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PDP-10 Archives
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decuslib10-02
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43,50145/hsbg.ssp
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C HSBG 10
���C ..................................................................HSBG 20
���C HSBG 30
���C SUBROUTINE HSBG HSBG 40
���C HSBG 50
���C PURPOSE HSBG 60
���C TO REDUCE A REAL MATRIX INTO UPPER ALMOST TRIANGULAR FORM HSBG 70
���C HSBG 80
���C USAGE HSBG 90
���C CALL HSBG(N,A,IA) HSBG 100
���C HSBG 110
���C DESCRIPTION OF THE PARAMETERS HSBG 120
���C N ORDER OF THE MATRIX HSBG 130
���C A THE INPUT MATRIX, N BY N HSBG 140
���C IA SIZE OF THE FIRST DIMENSION ASSIGNED TO THE ARRAY HSBG 150
���C A IN THE CALLING PROGRAM WHEN THE MATRIX IS IN HSBG 160
���C DOUBLE SUBSCRIPTED DATA STORAGE MODE. IA=N WHEN HSBG 170
���C THE MATRIX IS IN SSP VECTOR STORAGE MODE. HSBG 180
���C HSBG 190
���C REMARKS HSBG 200
���C THE HESSENBERG FORM REPLACES THE ORIGINAL MATRIX IN THE HSBG 210
���C ARRAY A. HSBG 220
���C HSBG 230
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED HSBG 240
���C NONE HSBG 250
���C HSBG 260
���C METHOD HSBG 270
���C SIMILARITY TRANSFORMATIONS USING ELEMENTARY ELIMINATION HSBG 280
���C MATRICES, WITH PARTIAL PIVOTING. HSBG 290
���C HSBG 300
���C REFERENCES HSBG 310
���C J.H. WILKINSON - THE ALGEBRAIC EIGENVALUE PROBLEM - HSBG 320
���C CLARENDON PRESS, OXFORD, 1965. HSBG 330
���C HSBG 340
���C ..................................................................HSBG 350
���C HSBG 360
��� SUBROUTINE HSBG(N,A,IA) HSBG 370
��� DIMENSION A(1) HSBG 380
��� DOUBLE PRECISION S HSBG 390
��� L=N HSBG 400
��� NIA=L*IA HSBG 410
��� LIA=NIA-IA HSBG 420
���C HSBG 430
���C L IS THE ROW INDEX OF THE ELIMINATION HSBG 440
���C HSBG 450
��� 20 IF(L-3) 360,40,40 HSBG 460
��� 40 LIA=LIA-IA HSBG 470
��� L1=L-1 HSBG 480
��� L2=L1-1 HSBG 490
���C HSBG 500
���C SEARCH FOR THE PIVOTAL ELEMENT IN THE LTH ROW HSBG 510
���C HSBG 520
��� ISUB=LIA+L HSBG 530
��� IPIV=ISUB-IA HSBG 540
��� PIV=ABS(A(IPIV)) HSBG 550
��� IF(L-3) 90,90,50 HSBG 560
��� 50 M=IPIV-IA HSBG 570
��� DO 80 I=L,M,IA HSBG 580
��� T=ABS(A(I)) HSBG 590
��� IF(T-PIV) 80,80,60 HSBG 600
��� 60 IPIV=I HSBG 610
��� PIV=T HSBG 620
��� 80 CONTINUE HSBG 630
��� 90 IF(PIV) 100,320,100 HSBG 640
��� 100 IF(PIV-ABS(A(ISUB))) 180,180,120 HSBG 650
���C HSBG 660
���C INTERCHANGE THE COLUMNS HSBG 670
���C HSBG 680
��� 120 M=IPIV-L HSBG 690
��� DO 140 I=1,L HSBG 700
��� J=M+I HSBG 710
��� T=A(J) HSBG 720
��� K=LIA+I HSBG 730
��� A(J)=A(K) HSBG 740
��� 140 A(K)=T HSBG 750
���C HSBG 760
���C INTERCHANGE THE ROWS HSBG 770
���C HSBG 780
��� M=L2-M/IA HSBG 790
��� DO 160 I=L1,NIA,IA HSBG 800
��� T=A(I) HSBG 810
��� J=I-M HSBG 820
��� A(I)=A(J) HSBG 830
��� 160 A(J)=T HSBG 840
���C HSBG 850
���C TERMS OF THE ELEMENTARY TRANSFORMATION HSBG 860
���C HSBG 870
��� 180 DO 200 I=L,LIA,IA HSBG 880
��� 200 A(I)=A(I)/A(ISUB) HSBG 890
���C HSBG 900
���C RIGHT TRANSFORMATION HSBG 910
���C HSBG 920
��� J=-IA HSBG 930
��� DO 240 I=1,L2 HSBG 940
��� J=J+IA HSBG 950
��� LJ=L+J HSBG 960
��� DO 220 K=1,L1 HSBG 970
��� KJ=K+J HSBG 980
��� KL=K+LIA HSBG 990
��� 220 A(KJ)=A(KJ)-A(LJ)*A(KL) HSBG1000
��� 240 CONTINUE HSBG1010
���C HSBG1020
���C LEFT TRANSFORMATION HSBG1030
���C HSBG1040
��� K=-IA HSBG1050
��� DO 300 I=1,N HSBG1060
��� K=K+IA HSBG1070
��� LK=K+L1 HSBG1080
��� S=A(LK) HSBG1090
��� LJ=L-IA HSBG1100
��� DO 280 J=1,L2 HSBG1110
��� JK=K+J HSBG1120
��� LJ=LJ+IA HSBG1130
��� 280 S=S+A(LJ)*A(JK)*1.0D0 HSBG1140
��� 300 A(LK)=S HSBG1150
���C HSBG1160
���C SET THE LOWER PART OF THE MATRIX TO ZERO HSBG1170
���C HSBG1180
��� DO 310 I=L,LIA,IA HSBG1190
��� 310 A(I)=0.0 HSBG1200
��� 320 L=L1 HSBG1210
��� GO TO 20 HSBG1220
��� 360 RETURN HSBG1230
��� END HSBG1240