NAG FL Interface
c06laf (invlaplace_crump)
1
Purpose
c06laf estimates values of the inverse Laplace transform of a given function using a Fourier series approximation. Real and imaginary parts of the function, and a bound on the exponential order of the inverse, are required.
2
Specification
Fortran Interface
Subroutine c06laf ( |
f, n, t, valinv, errest, relerr, alphab, tfac, mxterm, nterms, na, alow, ahigh, nfeval, work, ifail) |
Integer, Intent (In) |
:: |
n, mxterm |
Integer, Intent (Inout) |
:: |
ifail |
Integer, Intent (Out) |
:: |
nterms, na, nfeval |
Real (Kind=nag_wp), Intent (In) |
:: |
t(n), relerr, alphab, tfac |
Real (Kind=nag_wp), Intent (Out) |
:: |
valinv(n), errest(n), alow, ahigh, work(4*mxterm+2) |
External |
:: |
f |
|
C Header Interface
#include <nag.h>
void |
c06laf_ ( void (NAG_CALL *f)(const double *pr, const double *pi, double *fr, double *fi), const Integer *n, const double t[], double valinv[], double errest[], const double *relerr, const double *alphab, const double *tfac, const Integer *mxterm, Integer *nterms, Integer *na, double *alow, double *ahigh, Integer *nfeval, double work[], Integer *ifail) |
|
C++ Header Interface
#include <nag.h> extern "C" {
void |
c06laf_ ( void (NAG_CALL *f)(const double &pr, const double &pi, double &fr, double &fi), const Integer &n, const double t[], double valinv[], double errest[], const double &relerr, const double &alphab, const double &tfac, const Integer &mxterm, Integer &nterms, Integer &na, double &alow, double &ahigh, Integer &nfeval, double work[], Integer &ifail) |
}
|
The routine may be called by the names c06laf or nagf_sum_invlaplace_crump.
3
Description
Given a function
defined for complex values of
,
c06laf estimates values of its inverse Laplace transform by Crump's method (see
Crump (1976)). (For a definition of the Laplace transform and its inverse, see the
C06 Chapter Introduction.)
Crump's method applies the epsilon algorithm (see
Wynn (1956)) to the summation in Durbin's Fourier series approximation (see
Durbin (1974))
for
, by choosing
such that a prescribed relative error should be achieved. The method is modified slightly if
so that an estimate of
can be obtained when it has a finite value.
is calculated as
, where
. You specify
and
, an upper bound on the exponential order
of the inverse function
.
has two alternative interpretations:
-
(i) is the smallest number such that
for large ,
-
(ii) is the real part of the singularity of with largest real part.
The method depends critically on the value of
. See
Section 9 for further details. The routine calculates at least two different values of the argument
, such that
, in an attempt to achieve the requested relative error and provide error estimates. The values of
, for
, must be supplied in monotonically increasing order. The routine calculates the values of the inverse function
in decreasing order of
.
4
References
Crump K S (1976) Numerical inversion of Laplace transforms using a Fourier series approximation J. Assoc. Comput. Mach. 23 89–96
Durbin F (1974) Numerical inversion of Laplace transforms: An efficient improvement to Dubner and Abate's method Comput. J. 17 371–376
Wynn P (1956) On a device for computing the transformation Math. Tables Aids Comput. 10 91–96
5
Arguments
-
1:
– Subroutine, supplied by the user.
External Procedure
-
f must evaluate the real and imaginary parts of the function
for a given value of
.
The specification of
f is:
Fortran Interface
Real (Kind=nag_wp), Intent (In) |
:: |
pr, pi |
Real (Kind=nag_wp), Intent (Out) |
:: |
fr, fi |
|
C Header Interface
void |
f_ (const double *pr, const double *pi, double *fr, double *fi) |
|
C++ Header Interface
#include <nag.h> extern "C" {
void |
f_ (const double &pr, const double &pi, double &fr, double &fi) |
}
|
-
1:
– Real (Kind=nag_wp)
Input
-
2:
– Real (Kind=nag_wp)
Input
-
On entry: the real and imaginary parts of the argument .
-
3:
– Real (Kind=nag_wp)
Output
-
4:
– Real (Kind=nag_wp)
Output
-
On exit: the real and imaginary parts of the value .
f must either be a module subprogram USEd by, or declared as EXTERNAL in, the (sub)program from which
c06laf is called. Arguments denoted as
Input must
not be changed by this procedure.
Note: f should not return floating-point NaN (Not a Number) or infinity values, since these are not handled by
c06laf. If your code inadvertently
does return any NaNs or infinities,
c06laf is likely to produce unexpected results.
-
2:
– Integer
Input
-
On entry: , the number of points at which the value of the inverse Laplace transform is required.
Constraint:
.
-
3:
– Real (Kind=nag_wp) array
Input
-
On entry: each must specify a point at which the inverse Laplace transform is required, for .
Constraint:
.
-
4:
– Real (Kind=nag_wp) array
Output
-
On exit: an estimate of the value of the inverse Laplace transform at
, for .
-
5:
– Real (Kind=nag_wp) array
Output
-
On exit: an estimate of the error in
. This is usually an estimate of relative error but, if
,
estimates the absolute error.
is unreliable when
is small but slightly greater than
relerr.
-
6:
– Real (Kind=nag_wp)
Input
-
On entry: the required relative error in the values of the inverse Laplace transform. If the absolute value of the inverse is less than
relerr, absolute accuracy is used instead.
relerr must be in the range
. If
relerr is set too small or to
, the routine uses a value sufficiently larger than
machine precision.
-
7:
– Real (Kind=nag_wp)
Input
-
On entry:
, an upper bound for
(see
Section 3). Usually,
should be specified equal to, or slightly larger than, the value of
. If
then the prescribed accuracy may not be achieved or completely incorrect results may be obtained. If
is too large
c06laf will be inefficient and convergence may not be achieved.
Note: it is as important to specify correctly as it is to specify the correct function for inversion.
-
8:
– Real (Kind=nag_wp)
Input
-
On entry:
, a factor to be used in calculating the parameter
. Larger values (e.g.,
) may be specified for difficult problems, but these may require very large values of
mxterm.
Suggested value:
.
Constraint:
.
-
9:
– Integer
Input
-
On entry: the maximum number of (complex) terms to be used in the evaluation of the Fourier series.
Suggested value:
, except for very simple problems.
Constraint:
.
-
10:
– Integer
Output
-
On exit: the number of (complex) terms actually used.
-
11:
– Integer
Output
-
On exit: the number of values of
used by the routine. See
Section 9.
-
12:
– Real (Kind=nag_wp)
Output
-
On exit: the smallest value of
used in the algorithm. This may be used for checking the value of
see
Section 9.
-
13:
– Real (Kind=nag_wp)
Output
-
On exit: the largest value of
used in the algorithm. This may be used for checking the value of
see
Section 9.
-
14:
– Integer
Output
-
On exit: the number of calls to
f made by the routine.
-
15:
– Real (Kind=nag_wp) array
Workspace
-
-
16:
– Integer
Input/Output
-
On entry:
ifail must be set to
,
. If you are unfamiliar with this argument you should refer to
Section 4 in the Introduction to the NAG Library FL Interface for details.
For environments where it might be inappropriate to halt program execution when an error is detected, the value
is recommended. If the output of error messages is undesirable, then the value
is recommended. Otherwise, because for this routine the values of the output arguments may be useful even if
on exit, the recommended value is
.
When the value is used it is essential to test the value of ifail on exit.
On exit:
unless the routine detects an error or a warning has been flagged (see
Section 6).
6
Error Indicators and Warnings
If on entry
or
, explanatory error messages are output on the current error message unit (as defined by
x04aaf).
Errors or warnings detected by the routine:
Note: in some cases c06laf may return useful information.
-
On entry, .
Constraint: .
On entry, .
Constraint: .
On entry, .
Constraint: .
On entry, .
Constraint: .
-
On entry, .
Constraint: .
On entry, the elements of
t are not strictly increasing.
-
On entry,
is too large:
. If necessary, scale the problem as described in
Section 9.
-
Required accuracy cannot be obtained. Try increasing
tfac,
alphab, or both.
and
.
-
Convergence failure in epsilon algorithm:
. Some values of
may be calculated to the desired accuracy; this may be determined by examining the values of
. Try reducing the range of
t or increasing
mxterm. If
still results, try reducing
tfac.
-
All values of
valinv have been calculated, but are not of the required accuracy; the values of
should be examined carefully. Try reducing the range of
t, or increasing
tfac,
alphab or both.
An unexpected error has been triggered by this routine. Please
contact
NAG.
See
Section 7 in the Introduction to the NAG Library FL Interface for further information.
Your licence key may have expired or may not have been installed correctly.
See
Section 8 in the Introduction to the NAG Library FL Interface for further information.
Dynamic memory allocation failed.
See
Section 9 in the Introduction to the NAG Library FL Interface for further information.
7
Accuracy
The error estimates are often very close to the true error but, because the error control depends on an asymptotic formula, the required error may not always be met. There are two principal causes of this: Gibbs' phenomena, and zero or small values of the inverse Laplace transform.
Gibbs' phenomena (see the
C06 Chapter Introduction) are exhibited near
(due to the method) and around discontinuities in the inverse Laplace transform
. If there is a discontinuity at
then the method converges such that
.
Apparent loss of accuracy, when
is small, may not be serious. Crump's method keeps control of relative error so that good approximations to small function values may appear to be very inaccurate. If
is estimated to be less than
relerr then this routine switches to absolute error estimation. However, when
is slightly larger than
relerr the relative error estimates are likely to cause
. If this is found inconvenient it can sometimes be avoided by adding
to the function
, which shifts the inverse to
.
Loss of accuracy may also occur for highly oscillatory functions.
More serious loss of accuracy can occur if
is unknown and is incorrectly estimated. See
Section 9.
8
Parallelism and Performance
c06laf is not threaded in any implementation.
The value of
is less important in general than the value of
nterms. Unless
f is very inexpensive to compute, the timing is proportional to
. For simple problems
but in difficult problems
na may be somewhat larger.
You are referred to the
C06 Chapter Introduction for advice on simplifying problems with particular difficulties, e.g., where the inverse is known to be a step function.
The method does not work well for large values of
when
is positive. It is advisable, especially if
is obtained, to scale the problem if
is much greater than
. See the
C06 Chapter Introduction.
The range of values of specified for a particular call should not be greater than about units. This is because the method uses arguments based on the value and these tend to be less appropriate as becomes smaller. However, as the timing of the routine is not especially dependent on , it is usually far more efficient to evaluate the inverse for ranges of than to make separate calls to the routine for each value of .
The most important argument to specify correctly is
alphab, an upper bound for
. If, on entry,
alphab is sufficiently smaller than
then completely incorrect results will be obtained with
. Unless
is known theoretically it is strongly advised that you should test any estimated value used. This may be done by specifying a single value of
(i.e
,
) with two sets of suitable values of
tfac,
relerr and
mxterm, and examining the resulting values of
alow and
ahigh. The value of
should be chosen very carefully and the following points should be borne in mind:
-
(i) should be small but not too close to because of Gibbs' phenomenon (see Section 7),
-
(ii)the larger the value of , the smaller the range of values of that will be used in the algorithm,
-
(iii) should ideally not be chosen such that or a very small value. For suitable problems might be chosen as, say, or depending on these factors. The routine calculates alow from the formula
Additional values of
are computed by adding
to the previous value. As
, it will be seen that large values of
tfac and
relerr will test for
close to
alphab. Small values of
tfac and
relerr will test for
large. If the result of both tests is
, with comparable values for the inverse, then this gives some credibility to the chosen value of
alphab. You should note that this test could be more computationally expensive than the calculation of the inverse itself. The example program (see
Section 10) illustrates how such a test may be performed.
10
Example
This example estimates the inverse Laplace transform of the function
. The true inverse of
is
. Two preliminary calls to the routine are made to verify that the chosen value of
alphab is suitable. For these tests the single value
is used. To test values of
close to
alphab, the values
and
are chosen. To test larger
, the values
and
are used. Because the values of the computed inverse are similar and
in each case, these tests show that there is unlikely to be a singularity of
in the region
.
10.1
Program Text
10.2
Program Data
10.3
Program Results