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decus_20tap2_198111
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decus/20-0026/dprbm.ssp
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C DPRB 10
���C ..................................................................DPRB 20
���C DPRB 30
���C SUBROUTINE DPRBM DPRB 40
���C DPRB 50
���C PURPOSE DPRB 60
���C TO CALCULATE ALL REAL AND COMPLEX ROOTS OF A GIVEN DPRB 70
���C POLYNOMIAL WITH REAL COEFFICIENTS. DPRB 80
���C DPRB 90
���C USAGE DPRB 100
���C CALL DPRBM (C,IC,RR,RC,POL,IR,IER) DPRB 110
���C DPRB 120
���C DESCRIPTION OF PARAMETERS DPRB 130
���C C - DOUBLE PRECISION INPUT VECTOR CONTAINING THE DPRB 140
���C COEFFICIENTS OF THE GIVEN POLYNOMIAL. COEFFICIENTS DPRB 150
���C ARE ORDERED FROM LOW TO HIGH. ON RETURN COEFFI- DPRB 160
���C CIENTS ARE DIVIDED BY THE LAST NONZERO TERM. DPRB 170
���C IC - DIMENSION OF VECTORS C, RR, RC, AND POL. DPRB 180
���C RR - RESULTANT DOUBLE PRECISION VECTOR OF REAL PARTS DPRB 190
���C OF THE ROOTS. DPRB 200
���C RC - RESULTANT DOUBLE PRECISION VECTOR OF COMPLEX PARTS DPRB 210
���C OF THE ROOTS. DPRB 220
���C POL - RESULTANT DOUBLE PRECISION VECTOR OF COEFFICIENTS DPRB 230
���C OF THE POLYNOMIAL WITH CALCULATED ROOTS. DPRB 240
���C COEFFICIENTS ARE ORDERED FROM LOW TO HIGH (SEE DPRB 250
���C REMARK 4). DPRB 260
���C IR - OUTPUT VALUE SPECIFYING THE NUMBER OF CALCULATED DPRB 270
���C ROOTS. NORMALLY IR IS EQUAL TO IC-1. DPRB 280
���C IER - RESULTANT ERROR PARAMETER CODED AS FOLLOWS DPRB 290
���C IER=0 - NO ERROR, DPRB 300
���C IER=1 - SUBROUTINE DPQFB RECORDS POOR CONVERGENCEDPRB 310
���C AT SOME QUADRATIC FACTORIZATION WITHIN DPRB 320
���C 100 ITERATION STEPS, DPRB 330
���C IER=2 - POLYNOMIAL IS DEGENERATE, I.E. ZERO OR DPRB 340
���C CONSTANT, DPRB 350
���C OR OVERFLOW IN NORMALIZATION OF GIVEN DPRB 360
���C POLYNOMIAL, DPRB 370
���C IER=3 - THE SUBROUTINE IS BYPASSED DUE TO DPRB 380
���C SUCCESSIVE ZERO DIVISORS OR OVERFLOWS DPRB 390
���C IN QUADRATIC FACTORIZATION OR DUE TO DPRB 400
���C COMPLETELY UNSATISFACTORY ACCURACY, DPRB 410
���C IER=-1 - CALCULATED COEFFICIENT VECTOR HAS LESS DPRB 420
���C THAN SIX CORRECT SIGNIFICANT DIGITS. DPRB 430
���C THIS REVEALS POOR ACCURACY OF CALCULATED DPRB 440
���C ROOTS. DPRB 450
���C DPRB 460
���C REMARKS DPRB 470
���C (1) REAL PARTS OF THE ROOTS ARE STORED IN RR(1) UP TO RR(IR)DPRB 480
���C AND CORRESPONDING COMPLEX PARTS IN RC(1) UP TO RC(IR). DPRB 490
���C (2) ERROR MESSAGE IER=1 INDICATES POOR CONVERGENCE WITHIN DPRB 500
���C 100 ITERATION STEPS AT SOME QUADRATIC FACTORIZATION DPRB 510
���C PERFORMED BY SUBROUTINE DPQFB. DPRB 520
���C (3) NO ACTION BESIDES ERROR MESSAGE IER=2 IN CASE OF A ZERO DPRB 530
���C OR CONSTANT POLYNOMIAL. THE SAME ERROR MESSAGE IS GIVEN DPRB 540
���C IN CASE OF AN OVERFLOW IN NORMALIZATION OF GIVEN DPRB 550
���C POLYNOMIAL. DPRB 560
���C (4) ERROR MESSAGE IER=3 INDICATES SUCCESSIVE ZERO DIVISORS DPRB 570
���C OR OVERFLOWS OR COMPLETELY UNSATISFACTORY ACCURACY AT DPRB 580
���C ANY QUADRATIC FACTORIZATION PERFORMED BY DPRB 590
���C SUBROUTINE DPQFB. IN THIS CASE CALCULATION IS BYPASSED. DPRB 600
���C IR RECORDS THE NUMBER OF CALCULATED ROOTS. DPRB 610
���C POL(1),...,POL(J-IR) ARE THE COEFFICIENTS OF THE DPRB 620
���C REMAINING POLYNOMIAL, WHERE J IS THE ACTUAL NUMBER OF DPRB 630
���C COEFFICIENTS IN VECTOR C (NORMALLY J=IC). DPRB 640
���C (5) IF CALCULATED COEFFICIENT VECTOR HAS LESS THAN SIX DPRB 650
���C CORRECT SIGNIFICANT DIGITS THOUGH ALL QUADRATIC DPRB 660
���C FACTORIZATIONS SHOWED SATISFACTORY ACCURACY, THE ERROR DPRB 670
���C MESSAGE IER=-1 IS GIVEN. DPRB 680
���C (6) THE FINAL COMPARISON BETWEEN GIVEN AND CALCULATED DPRB 690
���C COEFFICIENT VECTOR IS PERFORMED ONLY IF ALL ROOTS HAVE DPRB 700
���C BEEN CALCULATED. IN THIS CASE THE NUMBER OF ROOTS IR IS DPRB 710
���C EQUAL TO THE ACTUAL DEGREE OF THE POLYNOMIAL (NORMALLY DPRB 720
���C IR=IC-1). THE MAXIMAL RELATIVE ERROR OF THE COEFFICIENT DPRB 730
���C VECTOR IS RECORDED IN RR(IR+1). DPRB 740
���C DPRB 750
���C SUBROUTINES AND FUNCTION SUBPROGRAMS REQUIRED DPRB 760
���C SUBROUTINE DPQFB QUADRATIC FACTORIZATION OF A POLYNOMIAL DPRB 770
���C BY BAIRSTOW ITERATION. DPRB 780
���C DPRB 790
���C METHOD DPRB 800
���C THE ROOTS OF THE POLYNOMIAL ARE CALCULATED BY MEANS OF DPRB 810
���C SUCCESSIVE QUADRATIC FACTORIZATION PERFORMED BY BAIRSTOW DPRB 820
���C ITERATION. X**2 IS USED AS INITIAL GUESS FOR THE FIRST DPRB 830
���C QUADRATIC FACTOR, AND FURTHER EACH CALCULATED QUADRATIC DPRB 840
���C FACTOR IS USED AS INITIAL GUESS FOR THE NEXT ONE. AFTER DPRB 850
���C COMPUTATION OF ALL ROOTS THE COEFFICIENT VECTOR IS DPRB 860
���C CALCULATED AND COMPARED WITH THE GIVEN ONE. DPRB 870
���C FOR REFERENCE, SEE J. H. WILKINSON, THE EVALUATION OF THE DPRB 880
���C ZEROS OF ILL-CONDITIONED POLYNOMIALS (PART ONE AND TWO), DPRB 890
���C NUMERISCHE MATHEMATIK, VOL.1 (1959), PP.150-180. DPRB 900
���C DPRB 910
���C ..................................................................DPRB 920
���C DPRB 930
��� SUBROUTINE DPRBM(C,IC,RR,RC,POL,IR,IER) DPRB 940
���C DPRB 950
���C DPRB 960
��� DIMENSION C(1),RR(1),RC(1),POL(1),Q(4) DPRB 970
��� DOUBLE PRECISION C,RR,RC,POL,Q,EPS,A,B,H,Q1,Q2 DPRB 980
���C DPRB 990
���C TEST ON LEADING ZERO COEFFICIENTS DPRB1000
��� EPS=1.D-6 DPRB1010
��� LIM=100 DPRB1020
��� IR=IC+1 DPRB1030
��� 1 IR=IR-1 DPRB1040
��� IF(IR-1)42,42,2 DPRB1050
��� 2 IF(C(IR))3,1,3 DPRB1060
���C DPRB1070
���C WORK UP ZERO ROOTS AND NORMALIZE REMAINING POLYNOMIAL DPRB1080
��� 3 IER=0 DPRB1090
��� J=IR DPRB1100
��� L=0 DPRB1110
��� A=C(IR) DPRB1120
��� DO 8 I=1,IR DPRB1130
��� IF(L)4,4,7 DPRB1140
��� 4 IF(C(I))6,5,6 DPRB1150
��� 5 RR(I)=0.D0 DPRB1160
��� RC(I)=0.D0 DPRB1170
��� POL(J)=0.D0 DPRB1180
��� J=J-1 DPRB1190
��� GO TO 8 DPRB1200
��� 6 L=1 DPRB1210
��� IST=I DPRB1220
��� J=0 DPRB1230
��� 7 J=J+1 DPRB1240
��� C(I)=C(I)/A DPRB1250
��� POL(J)=C(I) DPRB1260
��� CALL OVERFL(N) DPRB1270
��� IF(N-2)42,8,8 DPRB1280
��� 8 CONTINUE DPRB1290
���C DPRB1300
���C START BAIRSTOW ITERATION DPRB1310
��� Q1=0.D0 DPRB1320
��� Q2=0.D0 DPRB1330
��� 9 IF(J-2)33,10,14 DPRB1340
���C DPRB1350
���C DEGREE OF RESTPOLYNOMIAL IS EQUAL TO ONE DPRB1360
��� 10 A=POL(1) DPRB1370
��� RR(IST)=-A DPRB1380
��� RC(IST)=0.D0 DPRB1390
��� IR=IR-1 DPRB1400
��� Q2=0.D0 DPRB1410
��� IF(IR-1)13,13,11 DPRB1420
��� 11 DO 12 I=2,IR DPRB1430
��� Q1=Q2 DPRB1440
��� Q2=POL(I+1) DPRB1450
��� 12 POL(I)=A*Q2+Q1 DPRB1460
��� 13 POL(IR+1)=A+Q2 DPRB1470
��� GO TO 34 DPRB1480
���C THIS IS BRANCH TO COMPARISON OF COEFFICIENT VECTORS C AND POL DPRB1490
���C DPRB1500
���C DEGREE OF RESTPOLYNOMIAL IS GREATER THAN ONE DPRB1510
��� 14 DO 22 L=1,10 DPRB1520
��� N=1 DPRB1530
��� 15 Q(1)=Q1 DPRB1540
��� Q(2)=Q2 DPRB1550
��� CALL DPQFB(POL,J,Q,LIM,I) DPRB1560
��� IF(I)16,24,23 DPRB1570
��� 16 IF(Q1)18,17,18 DPRB1580
��� 17 IF(Q2)18,21,18 DPRB1590
��� 18 GO TO (19,20,19,21),N DPRB1600
��� 19 Q1=-Q1 DPRB1610
��� N=N+1 DPRB1620
��� GO TO 15 DPRB1630
��� 20 Q2=-Q2 DPRB1640
��� N=N+1 DPRB1650
��� GO TO 15 DPRB1660
��� 21 Q1=1.D0+Q1 DPRB1670
��� 22 Q2=1.D0-Q2 DPRB1680
���C DPRB1690
���C ERROR EXIT DUE TO UNSATISFACTORY RESULTS OF FACTORIZATION DPRB1700
��� IER=3 DPRB1710
��� IR=IR-J DPRB1720
��� RETURN DPRB1730
���C DPRB1740
���C WORK UP RESULTS OF QUADRATIC FACTORIZATION DPRB1750
��� 23 IER=1 DPRB1760
��� 24 Q1=Q(1) DPRB1770
��� Q2=Q(2) DPRB1780
���C DPRB1790
���C PERFORM DIVISION OF FACTORIZED POLYNOMIAL BY QUADRATIC FACTOR DPRB1800
��� B=0.D0 DPRB1810
��� A=0.D0 DPRB1820
��� I=J DPRB1830
��� 25 H=-Q1*B-Q2*A+POL(I) DPRB1840
��� POL(I)=B DPRB1850
��� B=A DPRB1860
��� A=H DPRB1870
��� I=I-1 DPRB1880
��� IF(I-2)26,26,25 DPRB1890
��� 26 POL(2)=B DPRB1900
��� POL(1)=A DPRB1910
���C DPRB1920
���C MULTIPLY POLYNOMIAL WITH CALCULATED ROOTS BY QUADRATIC FACTOR DPRB1930
��� L=IR-1 DPRB1940
��� IF(J-L)27,27,29 DPRB1950
��� 27 DO 28 I=J,L DPRB1960
��� 28 POL(I-1)=POL(I-1)+POL(I)*Q2+POL(I+1)*Q1 DPRB1970
��� 29 POL(L)=POL(L)+POL(L+1)*Q2+Q1 DPRB1980
��� POL(IR)=POL(IR)+Q2 DPRB1990
���C DPRB2000
���C CALCULATE ROOT-PAIR FROM QUADRATIC FACTOR X*X+Q2*X+Q1 DPRB2010
��� H=-.5D0*Q2 DPRB2020
��� A=H*H-Q1 DPRB2030
��� B=DSQRT(DABS(A)) DPRB2040
��� IF(A)30,30,31 DPRB2050
��� 30 RR(IST)=H DPRB2060
��� RC(IST)=B DPRB2070
��� IST=IST+1 DPRB2080
��� RR(IST)=H DPRB2090
��� RC(IST)=-B DPRB2100
��� GO TO 32 DPRB2110
��� 31 B=H+DSIGN(B,H) DPRB2120
��� RR(IST)=Q1/B DPRB2130
��� RC(IST)=0.D0 DPRB2140
��� IST=IST+1 DPRB2150
��� RR(IST)=B DPRB2160
��� RC(IST)=0.D0 DPRB2170
��� 32 IST=IST+1 DPRB2180
��� J=J-2 DPRB2190
��� GO TO 9 DPRB2200
���C DPRB2210
���C SHIFT BACK ELEMENTS OF POL BY 1 AND COMPARE VECTORS POL AND C DPRB2220
��� 33 IR=IR-1 DPRB2230
��� 34 A=0.D0 DPRB2240
��� DO 38 I=1,IR DPRB2250
��� Q1=C(I) DPRB2260
��� Q2=POL(I+1) DPRB2270
��� POL(I)=Q2 DPRB2280
��� IF(Q1)35,36,35 DPRB2290
��� 35 Q2=(Q1-Q2)/Q1 DPRB2300
��� 36 Q2=DABS(Q2) DPRB2310
��� IF(Q2-A)38,38,37 DPRB2320
��� 37 A=Q2 DPRB2330
��� 38 CONTINUE DPRB2340
��� I=IR+1 DPRB2350
��� POL(I)=1.D0 DPRB2360
��� RR(I)=A DPRB2370
��� RC(I)=0.D0 DPRB2380
��� IF(IER)39,39,41 DPRB2390
��� 39 IF(A-EPS)41,41,40 DPRB2400
���C DPRB2410
���C WARNING DUE TO POOR ACCURACY OF CALCULATED COEFFICIENT VECTOR DPRB2420
��� 40 IER=-1 DPRB2430
��� 41 RETURN DPRB2440
���C DPRB2450
���C ERROR EXIT DUE TO DEGENERATE POLYNOMIAL OR OVERFLOW IN DPRB2460
���C NORMALIZATION DPRB2470
��� 42 IER=2 DPRB2480
��� IR=0 DPRB2490
��� RETURN DPRB2500
��� END DPRB2510
���