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PDP-10 Archives
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decuslib10-02
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43,50145/qsf.ssp
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C QSF 10
���C ..................................................................QSF 20
���C QSF 30
���C SUBROUTINE QSF QSF 40
���C QSF 50
���C PURPOSE QSF 60
���C TO COMPUTE THE VECTOR OF INTEGRAL VALUES FOR A GIVEN QSF 70
���C EQUIDISTANT TABLE OF FUNCTION VALUES. QSF 80
���C QSF 90
���C USAGE QSF 100
���C CALL QSF (H,Y,Z,NDIM) QSF 110
���C QSF 120
���C DESCRIPTION OF PARAMETERS QSF 130
���C H - THE INCREMENT OF ARGUMENT VALUES. QSF 140
���C Y - THE INPUT VECTOR OF FUNCTION VALUES. QSF 150
���C Z - THE RESULTING VECTOR OF INTEGRAL VALUES. Z MAY BE QSF 160
���C IDENTICAL WITH Y. QSF 170
���C NDIM - THE DIMENSION OF VECTORS Y AND Z. QSF 180
���C QSF 190
���C REMARKS QSF 200
���C NO ACTION IN CASE NDIM LESS THAN 3. QSF 210
���C QSF 220
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED QSF 230
���C NONE QSF 240
���C QSF 250
���C METHOD QSF 260
���C BEGINNING WITH Z(1)=0, EVALUATION OF VECTOR Z IS DONE BY QSF 270
���C MEANS OF SIMPSONS RULE TOGETHER WITH NEWTONS 3/8 RULE OR A QSF 280
���C COMBINATION OF THESE TWO RULES. TRUNCATION ERROR IS OF QSF 290
���C ORDER H**5 (I.E. FOURTH ORDER METHOD). ONLY IN CASE NDIM=3 QSF 300
���C TRUNCATION ERROR OF Z(2) IS OF ORDER H**4. QSF 310
���C FOR REFERENCE, SEE QSF 320
���C (1) F.B.HILDEBRAND, INTRODUCTION TO NUMERICAL ANALYSIS, QSF 330
���C MCGRAW-HILL, NEW YORK/TORONTO/LONDON, 1956, PP.71-76. QSF 340
���C (2) R.ZURMUEHL, PRAKTISCHE MATHEMATIK FUER INGENIEURE UND QSF 350
���C PHYSIKER, SPRINGER, BERLIN/GOETTINGEN/HEIDELBERG, 1963, QSF 360
���C PP.214-221. QSF 370
���C QSF 380
���C ..................................................................QSF 390
���C QSF 400
��� SUBROUTINE QSF(H,Y,Z,NDIM) QSF 410
���C QSF 420
���C QSF 430
��� DIMENSION Y(1),Z(1) QSF 440
���C QSF 450
��� HT=.3333333*H QSF 460
��� IF(NDIM-5)7,8,1 QSF 470
���C QSF 480
���C NDIM IS GREATER THAN 5. PREPARATIONS OF INTEGRATION LOOP QSF 490
��� 1 SUM1=Y(2)+Y(2) QSF 500
��� SUM1=SUM1+SUM1 QSF 510
��� SUM1=HT*(Y(1)+SUM1+Y(3)) QSF 520
��� AUX1=Y(4)+Y(4) QSF 530
��� AUX1=AUX1+AUX1 QSF 540
��� AUX1=SUM1+HT*(Y(3)+AUX1+Y(5)) QSF 550
��� AUX2=HT*(Y(1)+3.875*(Y(2)+Y(5))+2.625*(Y(3)+Y(4))+Y(6)) QSF 560
��� SUM2=Y(5)+Y(5) QSF 570
��� SUM2=SUM2+SUM2 QSF 580
��� SUM2=AUX2-HT*(Y(4)+SUM2+Y(6)) QSF 590
��� Z(1)=0. QSF 600
��� AUX=Y(3)+Y(3) QSF 610
��� AUX=AUX+AUX QSF 620
��� Z(2)=SUM2-HT*(Y(2)+AUX+Y(4)) QSF 630
��� Z(3)=SUM1 QSF 640
��� Z(4)=SUM2 QSF 650
��� IF(NDIM-6)5,5,2 QSF 660
���C QSF 670
���C INTEGRATION LOOP QSF 680
��� 2 DO 4 I=7,NDIM,2 QSF 690
��� SUM1=AUX1 QSF 700
��� SUM2=AUX2 QSF 710
��� AUX1=Y(I-1)+Y(I-1) QSF 720
��� AUX1=AUX1+AUX1 QSF 730
��� AUX1=SUM1+HT*(Y(I-2)+AUX1+Y(I)) QSF 740
��� Z(I-2)=SUM1 QSF 750
��� IF(I-NDIM)3,6,6 QSF 760
��� 3 AUX2=Y(I)+Y(I) QSF 770
��� AUX2=AUX2+AUX2 QSF 780
��� AUX2=SUM2+HT*(Y(I-1)+AUX2+Y(I+1)) QSF 790
��� 4 Z(I-1)=SUM2 QSF 800
��� 5 Z(NDIM-1)=AUX1 QSF 810
��� Z(NDIM)=AUX2 QSF 820
��� RETURN QSF 830
��� 6 Z(NDIM-1)=SUM2 QSF 840
��� Z(NDIM)=AUX1 QSF 850
��� RETURN QSF 860
���C END OF INTEGRATION LOOP QSF 870
���C QSF 880
��� 7 IF(NDIM-3)12,11,8 QSF 890
���C QSF 900
���C NDIM IS EQUAL TO 4 OR 5 QSF 910
��� 8 SUM2=1.125*HT*(Y(1)+Y(2)+Y(2)+Y(2)+Y(3)+Y(3)+Y(3)+Y(4)) QSF 920
��� SUM1=Y(2)+Y(2) QSF 930
��� SUM1=SUM1+SUM1 QSF 940
��� SUM1=HT*(Y(1)+SUM1+Y(3)) QSF 950
��� Z(1)=0. QSF 960
��� AUX1=Y(3)+Y(3) QSF 970
��� AUX1=AUX1+AUX1 QSF 980
��� Z(2)=SUM2-HT*(Y(2)+AUX1+Y(4)) QSF 990
��� IF(NDIM-5)10,9,9 QSF 1000
��� 9 AUX1=Y(4)+Y(4) QSF 1010
��� AUX1=AUX1+AUX1 QSF 1020
��� Z(5)=SUM1+HT*(Y(3)+AUX1+Y(5)) QSF 1030
��� 10 Z(3)=SUM1 QSF 1040
��� Z(4)=SUM2 QSF 1050
��� RETURN QSF 1060
���C QSF 1070
���C NDIM IS EQUAL TO 3 QSF 1080
��� 11 SUM1=HT*(1.25*Y(1)+Y(2)+Y(2)-.25*Y(3)) QSF 1090
��� SUM2=Y(2)+Y(2) QSF 1100
��� SUM2=SUM2+SUM2 QSF 1110
��� Z(3)=HT*(Y(1)+SUM2+Y(3)) QSF 1120
��� Z(1)=0. QSF 1130
��� Z(2)=SUM1 QSF 1140
��� 12 RETURN QSF 1150
��� END QSF 1160