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286 lines
12 KiB
Fortran
286 lines
12 KiB
Fortran
*DECK ZBESK
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SUBROUTINE ZBESK (ZR, ZI, FNU, KODE, N, CYR, CYI, NZ, IERR)
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C***BEGIN PROLOGUE ZBESK
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C***PURPOSE Compute a sequence of the Bessel functions K(a,z) for
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C complex argument z and real nonnegative orders a=b,b+1,
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C b+2,... where b>0. A scaling option is available to
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C help avoid overflow.
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C***LIBRARY SLATEC
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C***CATEGORY C10B4
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C***TYPE COMPLEX (CBESK-C, ZBESK-C)
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C***KEYWORDS BESSEL FUNCTIONS OF COMPLEX ARGUMENT, K BESSEL FUNCTIONS,
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C MODIFIED BESSEL FUNCTIONS
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C***AUTHOR Amos, D. E., (SNL)
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C***DESCRIPTION
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C
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C ***A DOUBLE PRECISION ROUTINE***
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C On KODE=1, ZBESK computes an N member sequence of complex
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C Bessel functions CY(L)=K(FNU+L-1,Z) for real nonnegative
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C orders FNU+L-1, L=1,...,N and complex Z.NE.0 in the cut
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C plane -pi<arg(Z)<=pi where Z=ZR+i*ZI. On KODE=2, CBESJ
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C returns the scaled functions
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C
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C CY(L) = exp(Z)*K(FNU+L-1,Z), L=1,...,N
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C
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C which remove the exponential growth in both the left and
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C right half planes as Z goes to infinity. Definitions and
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C notation are found in the NBS Handbook of Mathematical
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C Functions (Ref. 1).
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C
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C Input
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C ZR - DOUBLE PRECISION real part of nonzero argument Z
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C ZI - DOUBLE PRECISION imag part of nonzero argument Z
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C FNU - DOUBLE PRECISION initial order, FNU>=0
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C KODE - A parameter to indicate the scaling option
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C KODE=1 returns
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C CY(L)=K(FNU+L-1,Z), L=1,...,N
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C =2 returns
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C CY(L)=K(FNU+L-1,Z)*EXP(Z), L=1,...,N
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C N - Number of terms in the sequence, N>=1
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C
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C Output
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C CYR - DOUBLE PRECISION real part of result vector
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C CYI - DOUBLE PRECISION imag part of result vector
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C NZ - Number of underflows set to zero
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C NZ=0 Normal return
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C NZ>0 CY(L)=0 for NZ values of L (if Re(Z)>0
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C then CY(L)=0 for L=1,...,NZ; in the
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C complementary half plane the underflows
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C may not be in an uninterrupted sequence)
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C IERR - Error flag
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C IERR=0 Normal return - COMPUTATION COMPLETED
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C IERR=1 Input error - NO COMPUTATION
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C IERR=2 Overflow - NO COMPUTATION
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C (abs(Z) too small and/or FNU+N-1
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C too large)
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C IERR=3 Precision warning - COMPUTATION COMPLETED
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C (Result has half precision or less
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C because abs(Z) or FNU+N-1 is large)
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C IERR=4 Precision error - NO COMPUTATION
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C (Result has no precision because
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C abs(Z) or FNU+N-1 is too large)
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C IERR=5 Algorithmic error - NO COMPUTATION
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C (Termination condition not met)
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C
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C *Long Description:
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C
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C Equations of the reference are implemented to compute K(a,z)
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C for small orders a and a+1 in the right half plane Re(z)>=0.
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C Forward recurrence generates higher orders. The formula
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C
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C K(a,z*exp((t)) = exp(-t)*K(a,z) - t*I(a,z), Re(z)>0
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C t = i*pi or -i*pi
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C
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C continues K to the left half plane.
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C
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C For large orders, K(a,z) is computed by means of its uniform
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C asymptotic expansion.
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C
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C For negative orders, the formula
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C
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C K(-a,z) = K(a,z)
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C
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C can be used.
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C
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C CBESK assumes that a significant digit sinh function is
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C available.
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C
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C In most complex variable computation, one must evaluate ele-
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C mentary functions. When the magnitude of Z or FNU+N-1 is
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C large, losses of significance by argument reduction occur.
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C Consequently, if either one exceeds U1=SQRT(0.5/UR), then
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C losses exceeding half precision are likely and an error flag
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C IERR=3 is triggered where UR=MAX(D1MACH(4),1.0D-18) is double
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C precision unit roundoff limited to 18 digits precision. Also,
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C if either is larger than U2=0.5/UR, then all significance is
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C lost and IERR=4. In order to use the INT function, arguments
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C must be further restricted not to exceed the largest machine
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C integer, U3=I1MACH(9). Thus, the magnitude of Z and FNU+N-1
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C is restricted by MIN(U2,U3). In IEEE arithmetic, U1,U2, and
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C U3 approximate 2.0E+3, 4.2E+6, 2.1E+9 in single precision
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C and 4.7E+7, 2.3E+15 and 2.1E+9 in double precision. This
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C makes U2 limiting in single precision and U3 limiting in
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C double precision. This means that one can expect to retain,
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C in the worst cases on IEEE machines, no digits in single pre-
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C cision and only 6 digits in double precision. Similar con-
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C siderations hold for other machines.
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C
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C The approximate relative error in the magnitude of a complex
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C Bessel function can be expressed as P*10**S where P=MAX(UNIT
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C ROUNDOFF,1.0E-18) is the nominal precision and 10**S repre-
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C sents the increase in error due to argument reduction in the
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C elementary functions. Here, S=MAX(1,ABS(LOG10(ABS(Z))),
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C ABS(LOG10(FNU))) approximately (i.e., S=MAX(1,ABS(EXPONENT OF
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C ABS(Z),ABS(EXPONENT OF FNU)) ). However, the phase angle may
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C have only absolute accuracy. This is most likely to occur
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C when one component (in magnitude) is larger than the other by
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C several orders of magnitude. If one component is 10**K larger
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C than the other, then one can expect only MAX(ABS(LOG10(P))-K,
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C 0) significant digits; or, stated another way, when K exceeds
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C the exponent of P, no significant digits remain in the smaller
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C component. However, the phase angle retains absolute accuracy
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C because, in complex arithmetic with precision P, the smaller
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C component will not (as a rule) decrease below P times the
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C magnitude of the larger component. In these extreme cases,
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C the principal phase angle is on the order of +P, -P, PI/2-P,
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C or -PI/2+P.
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C
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C***REFERENCES 1. M. Abramowitz and I. A. Stegun, Handbook of Mathe-
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C matical Functions, National Bureau of Standards
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C Applied Mathematics Series 55, U. S. Department
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C of Commerce, Tenth Printing (1972) or later.
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C 2. D. E. Amos, Computation of Bessel Functions of
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C Complex Argument, Report SAND83-0086, Sandia National
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C Laboratories, Albuquerque, NM, May 1983.
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C 3. D. E. Amos, Computation of Bessel Functions of
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C Complex Argument and Large Order, Report SAND83-0643,
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C Sandia National Laboratories, Albuquerque, NM, May
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C 1983.
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C 4. D. E. Amos, A Subroutine Package for Bessel Functions
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C of a Complex Argument and Nonnegative Order, Report
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C SAND85-1018, Sandia National Laboratory, Albuquerque,
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C NM, May 1985.
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C 5. D. E. Amos, A portable package for Bessel functions
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C of a complex argument and nonnegative order, ACM
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C Transactions on Mathematical Software, 12 (September
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C 1986), pp. 265-273.
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C
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C***ROUTINES CALLED D1MACH, I1MACH, ZABS, ZACON, ZBKNU, ZBUNK, ZUOIK
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C***REVISION HISTORY (YYMMDD)
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C 830501 DATE WRITTEN
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C 890801 REVISION DATE from Version 3.2
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C 910415 Prologue converted to Version 4.0 format. (BAB)
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C 920128 Category corrected. (WRB)
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C 920811 Prologue revised. (DWL)
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C***END PROLOGUE ZBESK
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C
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C COMPLEX CY,Z
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DOUBLE PRECISION AA, ALIM, ALN, ARG, AZ, CYI, CYR, DIG, ELIM, FN,
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* FNU, FNUL, RL, R1M5, TOL, UFL, ZI, ZR, D1MACH, ZABS, BB
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INTEGER IERR, K, KODE, K1, K2, MR, N, NN, NUF, NW, NZ, I1MACH
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DIMENSION CYR(N), CYI(N)
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EXTERNAL ZABS
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C***FIRST EXECUTABLE STATEMENT ZBESK
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IERR = 0
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NZ=0
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IF (ZI.EQ.0.0E0 .AND. ZR.EQ.0.0E0) IERR=1
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IF (FNU.LT.0.0D0) IERR=1
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IF (KODE.LT.1 .OR. KODE.GT.2) IERR=1
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IF (N.LT.1) IERR=1
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IF (IERR.NE.0) RETURN
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NN = N
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C-----------------------------------------------------------------------
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C SET PARAMETERS RELATED TO MACHINE CONSTANTS.
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C TOL IS THE APPROXIMATE UNIT ROUNDOFF LIMITED TO 1.0E-18.
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C ELIM IS THE APPROXIMATE EXPONENTIAL OVER- AND UNDERFLOW LIMIT.
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C EXP(-ELIM).LT.EXP(-ALIM)=EXP(-ELIM)/TOL AND
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C EXP(ELIM).GT.EXP(ALIM)=EXP(ELIM)*TOL ARE INTERVALS NEAR
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C UNDERFLOW AND OVERFLOW LIMITS WHERE SCALED ARITHMETIC IS DONE.
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C RL IS THE LOWER BOUNDARY OF THE ASYMPTOTIC EXPANSION FOR LARGE Z.
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C DIG = NUMBER OF BASE 10 DIGITS IN TOL = 10**(-DIG).
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C FNUL IS THE LOWER BOUNDARY OF THE ASYMPTOTIC SERIES FOR LARGE FNU
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C-----------------------------------------------------------------------
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TOL = MAX(D1MACH(4),1.0D-18)
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K1 = I1MACH(15)
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K2 = I1MACH(16)
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R1M5 = D1MACH(5)
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K = MIN(ABS(K1),ABS(K2))
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ELIM = 2.303D0*(K*R1M5-3.0D0)
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K1 = I1MACH(14) - 1
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AA = R1M5*K1
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DIG = MIN(AA,18.0D0)
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AA = AA*2.303D0
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ALIM = ELIM + MAX(-AA,-41.45D0)
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FNUL = 10.0D0 + 6.0D0*(DIG-3.0D0)
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RL = 1.2D0*DIG + 3.0D0
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C-----------------------------------------------------------------------
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C TEST FOR PROPER RANGE
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C-----------------------------------------------------------------------
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AZ = ZABS(ZR,ZI)
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FN = FNU + (NN-1)
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AA = 0.5D0/TOL
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BB = I1MACH(9)*0.5D0
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AA = MIN(AA,BB)
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IF (AZ.GT.AA) GO TO 260
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IF (FN.GT.AA) GO TO 260
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AA = SQRT(AA)
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IF (AZ.GT.AA) IERR=3
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IF (FN.GT.AA) IERR=3
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C-----------------------------------------------------------------------
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C OVERFLOW TEST ON THE LAST MEMBER OF THE SEQUENCE
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C-----------------------------------------------------------------------
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C UFL = EXP(-ELIM)
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UFL = D1MACH(1)*1.0D+3
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IF (AZ.LT.UFL) GO TO 180
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IF (FNU.GT.FNUL) GO TO 80
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IF (FN.LE.1.0D0) GO TO 60
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IF (FN.GT.2.0D0) GO TO 50
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IF (AZ.GT.TOL) GO TO 60
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ARG = 0.5D0*AZ
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ALN = -FN*LOG(ARG)
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IF (ALN.GT.ELIM) GO TO 180
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GO TO 60
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50 CONTINUE
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CALL ZUOIK(ZR, ZI, FNU, KODE, 2, NN, CYR, CYI, NUF, TOL, ELIM,
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* ALIM)
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IF (NUF.LT.0) GO TO 180
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NZ = NZ + NUF
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NN = NN - NUF
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C-----------------------------------------------------------------------
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C HERE NN=N OR NN=0 SINCE NUF=0,NN, OR -1 ON RETURN FROM CUOIK
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C IF NUF=NN, THEN CY(I)=CZERO FOR ALL I
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C-----------------------------------------------------------------------
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IF (NN.EQ.0) GO TO 100
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60 CONTINUE
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IF (ZR.LT.0.0D0) GO TO 70
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C-----------------------------------------------------------------------
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C RIGHT HALF PLANE COMPUTATION, REAL(Z).GE.0.
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C-----------------------------------------------------------------------
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CALL ZBKNU(ZR, ZI, FNU, KODE, NN, CYR, CYI, NW, TOL, ELIM, ALIM)
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IF (NW.LT.0) GO TO 200
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NZ=NW
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RETURN
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C-----------------------------------------------------------------------
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C LEFT HALF PLANE COMPUTATION
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C PI/2.LT.ARG(Z).LE.PI AND -PI.LT.ARG(Z).LT.-PI/2.
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C-----------------------------------------------------------------------
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70 CONTINUE
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IF (NZ.NE.0) GO TO 180
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MR = 1
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IF (ZI.LT.0.0D0) MR = -1
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CALL ZACON(ZR, ZI, FNU, KODE, MR, NN, CYR, CYI, NW, RL, FNUL,
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* TOL, ELIM, ALIM)
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IF (NW.LT.0) GO TO 200
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NZ=NW
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RETURN
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C-----------------------------------------------------------------------
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C UNIFORM ASYMPTOTIC EXPANSIONS FOR FNU.GT.FNUL
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C-----------------------------------------------------------------------
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80 CONTINUE
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MR = 0
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IF (ZR.GE.0.0D0) GO TO 90
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MR = 1
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IF (ZI.LT.0.0D0) MR = -1
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90 CONTINUE
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CALL ZBUNK(ZR, ZI, FNU, KODE, MR, NN, CYR, CYI, NW, TOL, ELIM,
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* ALIM)
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IF (NW.LT.0) GO TO 200
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NZ = NZ + NW
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RETURN
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100 CONTINUE
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IF (ZR.LT.0.0D0) GO TO 180
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RETURN
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180 CONTINUE
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NZ = 0
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IERR=2
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RETURN
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200 CONTINUE
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IF(NW.EQ.(-1)) GO TO 180
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NZ=0
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IERR=5
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RETURN
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260 CONTINUE
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NZ=0
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IERR=4
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RETURN
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END
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