mirror of
https://git.planet-casio.com/Lephenixnoir/OpenLibm.git
synced 2025-01-01 06:23:39 +01:00
499 lines
16 KiB
Fortran
499 lines
16 KiB
Fortran
*DECK HWSCYL
|
|
SUBROUTINE HWSCYL (A, B, M, MBDCND, BDA, BDB, C, D, N, NBDCND,
|
|
+ BDC, BDD, ELMBDA, F, IDIMF, PERTRB, IERROR, W)
|
|
C***BEGIN PROLOGUE HWSCYL
|
|
C***PURPOSE Solve a standard finite difference approximation
|
|
C to the Helmholtz equation in cylindrical coordinates.
|
|
C***LIBRARY SLATEC (FISHPACK)
|
|
C***CATEGORY I2B1A1A
|
|
C***TYPE SINGLE PRECISION (HWSCYL-S)
|
|
C***KEYWORDS CYLINDRICAL, ELLIPTIC, FISHPACK, HELMHOLTZ, PDE
|
|
C***AUTHOR Adams, J., (NCAR)
|
|
C Swarztrauber, P. N., (NCAR)
|
|
C Sweet, R., (NCAR)
|
|
C***DESCRIPTION
|
|
C
|
|
C Subroutine HWSCYL solves a finite difference approximation to the
|
|
C Helmholtz equation in cylindrical coordinates:
|
|
C
|
|
C (1/R)(d/dR)(R(dU/dR)) + (d/dZ)(dU/dZ)
|
|
C
|
|
C + (LAMBDA/R**2)U = F(R,Z)
|
|
C
|
|
C This modified Helmholtz equation results from the Fourier
|
|
C transform of the three-dimensional Poisson equation.
|
|
C
|
|
C * * * * * * * * Parameter Description * * * * * * * * * *
|
|
C
|
|
C * * * * * * On Input * * * * * *
|
|
C
|
|
C A,B
|
|
C The range of R, i.e., A .LE. R .LE. B. A must be less than B
|
|
C and A must be non-negative.
|
|
C
|
|
C M
|
|
C The number of panels into which the interval (A,B) is
|
|
C subdivided. Hence, there will be M+1 grid points in the
|
|
C R-direction given by R(I) = A+(I-1)DR, for I = 1,2,...,M+1,
|
|
C where DR = (B-A)/M is the panel width. M must be greater than 3.
|
|
C
|
|
C MBDCND
|
|
C Indicates the type of boundary conditions at R = A and R = B.
|
|
C
|
|
C = 1 If the solution is specified at R = A and R = B.
|
|
C = 2 If the solution is specified at R = A and the derivative of
|
|
C the solution with respect to R is specified at R = B.
|
|
C = 3 If the derivative of the solution with respect to R is
|
|
C specified at R = A (see note below) and R = B.
|
|
C = 4 If the derivative of the solution with respect to R is
|
|
C specified at R = A (see note below) and the solution is
|
|
C specified at R = B.
|
|
C = 5 If the solution is unspecified at R = A = 0 and the
|
|
C solution is specified at R = B.
|
|
C = 6 If the solution is unspecified at R = A = 0 and the
|
|
C derivative of the solution with respect to R is specified
|
|
C at R = B.
|
|
C
|
|
C NOTE: If A = 0, do not use MBDCND = 3 or 4, but instead use
|
|
C MBDCND = 1,2,5, or 6 .
|
|
C
|
|
C BDA
|
|
C A one-dimensional array of length N+1 that specifies the values
|
|
C of the derivative of the solution with respect to R at R = A.
|
|
C When MBDCND = 3 or 4,
|
|
C
|
|
C BDA(J) = (d/dR)U(A,Z(J)), J = 1,2,...,N+1 .
|
|
C
|
|
C When MBDCND has any other value, BDA is a dummy variable.
|
|
C
|
|
C BDB
|
|
C A one-dimensional array of length N+1 that specifies the values
|
|
C of the derivative of the solution with respect to R at R = B.
|
|
C When MBDCND = 2,3, or 6,
|
|
C
|
|
C BDB(J) = (d/dR)U(B,Z(J)), J = 1,2,...,N+1 .
|
|
C
|
|
C When MBDCND has any other value, BDB is a dummy variable.
|
|
C
|
|
C C,D
|
|
C The range of Z, i.e., C .LE. Z .LE. D. C must be less than D.
|
|
C
|
|
C N
|
|
C The number of panels into which the interval (C,D) is
|
|
C subdivided. Hence, there will be N+1 grid points in the
|
|
C Z-direction given by Z(J) = C+(J-1)DZ, for J = 1,2,...,N+1,
|
|
C where DZ = (D-C)/N is the panel width. N must be greater than 3.
|
|
C
|
|
C NBDCND
|
|
C Indicates the type of boundary conditions at Z = C and Z = D.
|
|
C
|
|
C = 0 If the solution is periodic in Z, i.e., U(I,1) = U(I,N+1).
|
|
C = 1 If the solution is specified at Z = C and Z = D.
|
|
C = 2 If the solution is specified at Z = C and the derivative of
|
|
C the solution with respect to Z is specified at Z = D.
|
|
C = 3 If the derivative of the solution with respect to Z is
|
|
C specified at Z = C and Z = D.
|
|
C = 4 If the derivative of the solution with respect to Z is
|
|
C specified at Z = C and the solution is specified at Z = D.
|
|
C
|
|
C BDC
|
|
C A one-dimensional array of length M+1 that specifies the values
|
|
C of the derivative of the solution with respect to Z at Z = C.
|
|
C When NBDCND = 3 or 4,
|
|
C
|
|
C BDC(I) = (d/dZ)U(R(I),C), I = 1,2,...,M+1 .
|
|
C
|
|
C When NBDCND has any other value, BDC is a dummy variable.
|
|
C
|
|
C BDD
|
|
C A one-dimensional array of length M+1 that specifies the values
|
|
C of the derivative of the solution with respect to Z at Z = D.
|
|
C When NBDCND = 2 or 3,
|
|
C
|
|
C BDD(I) = (d/dZ)U(R(I),D), I = 1,2,...,M+1 .
|
|
C
|
|
C When NBDCND has any other value, BDD is a dummy variable.
|
|
C
|
|
C ELMBDA
|
|
C The constant LAMBDA in the Helmholtz equation. If
|
|
C LAMBDA .GT. 0, a solution may not exist. However, HWSCYL will
|
|
C attempt to find a solution. LAMBDA must be zero when
|
|
C MBDCND = 5 or 6 .
|
|
C
|
|
C F
|
|
C A two-dimensional array that specifies the values of the right
|
|
C side of the Helmholtz equation and boundary data (if any). For
|
|
C I = 2,3,...,M and J = 2,3,...,N
|
|
C
|
|
C F(I,J) = F(R(I),Z(J)).
|
|
C
|
|
C On the boundaries F is defined by
|
|
C
|
|
C MBDCND F(1,J) F(M+1,J)
|
|
C ------ --------- ---------
|
|
C
|
|
C 1 U(A,Z(J)) U(B,Z(J))
|
|
C 2 U(A,Z(J)) F(B,Z(J))
|
|
C 3 F(A,Z(J)) F(B,Z(J)) J = 1,2,...,N+1
|
|
C 4 F(A,Z(J)) U(B,Z(J))
|
|
C 5 F(0,Z(J)) U(B,Z(J))
|
|
C 6 F(0,Z(J)) F(B,Z(J))
|
|
C
|
|
C NBDCND F(I,1) F(I,N+1)
|
|
C ------ --------- ---------
|
|
C
|
|
C 0 F(R(I),C) F(R(I),C)
|
|
C 1 U(R(I),C) U(R(I),D)
|
|
C 2 U(R(I),C) F(R(I),D) I = 1,2,...,M+1
|
|
C 3 F(R(I),C) F(R(I),D)
|
|
C 4 F(R(I),C) U(R(I),D)
|
|
C
|
|
C F must be dimensioned at least (M+1)*(N+1).
|
|
C
|
|
C NOTE
|
|
C
|
|
C If the table calls for both the solution U and the right side F
|
|
C at a corner then the solution must be specified.
|
|
C
|
|
C IDIMF
|
|
C The row (or first) dimension of the array F as it appears in the
|
|
C program calling HWSCYL. This parameter is used to specify the
|
|
C variable dimension of F. IDIMF must be at least M+1 .
|
|
C
|
|
C W
|
|
C A one-dimensional array that must be provided by the user for
|
|
C work space. W may require up to 4*(N+1) +
|
|
C (13 + INT(log2(N+1)))*(M+1) locations. The actual number of
|
|
C locations used is computed by HWSCYL and is returned in location
|
|
C W(1).
|
|
C
|
|
C
|
|
C * * * * * * On Output * * * * * *
|
|
C
|
|
C F
|
|
C Contains the solution U(I,J) of the finite difference
|
|
C approximation for the grid point (R(I),Z(J)), I = 1,2,...,M+1,
|
|
C J = 1,2,...,N+1 .
|
|
C
|
|
C PERTRB
|
|
C If one specifies a combination of periodic, derivative, and
|
|
C unspecified boundary conditions for a Poisson equation
|
|
C (LAMBDA = 0), a solution may not exist. PERTRB is a constant,
|
|
C calculated and subtracted from F, which ensures that a solution
|
|
C exists. HWSCYL then computes this solution, which is a least
|
|
C squares solution to the original approximation. This solution
|
|
C plus any constant is also a solution. Hence, the solution is
|
|
C not unique. The value of PERTRB should be small compared to the
|
|
C right side F. Otherwise, a solution is obtained to an
|
|
C essentially different problem. This comparison should always
|
|
C be made to insure that a meaningful solution has been obtained.
|
|
C
|
|
C IERROR
|
|
C An error flag which indicates invalid input parameters. Except
|
|
C for numbers 0 and 11, a solution is not attempted.
|
|
C
|
|
C = 0 No error.
|
|
C = 1 A .LT. 0 .
|
|
C = 2 A .GE. B.
|
|
C = 3 MBDCND .LT. 1 or MBDCND .GT. 6 .
|
|
C = 4 C .GE. D.
|
|
C = 5 N .LE. 3
|
|
C = 6 NBDCND .LT. 0 or NBDCND .GT. 4 .
|
|
C = 7 A = 0, MBDCND = 3 or 4 .
|
|
C = 8 A .GT. 0, MBDCND .GE. 5 .
|
|
C = 9 A = 0, LAMBDA .NE. 0, MBDCND .GE. 5 .
|
|
C = 10 IDIMF .LT. M+1 .
|
|
C = 11 LAMBDA .GT. 0 .
|
|
C = 12 M .LE. 3
|
|
C
|
|
C Since this is the only means of indicating a possibly incorrect
|
|
C call to HWSCYL, the user should test IERROR after the call.
|
|
C
|
|
C W
|
|
C W(1) contains the required length of W.
|
|
C
|
|
C *Long Description:
|
|
C
|
|
C * * * * * * * Program Specifications * * * * * * * * * * * *
|
|
C
|
|
C Dimension of BDA(N+1),BDB(N+1),BDC(M+1),BDD(M+1),F(IDIMF,N+1),
|
|
C Arguments W(see argument list)
|
|
C
|
|
C Latest June 1, 1976
|
|
C Revision
|
|
C
|
|
C Subprograms HWSCYL,GENBUN,POISD2,POISN2,POISP2,COSGEN,MERGE,
|
|
C Required TRIX,TRI3,PIMACH
|
|
C
|
|
C Special NONE
|
|
C Conditions
|
|
C
|
|
C Common NONE
|
|
C Blocks
|
|
C
|
|
C I/O NONE
|
|
C
|
|
C Precision Single
|
|
C
|
|
C Specialist Roland Sweet
|
|
C
|
|
C Language FORTRAN
|
|
C
|
|
C History Standardized September 1, 1973
|
|
C Revised April 1, 1976
|
|
C
|
|
C Algorithm The routine defines the finite difference
|
|
C equations, incorporates boundary data, and adjusts
|
|
C the right side of singular systems and then calls
|
|
C GENBUN to solve the system.
|
|
C
|
|
C Space 5818(decimal) = 13272(octal) locations on the NCAR
|
|
C Required Control Data 7600
|
|
C
|
|
C Timing and The execution time T on the NCAR Control Data
|
|
C Accuracy 7600 for subroutine HWSCYL is roughly proportional
|
|
C to M*N*log2(N), but also depends on the input
|
|
C parameters NBDCND and MBDCND. Some typical values
|
|
C are listed in the table below.
|
|
C The solution process employed results in a loss
|
|
C of no more than three significant digits for N and
|
|
C M as large as 64. More detailed information about
|
|
C accuracy can be found in the documentation for
|
|
C subroutine GENBUN which is the routine that
|
|
C solves the finite difference equations.
|
|
C
|
|
C
|
|
C M(=N) MBDCND NBDCND T(MSECS)
|
|
C ----- ------ ------ --------
|
|
C
|
|
C 32 1 0 31
|
|
C 32 1 1 23
|
|
C 32 3 3 36
|
|
C 64 1 0 128
|
|
C 64 1 1 96
|
|
C 64 3 3 142
|
|
C
|
|
C Portability American National Standards Institute FORTRAN.
|
|
C The machine dependent constant PI is defined in
|
|
C function PIMACH.
|
|
C
|
|
C Required COS
|
|
C Resident
|
|
C Routines
|
|
C
|
|
C Reference Swarztrauber, P. and R. Sweet, 'Efficient FORTRAN
|
|
C Subprograms for the Solution of Elliptic Equations'
|
|
C NCAR TN/IA-109, July, 1975, 138 pp.
|
|
C
|
|
C * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
|
|
C
|
|
C***REFERENCES P. N. Swarztrauber and R. Sweet, Efficient Fortran
|
|
C subprograms for the solution of elliptic equations,
|
|
C NCAR TN/IA-109, July 1975, 138 pp.
|
|
C***ROUTINES CALLED GENBUN
|
|
C***REVISION HISTORY (YYMMDD)
|
|
C 801001 DATE WRITTEN
|
|
C 890531 Changed all specific intrinsics to generic. (WRB)
|
|
C 890531 REVISION DATE from Version 3.2
|
|
C 891214 Prologue converted to Version 4.0 format. (BAB)
|
|
C 920501 Reformatted the REFERENCES section. (WRB)
|
|
C***END PROLOGUE HWSCYL
|
|
C
|
|
C
|
|
DIMENSION F(IDIMF,*)
|
|
DIMENSION BDA(*) ,BDB(*) ,BDC(*) ,BDD(*) ,
|
|
1 W(*)
|
|
C***FIRST EXECUTABLE STATEMENT HWSCYL
|
|
IERROR = 0
|
|
IF (A .LT. 0.) IERROR = 1
|
|
IF (A .GE. B) IERROR = 2
|
|
IF (MBDCND.LE.0 .OR. MBDCND.GE.7) IERROR = 3
|
|
IF (C .GE. D) IERROR = 4
|
|
IF (N .LE. 3) IERROR = 5
|
|
IF (NBDCND.LE.-1 .OR. NBDCND.GE.5) IERROR = 6
|
|
IF (A.EQ.0. .AND. (MBDCND.EQ.3 .OR. MBDCND.EQ.4)) IERROR = 7
|
|
IF (A.GT.0. .AND. MBDCND.GE.5) IERROR = 8
|
|
IF (A.EQ.0. .AND. ELMBDA.NE.0. .AND. MBDCND.GE.5) IERROR = 9
|
|
IF (IDIMF .LT. M+1) IERROR = 10
|
|
IF (M .LE. 3) IERROR = 12
|
|
IF (IERROR .NE. 0) RETURN
|
|
MP1 = M+1
|
|
DELTAR = (B-A)/M
|
|
DLRBY2 = DELTAR/2.
|
|
DLRSQ = DELTAR**2
|
|
NP1 = N+1
|
|
DELTHT = (D-C)/N
|
|
DLTHSQ = DELTHT**2
|
|
NP = NBDCND+1
|
|
C
|
|
C DEFINE RANGE OF INDICES I AND J FOR UNKNOWNS U(I,J).
|
|
C
|
|
MSTART = 2
|
|
MSTOP = M
|
|
GO TO (104,103,102,101,101,102),MBDCND
|
|
101 MSTART = 1
|
|
GO TO 104
|
|
102 MSTART = 1
|
|
103 MSTOP = MP1
|
|
104 MUNK = MSTOP-MSTART+1
|
|
NSTART = 1
|
|
NSTOP = N
|
|
GO TO (108,105,106,107,108),NP
|
|
105 NSTART = 2
|
|
GO TO 108
|
|
106 NSTART = 2
|
|
107 NSTOP = NP1
|
|
108 NUNK = NSTOP-NSTART+1
|
|
C
|
|
C DEFINE A,B,C COEFFICIENTS IN W-ARRAY.
|
|
C
|
|
ID2 = MUNK
|
|
ID3 = ID2+MUNK
|
|
ID4 = ID3+MUNK
|
|
ID5 = ID4+MUNK
|
|
ID6 = ID5+MUNK
|
|
ISTART = 1
|
|
A1 = 2./DLRSQ
|
|
IJ = 0
|
|
IF (MBDCND.EQ.3 .OR. MBDCND.EQ.4) IJ = 1
|
|
IF (MBDCND .LE. 4) GO TO 109
|
|
W(1) = 0.
|
|
W(ID2+1) = -2.*A1
|
|
W(ID3+1) = 2.*A1
|
|
ISTART = 2
|
|
IJ = 1
|
|
109 DO 110 I=ISTART,MUNK
|
|
R = A+(I-IJ)*DELTAR
|
|
J = ID5+I
|
|
W(J) = R
|
|
J = ID6+I
|
|
W(J) = 1./R**2
|
|
W(I) = (R-DLRBY2)/(R*DLRSQ)
|
|
J = ID3+I
|
|
W(J) = (R+DLRBY2)/(R*DLRSQ)
|
|
K = ID6+I
|
|
J = ID2+I
|
|
W(J) = -A1+ELMBDA*W(K)
|
|
110 CONTINUE
|
|
GO TO (114,111,112,113,114,112),MBDCND
|
|
111 W(ID2) = A1
|
|
GO TO 114
|
|
112 W(ID2) = A1
|
|
113 W(ID3+1) = A1*ISTART
|
|
114 CONTINUE
|
|
C
|
|
C ENTER BOUNDARY DATA FOR R-BOUNDARIES.
|
|
C
|
|
GO TO (115,115,117,117,119,119),MBDCND
|
|
115 A1 = W(1)
|
|
DO 116 J=NSTART,NSTOP
|
|
F(2,J) = F(2,J)-A1*F(1,J)
|
|
116 CONTINUE
|
|
GO TO 119
|
|
117 A1 = 2.*DELTAR*W(1)
|
|
DO 118 J=NSTART,NSTOP
|
|
F(1,J) = F(1,J)+A1*BDA(J)
|
|
118 CONTINUE
|
|
119 GO TO (120,122,122,120,120,122),MBDCND
|
|
120 A1 = W(ID4)
|
|
DO 121 J=NSTART,NSTOP
|
|
F(M,J) = F(M,J)-A1*F(MP1,J)
|
|
121 CONTINUE
|
|
GO TO 124
|
|
122 A1 = 2.*DELTAR*W(ID4)
|
|
DO 123 J=NSTART,NSTOP
|
|
F(MP1,J) = F(MP1,J)-A1*BDB(J)
|
|
123 CONTINUE
|
|
C
|
|
C ENTER BOUNDARY DATA FOR Z-BOUNDARIES.
|
|
C
|
|
124 A1 = 1./DLTHSQ
|
|
L = ID5-MSTART+1
|
|
GO TO (134,125,125,127,127),NP
|
|
125 DO 126 I=MSTART,MSTOP
|
|
F(I,2) = F(I,2)-A1*F(I,1)
|
|
126 CONTINUE
|
|
GO TO 129
|
|
127 A1 = 2./DELTHT
|
|
DO 128 I=MSTART,MSTOP
|
|
F(I,1) = F(I,1)+A1*BDC(I)
|
|
128 CONTINUE
|
|
129 A1 = 1./DLTHSQ
|
|
GO TO (134,130,132,132,130),NP
|
|
130 DO 131 I=MSTART,MSTOP
|
|
F(I,N) = F(I,N)-A1*F(I,NP1)
|
|
131 CONTINUE
|
|
GO TO 134
|
|
132 A1 = 2./DELTHT
|
|
DO 133 I=MSTART,MSTOP
|
|
F(I,NP1) = F(I,NP1)-A1*BDD(I)
|
|
133 CONTINUE
|
|
134 CONTINUE
|
|
C
|
|
C ADJUST RIGHT SIDE OF SINGULAR PROBLEMS TO INSURE EXISTENCE OF A
|
|
C SOLUTION.
|
|
C
|
|
PERTRB = 0.
|
|
IF (ELMBDA) 146,136,135
|
|
135 IERROR = 11
|
|
GO TO 146
|
|
136 W(ID5+1) = .5*(W(ID5+2)-DLRBY2)
|
|
GO TO (146,146,138,146,146,137),MBDCND
|
|
137 W(ID5+1) = .5*W(ID5+1)
|
|
138 GO TO (140,146,146,139,146),NP
|
|
139 A2 = 2.
|
|
GO TO 141
|
|
140 A2 = 1.
|
|
141 K = ID5+MUNK
|
|
W(K) = .5*(W(K-1)+DLRBY2)
|
|
S = 0.
|
|
DO 143 I=MSTART,MSTOP
|
|
S1 = 0.
|
|
NSP1 = NSTART+1
|
|
NSTM1 = NSTOP-1
|
|
DO 142 J=NSP1,NSTM1
|
|
S1 = S1+F(I,J)
|
|
142 CONTINUE
|
|
K = I+L
|
|
S = S+(A2*S1+F(I,NSTART)+F(I,NSTOP))*W(K)
|
|
143 CONTINUE
|
|
S2 = M*A+(.75+(M-1)*(M+1))*DLRBY2
|
|
IF (MBDCND .EQ. 3) S2 = S2+.25*DLRBY2
|
|
S1 = (2.+A2*(NUNK-2))*S2
|
|
PERTRB = S/S1
|
|
DO 145 I=MSTART,MSTOP
|
|
DO 144 J=NSTART,NSTOP
|
|
F(I,J) = F(I,J)-PERTRB
|
|
144 CONTINUE
|
|
145 CONTINUE
|
|
146 CONTINUE
|
|
C
|
|
C MULTIPLY I-TH EQUATION THROUGH BY DELTHT**2 TO PUT EQUATION INTO
|
|
C CORRECT FORM FOR SUBROUTINE GENBUN.
|
|
C
|
|
DO 148 I=MSTART,MSTOP
|
|
K = I-MSTART+1
|
|
W(K) = W(K)*DLTHSQ
|
|
J = ID2+K
|
|
W(J) = W(J)*DLTHSQ
|
|
J = ID3+K
|
|
W(J) = W(J)*DLTHSQ
|
|
DO 147 J=NSTART,NSTOP
|
|
F(I,J) = F(I,J)*DLTHSQ
|
|
147 CONTINUE
|
|
148 CONTINUE
|
|
W(1) = 0.
|
|
W(ID4) = 0.
|
|
C
|
|
C CALL GENBUN TO SOLVE THE SYSTEM OF EQUATIONS.
|
|
C
|
|
CALL GENBUN (NBDCND,NUNK,1,MUNK,W(1),W(ID2+1),W(ID3+1),IDIMF,
|
|
1 F(MSTART,NSTART),IERR1,W(ID4+1))
|
|
W(1) = W(ID4+1)+3*MUNK
|
|
IF (NBDCND .NE. 0) GO TO 150
|
|
DO 149 I=MSTART,MSTOP
|
|
F(I,NP1) = F(I,1)
|
|
149 CONTINUE
|
|
150 CONTINUE
|
|
RETURN
|
|
END
|