D0*H*(AUX(N+6,I)+AUX(N+6,I)- DLBV5020
1AUX(N+5,I)+AUX(N+4,I)+AUX(N+4,I)) DLBV5030
Y(I)=DELT-.9256198347107438D0*AUX(16,I) DLBV5040
607 AUX(16,I)=DELT DLBV5050
C PREDICTOR IS NOW GENERATED IN ROW 16 OF AUX, MODIFIED PREDICTOR DLBV5060
C IS GENERATED IN Y. DELT MEANS AN AUXILIARY STORAGE. DLBV5070
C DLBV5080
ISW2=7 DLBV5090
GOTO 200 DLBV5100
C DERIVATIVE OF MODIFIED PREDICTOR IS GENERATED IN DERY. DLBV5110
C DLBV5120
608 DO 609 I=1,NDIM DLBV5130
0DELT=.125D0*(9.D0*AUX(N-1,I)-AUX(N-3,I)+3.D0*H*(DERY(I)+AUX(N+6,I)DLBV5140
1+AUX(N+6,I)-AUX(N+5,I))) DLBV5150
AUX(16,I)=AUX(16,I)-DELT DLBV5160
609 Y(I)=DELT+.07438016528925620D0*AUX(16,I) DLBV5170
C DLBV5180
C TEST WHETHER H MUST BE HALVED OR DOUBLED DLBV5190
DELT=0.D0 DLBV5200
DO 616 I=1,NDIM DLBV5210
Z=DABS(Y(I)) DLBV5220
IF(Z-1.D0)610,611,611 DLBV5230
610 Z=1.D0 DLBV5240
611 Z=DABS(AUX(16,I))/Z DLBV5250
IF(ISW)613,613,612 DLBV5260
612 Z=AUX(15,I)*Z DLBV5270
613 IF(Z-PRMT(4))614,614,628 DLBV5280
614 IF(DELT-Z)615,616,616 DLBV5290
615 DELT=Z DLBV5300
616 CONTINUE DLBV5310
C DLBV5320
C H MUST NOT BE HALVED. THAT MEANS Y(I) ARE GOOD. DLBV5330
ISW2=8 DLBV5340
GOTO 200 DLBV5350
617 ISW3=1 DLBV5360
GOTO 300 DLBV5370
618 IF(H*(X-XEND))619,621,621 DLBV5380
619 IF(DABS(X-XEND)-.1D0*DABS(H))621,620,620 DLBV5390
620 IF(DELT-.02D0*PRMT(4))622,622,601 DLBV5400
621 IF(ISW)105,105,117 DLBV5410
C DLBV5420
C H COULD BE DOUBLED IF ALL NECESSARY PRECEEDING VALUES ARE DLBV5430
C AVAILABLE. DLBV5440
622 IF(IHLF)601,601,623 DLBV5450
623 IF(N-7)601,624,624 DLBV5460
624 IF(ISTEP-4)601,625,625 DLBV5470
625 IMOD=ISTEP/2 DLBV5480
IF(ISTEP-IMOD-IMOD)601,626,601 DLBV5490
626 H=H+H DLBV5500
IHLF=IHLF-1 DLBV5510
ISTEP=0 DLBV5520
DO 627 I=1,NDIM DLBV5530
AUX(N-1,I)=AUX(N-2,I) DLBV5540
AUX(N-2,I)=AUX(N-4,I) DLBV5550
AUX(N-3,I)=AUX(N-6,I) DLBV5560
AUX(N+6,I)=AUX(N+5,I) DLBV5570
AUX(N+5,I)=AUX(N+3,I) DLBV5580
AUX(N+4,I)=AUX(N+1,I) DLBV5590
DELT=AUX(N+6,I)+AUX(N+5,I) DLBV5600
DELT=DELT+DELT+DELT DLBV5610
6270AUX(16,I)=8.962962962962963D0*(Y(I)-AUX(N-3,I)) DLBV5620
1-3.3611111111111111D0*H*(DERY(I)+DELT+AUX(N+4,I)) DLBV5630
GOTO 601 DLBV5640
C DLBV5650
C H MUST BE HALVED DLBV5660
628 IHLF=IHLF+1 DLBV5670
IF(IHLF-10)630,630,629 DLBV5680
629 IF(ISW)105,105,114 DLBV5690
630 H=.5D0*H DLBV5700
ISTEP=0 DLBV5710
DO 631 I=1,NDIM DLBV5720
0Y(I)=.390625D-2*(8.D1*AUX(N-1,I)+135.D0*AUX(N-2,I)+4.D1*AUX(N-3,I)DLBV5730
1+AUX(N-4,I))-.1171875D0*(AUX(N+6,I)-6.D0*AUX(N+5,I)-AUX(N+4,I))*H DLBV5740
0AUX(N-4,I)=.390625D-2*(12.D0*AUX(N-1,I)+135.D0*AUX(N-2,I)+ DLBV5750
1108.D0*AUX(N-3,I)+AUX(N-4,I))-.0234375D0*(AUX(N+6,I)+ DLBV5760
218.D0*AUX(N+5,I)-9.D0*AUX(N+4,I))*H DLBV5770
AUX(N-3,I)=AUX(N-2,I) DLBV5780
631 AUX(N+4,I)=AUX(N+5,I) DLBV5790
DELT=X-H DLBV5800
X=DELT-(H+H) DLBV5810
ISW2=9 DLBV5820
GOTO 200 DLBV5830
632 DO 633 I=1,NDIM DLBV5840
AUX(N-2,I)=Y(I) DLBV5850
AUX(N+5,I)=DERY(I) DLBV5860
633 Y(I)=AUX(N-4,I) DLBV5870
X=X-(H+H) DLBV5880
ISW2=10 DLBV5890
GOTO 200 DLBV5900
634 X=DELT DLBV5910
DO 635 I=1,NDIM DLBV5920
DELT=AUX(N+5,I)+AUX(N+4,I) DLBV5930
DELT=DELT+DELT+DELT DLBV5940
0AUX(16,I)=8.962962962962963D0*(AUX(N-1,I)-Y(I)) DLBV5950
1-3.3611111111111111D0*H*(AUX(N+6,I)+DELT+DERY(I)) DLBV5960
635 AUX(N+3,I)=DERY(I) DLBV5970
GOTO 606 DLBV5980
C END OF INITIAL VALUE PROBLEM DLBV5990
END DLBV6000