NAG FL Interface
d01aqf (dim1_fin_wcauchy)
1
Purpose
d01aqf calculates an approximation to the Hilbert transform of a function
over
:
for user-specified values of
,
and
.
2
Specification
Fortran Interface
Subroutine d01aqf ( |
g, a, b, c, epsabs, epsrel, result, abserr, w, lw, iw, liw, ifail) |
Integer, Intent (In) |
:: |
lw, liw |
Integer, Intent (Inout) |
:: |
ifail |
Integer, Intent (Out) |
:: |
iw(liw) |
Real (Kind=nag_wp), External |
:: |
g |
Real (Kind=nag_wp), Intent (In) |
:: |
a, b, c, epsabs, epsrel |
Real (Kind=nag_wp), Intent (Out) |
:: |
result, abserr, w(lw) |
|
C Header Interface
#include <nag.h>
void |
d01aqf_ ( double (NAG_CALL *g)(const double *x), const double *a, const double *b, const double *c, const double *epsabs, const double *epsrel, double *result, double *abserr, double w[], const Integer *lw, Integer iw[], const Integer *liw, Integer *ifail) |
|
C++ Header Interface
#include <nag.h> extern "C" {
void |
d01aqf_ ( double (NAG_CALL *g)(const double &x), const double &a, const double &b, const double &c, const double &epsabs, const double &epsrel, double &result, double &abserr, double w[], const Integer &lw, Integer iw[], const Integer &liw, Integer &ifail) |
}
|
The routine may be called by the names d01aqf or nagf_quad_dim1_fin_wcauchy.
3
Description
d01aqf is based on the QUADPACK routine QAWC (see
Piessens et al. (1983)) and integrates a function of the form
, where the weight function
is that of the Hilbert transform. (If
the integral has to be interpreted in the sense of a Cauchy principal value.) It is an adaptive routine which employs a ‘global’ acceptance criterion (as defined by
Malcolm and Simpson (1976)). Special care is taken to ensure that
is never the end point of a sub-interval (see
Piessens et al. (1976)). On each sub-interval
modified Clenshaw–Curtis integration of orders
and
is performed if
where
. Otherwise the Gauss
-point and Kronrod
-point rules are used. The local error estimation is described by
Piessens et al. (1983).
4
References
Malcolm M A and Simpson R B (1976) Local versus global strategies for adaptive quadrature ACM Trans. Math. Software 1 129–146
Piessens R, de Doncker–Kapenga E, Überhuber C and Kahaner D (1983) QUADPACK, A Subroutine Package for Automatic Integration Springer–Verlag
Piessens R, van Roy–Branders M and Mertens I (1976) The automatic evaluation of Cauchy principal value integrals Angew. Inf. 18 31–35
5
Arguments
-
1:
– real (Kind=nag_wp) Function, supplied by the user.
External Procedure
-
g must return the value of the function
at a given point
x.
The specification of
g is:
Fortran Interface
Real (Kind=nag_wp) |
:: |
g |
Real (Kind=nag_wp), Intent (In) |
:: |
x |
|
C Header Interface
double |
g_ (const double *x) |
|
C++ Header Interface
#include <nag.h> extern "C" {
double |
g_ (const double &x) |
}
|
-
1:
– Real (Kind=nag_wp)
Input
-
On entry: the point at which the function must be evaluated.
g must either be a module subprogram USEd by, or declared as EXTERNAL in, the (sub)program from which
d01aqf is called. Arguments denoted as
Input must
not be changed by this procedure.
Note: g should not return floating-point NaN (Not a Number) or infinity values, since these are not handled by
d01aqf. If your code inadvertently
does return any NaNs or infinities,
d01aqf is likely to produce unexpected results.
-
2:
– Real (Kind=nag_wp)
Input
-
On entry: , the lower limit of integration.
-
3:
– Real (Kind=nag_wp)
Input
-
On entry: , the upper limit of integration. It is not necessary that .
-
4:
– Real (Kind=nag_wp)
Input
-
On entry: the argument in the weight function.
Constraint:
must not equal
a or
b.
-
5:
– Real (Kind=nag_wp)
Input
-
On entry: the absolute accuracy required. If
epsabs is negative, the absolute value is used. See
Section 7.
-
6:
– Real (Kind=nag_wp)
Input
-
On entry: the relative accuracy required. If
epsrel is negative, the absolute value is used. See
Section 7.
-
7:
– Real (Kind=nag_wp)
Output
-
On exit: the approximation to the integral .
-
8:
– Real (Kind=nag_wp)
Output
-
On exit: an estimate of the modulus of the absolute error, which should be an upper bound for .
-
9:
– Real (Kind=nag_wp) array
Output
-
On exit: details of the computation see
Section 9 for more information.
-
10:
– Integer
Input
-
On entry: the dimension of the array
w as declared in the (sub)program from which
d01aqf is called. The value of
lw (together with that of
liw) imposes a bound on the number of sub-intervals into which the interval of integration may be divided by the routine. The number of sub-intervals cannot exceed
. The more difficult the integrand, the larger
lw should be.
Suggested value:
to is adequate for most problems.
Constraint:
.
-
11:
– Integer array
Output
-
On exit: contains the actual number of sub-intervals used. The rest of the array is used as workspace.
-
12:
– Integer
Input
-
On entry: the dimension of the array
iw as declared in the (sub)program from which
d01aqf is called. The number of sub-intervals into which the interval of integration may be divided cannot exceed
liw.
Suggested value:
.
Constraint:
.
-
13:
– 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 d01aqf may return useful information.
-
The maximum number of subdivisions allowed with the given workspace has been reached without the accuracy requirements being achieved. Look at the integrand in order to determine the integration difficulties. If necessary, another integrator, which is designed for handling the type of difficulty involved, must be used. Alternatively, consider relaxing the accuracy requirements specified by
epsabs and
epsrel, or increasing the amount of workspace.
-
Round-off error prevents the requested tolerance from being achieved: and .
-
Extremely bad integrand behaviour occurs around the sub-interval . The same advice applies as in the case of .
-
On entry, , and .
Constraint: and .
-
On entry, .
Constraint: .
On entry, .
Constraint: .
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
d01aqf cannot guarantee, but in practice usually achieves, the following accuracy:
where
and
epsabs and
epsrel are user-specified absolute and relative error tolerances. Moreover, it returns the quantity
abserr which, in normal circumstances satisfies:
8
Parallelism and Performance
d01aqf is not threaded in any implementation.
The time taken by d01aqf depends on the integrand and the accuracy required.
If
on exit, then you may wish to examine the contents of the array
w, which contains the end points of the sub-intervals used by
d01aqf along with the integral contributions and error estimates over these sub-intervals.
Specifically, for
, let
denote the approximation to the value of the integral over the sub-interval [
] in the partition of
and
be the corresponding absolute error estimate. Then,
and
. The value of
is returned in
,
and the values
,
,
and
are stored consecutively in the
array
w,
that is:
- ,
- ,
- and
- .
10
Example
This example computes the Cauchy principal value of
10.1
Program Text
10.2
Program Data
None.
10.3
Program Results