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132 lines
3.8 KiB
Fortran
132 lines
3.8 KiB
Fortran
SUBROUTINE ZRATI(ZR, ZI, FNU, N, CYR, CYI, TOL)
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C***BEGIN PROLOGUE ZRATI
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C***REFER TO ZBESI,ZBESK,ZBESH
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C
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C ZRATI COMPUTES RATIOS OF I BESSEL FUNCTIONS BY BACKWARD
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C RECURRENCE. THE STARTING INDEX IS DETERMINED BY FORWARD
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C RECURRENCE AS DESCRIBED IN J. RES. OF NAT. BUR. OF STANDARDS-B,
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C MATHEMATICAL SCIENCES, VOL 77B, P111-114, SEPTEMBER, 1973,
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C BESSEL FUNCTIONS I AND J OF COMPLEX ARGUMENT AND INTEGER ORDER,
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C BY D. J. SOOKNE.
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C
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C***ROUTINES CALLED ZABS,ZDIV
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C***END PROLOGUE ZRATI
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C COMPLEX Z,CY(1),CONE,CZERO,P1,P2,T1,RZ,PT,CDFNU
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DOUBLE PRECISION AK, AMAGZ, AP1, AP2, ARG, AZ, CDFNUI, CDFNUR,
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* CONEI, CONER, CYI, CYR, CZEROI, CZEROR, DFNU, FDNU, FLAM, FNU,
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* FNUP, PTI, PTR, P1I, P1R, P2I, P2R, RAK, RAP1, RHO, RT2, RZI,
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* RZR, TEST, TEST1, TOL, TTI, TTR, T1I, T1R, ZI, ZR, ZABS
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INTEGER I, ID, IDNU, INU, ITIME, K, KK, MAGZ, N
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DIMENSION CYR(N), CYI(N)
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DATA CZEROR,CZEROI,CONER,CONEI,RT2/
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1 0.0D0, 0.0D0, 1.0D0, 0.0D0, 1.41421356237309505D0 /
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AZ = ZABS(COMPLEX(ZR,ZI))
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INU = INT(SNGL(FNU))
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IDNU = INU + N - 1
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MAGZ = INT(SNGL(AZ))
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AMAGZ = DBLE(FLOAT(MAGZ+1))
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FDNU = DBLE(FLOAT(IDNU))
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FNUP = DMAX1(AMAGZ,FDNU)
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ID = IDNU - MAGZ - 1
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ITIME = 1
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K = 1
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PTR = 1.0D0/AZ
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RZR = PTR*(ZR+ZR)*PTR
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RZI = -PTR*(ZI+ZI)*PTR
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T1R = RZR*FNUP
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T1I = RZI*FNUP
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P2R = -T1R
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P2I = -T1I
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P1R = CONER
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P1I = CONEI
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T1R = T1R + RZR
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T1I = T1I + RZI
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IF (ID.GT.0) ID = 0
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AP2 = ZABS(COMPLEX(P2R,P2I))
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AP1 = ZABS(COMPLEX(P1R,P1I))
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C-----------------------------------------------------------------------
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C THE OVERFLOW TEST ON K(FNU+I-1,Z) BEFORE THE CALL TO CBKNU
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C GUARANTEES THAT P2 IS ON SCALE. SCALE TEST1 AND ALL SUBSEQUENT
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C P2 VALUES BY AP1 TO ENSURE THAT AN OVERFLOW DOES NOT OCCUR
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C PREMATURELY.
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C-----------------------------------------------------------------------
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ARG = (AP2+AP2)/(AP1*TOL)
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TEST1 = DSQRT(ARG)
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TEST = TEST1
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RAP1 = 1.0D0/AP1
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P1R = P1R*RAP1
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P1I = P1I*RAP1
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P2R = P2R*RAP1
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P2I = P2I*RAP1
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AP2 = AP2*RAP1
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10 CONTINUE
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K = K + 1
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AP1 = AP2
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PTR = P2R
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PTI = P2I
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P2R = P1R - (T1R*PTR-T1I*PTI)
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P2I = P1I - (T1R*PTI+T1I*PTR)
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P1R = PTR
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P1I = PTI
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T1R = T1R + RZR
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T1I = T1I + RZI
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AP2 = ZABS(COMPLEX(P2R,P2I))
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IF (AP1.LE.TEST) GO TO 10
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IF (ITIME.EQ.2) GO TO 20
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AK = ZABS(COMPLEX(T1R,T1I)*0.5D0)
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FLAM = AK + DSQRT(AK*AK-1.0D0)
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RHO = DMIN1(AP2/AP1,FLAM)
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TEST = TEST1*DSQRT(RHO/(RHO*RHO-1.0D0))
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ITIME = 2
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GO TO 10
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20 CONTINUE
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KK = K + 1 - ID
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AK = DBLE(FLOAT(KK))
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T1R = AK
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T1I = CZEROI
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DFNU = FNU + DBLE(FLOAT(N-1))
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P1R = 1.0D0/AP2
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P1I = CZEROI
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P2R = CZEROR
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P2I = CZEROI
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DO 30 I=1,KK
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PTR = P1R
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PTI = P1I
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RAP1 = DFNU + T1R
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TTR = RZR*RAP1
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TTI = RZI*RAP1
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P1R = (PTR*TTR-PTI*TTI) + P2R
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P1I = (PTR*TTI+PTI*TTR) + P2I
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P2R = PTR
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P2I = PTI
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T1R = T1R - CONER
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30 CONTINUE
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IF (P1R.NE.CZEROR .OR. P1I.NE.CZEROI) GO TO 40
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P1R = TOL
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P1I = TOL
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40 CONTINUE
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CALL ZDIV(P2R, P2I, P1R, P1I, CYR(N), CYI(N))
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IF (N.EQ.1) RETURN
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K = N - 1
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AK = DBLE(FLOAT(K))
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T1R = AK
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T1I = CZEROI
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CDFNUR = FNU*RZR
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CDFNUI = FNU*RZI
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DO 60 I=2,N
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PTR = CDFNUR + (T1R*RZR-T1I*RZI) + CYR(K+1)
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PTI = CDFNUI + (T1R*RZI+T1I*RZR) + CYI(K+1)
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AK = ZABS(COMPLEX(PTR,PTI))
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IF (AK.NE.CZEROR) GO TO 50
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PTR = TOL
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PTI = TOL
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AK = TOL*RT2
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50 CONTINUE
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RAK = CONER/AK
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CYR(K) = RAK*PTR*RAK
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CYI(K) = -RAK*PTI*RAK
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T1R = T1R - CONER
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K = K - 1
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60 CONTINUE
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RETURN
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END
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