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decuslib10-02
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43,50145/mfsd.ssp
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C MFSD 10
���C ..................................................................MFSD 20
���C MFSD 30
���C SUBROUTINE MFSD MFSD 40
���C MFSD 50
���C PURPOSE MFSD 60
���C FACTOR A GIVEN SYMMETRIC POSITIVE DEFINITE MATRIX MFSD 70
���C MFSD 80
���C USAGE MFSD 90
���C CALL MFSD(A,N,EPS,IER) MFSD 100
���C MFSD 110
���C DESCRIPTION OF PARAMETERS MFSD 120
���C A - UPPER TRIANGULAR PART OF THE GIVEN SYMMETRIC MFSD 130
���C POSITIVE DEFINITE N BY N COEFFICIENT MATRIX. MFSD 140
���C ON RETURN A CONTAINS THE RESULTANT UPPER MFSD 150
���C TRIANGULAR MATRIX. MFSD 160
���C N - THE NUMBER OF ROWS (COLUMNS) IN GIVEN MATRIX. MFSD 170
���C EPS - AN INPUT CONSTANT WHICH IS USED AS RELATIVE MFSD 180
���C TOLERANCE FOR TEST ON LOSS OF SIGNIFICANCE. MFSD 190
���C IER - RESULTING ERROR PARAMETER CODED AS FOLLOWS MFSD 200
���C IER=0 - NO ERROR MFSD 210
���C IER=-1 - NO RESULT BECAUSE OF WRONG INPUT PARAME- MFSD 220
���C TER N OR BECAUSE SOME RADICAND IS NON- MFSD 230
���C POSITIVE (MATRIX A IS NOT POSITIVE MFSD 240
���C DEFINITE, POSSIBLY DUE TO LOSS OF SIGNI- MFSD 250
���C FICANCE) MFSD 260
���C IER=K - WARNING WHICH INDICATES LOSS OF SIGNIFI- MFSD 270
���C CANCE. THE RADICAND FORMED AT FACTORIZA- MFSD 280
���C TION STEP K+1 WAS STILL POSITIVE BUT NO MFSD 290
���C LONGER GREATER THAN ABS(EPS*A(K+1,K+1)). MFSD 300
���C MFSD 310
���C REMARKS MFSD 320
���C THE UPPER TRIANGULAR PART OF GIVEN MATRIX IS ASSUMED TO BE MFSD 330
���C STORED COLUMNWISE IN N*(N+1)/2 SUCCESSIVE STORAGE LOCATIONS.MFSD 340
���C IN THE SAME STORAGE LOCATIONS THE RESULTING UPPER TRIANGU- MFSD 350
���C LAR MATRIX IS STORED COLUMNWISE TOO. MFSD 360
���C THE PROCEDURE GIVES RESULTS IF N IS GREATER THAN 0 AND ALL MFSD 370
���C CALCULATED RADICANDS ARE POSITIVE. MFSD 380
���C THE PRODUCT OF RETURNED DIAGONAL TERMS IS EQUAL TO THE MFSD 390
���C SQUARE-ROOT OF THE DETERMINANT OF THE GIVEN MATRIX. MFSD 400
���C MFSD 410
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED MFSD 420
���C NONE MFSD 430
���C MFSD 440
���C METHOD MFSD 450
���C SOLUTION IS DONE USING THE SQUARE-ROOT METHOD OF CHOLESKY. MFSD 460
���C THE GIVEN MATRIX IS REPRESENTED AS PRODUCT OF TWO TRIANGULARMFSD 470
���C MATRICES, WHERE THE LEFT HAND FACTOR IS THE TRANSPOSE OF MFSD 480
���C THE RETURNED RIGHT HAND FACTOR. MFSD 490
���C MFSD 500
���C ..................................................................MFSD 510
���C MFSD 520
��� SUBROUTINE MFSD(A,N,EPS,IER) MFSD 530
���C MFSD 540
���C MFSD 550
��� DIMENSION A(1) MFSD 560
��� DOUBLE PRECISION DPIV,DSUM MFSD 570
���C MFSD 580
���C TEST ON WRONG INPUT PARAMETER N MFSD 590
��� IF(N-1) 12,1,1 MFSD 600
��� 1 IER=0 MFSD 610
���C MFSD 620
���C INITIALIZE DIAGONAL-LOOP MFSD 630
��� KPIV=0 MFSD 640
��� DO 11 K=1,N MFSD 650
��� KPIV=KPIV+K MFSD 660
��� IND=KPIV MFSD 670
��� LEND=K-1 MFSD 680
���C MFSD 690
���C CALCULATE TOLERANCE MFSD 700
��� TOL=ABS(EPS*A(KPIV)) MFSD 710
���C MFSD 720
���C START FACTORIZATION-LOOP OVER K-TH ROW MFSD 730
��� DO 11 I=K,N MFSD 740
��� DSUM=0.D0 MFSD 750
��� IF(LEND) 2,4,2 MFSD 760
���C MFSD 770
���C START INNER LOOP MFSD 780
��� 2 DO 3 L=1,LEND MFSD 790
��� LANF=KPIV-L MFSD 800
��� LIND=IND-L MFSD 810
��� 3 DSUM=DSUM+DBLE(A(LANF)*A(LIND)) MFSD 820
���C END OF INNER LOOP MFSD 830
���C MFSD 840
���C TRANSFORM ELEMENT A(IND) MFSD 850
��� 4 DSUM=DBLE(A(IND))-DSUM MFSD 860
��� IF(I-K) 10,5,10 MFSD 870
���C MFSD 880
���C TEST FOR NEGATIVE PIVOT ELEMENT AND FOR LOSS OF SIGNIFICANCE MFSD 890
��� 5 IF(SNGL(DSUM)-TOL) 6,6,9 MFSD 900
��� 6 IF(DSUM) 12,12,7 MFSD 910
��� 7 IF(IER) 8,8,9 MFSD 920
��� 8 IER=K-1 MFSD 930
���C MFSD 940
���C COMPUTE PIVOT ELEMENT MFSD 950
��� 9 DPIV=DSQRT(DSUM) MFSD 960
��� A(KPIV)=DPIV MFSD 970
��� DPIV=1.D0/DPIV MFSD 980
��� GO TO 11 MFSD 990
���C MFSD1000
���C CALCULATE TERMS IN ROW MFSD1010
��� 10 A(IND)=DSUM*DPIV MFSD1020
��� 11 IND=IND+I MFSD1030
���C MFSD1040
���C END OF DIAGONAL-LOOP MFSD1050
��� RETURN MFSD1060
��� 12 IER=-1 MFSD1070
��� RETURN MFSD1080
��� END MFSD1090