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NAG Toolbox

NAG Toolbox: nag_specfun_kelvin_ber (s19aa)

 Contents

    1  Purpose
    2  Syntax
    3  Description
    4  References
5  Parameters
    6  Error Indicators and Warnings
    7  Accuracy
    8  Further Comments
    9  Example

Purpose

nag_specfun_kelvin_ber (s19aa) returns a value for the Kelvin function berx via the function name.

Syntax

[result, ifail] = s19aa(x)
[result, ifail] = nag_specfun_kelvin_ber(x)

Description

nag_specfun_kelvin_ber (s19aa) evaluates an approximation to the Kelvin function berx.
Note:  ber-x=berx, so the approximation need only consider x0.0.
The function is based on several Chebyshev expansions:
For 0x5,
berx=r=0arTrt,   with ​ t=2 x5 4-1.  
For x>5,
berx= ex/22πx 1+ 1xat cosα+ 1xbtsinα + e-x/22πx 1+ 1xct sinβ+ 1xdtcosβ ,  
where α= x2- π8 , β= x2+ π8 ,
and at, bt, ct, and dt are expansions in the variable t= 10x-1.
When x is sufficiently close to zero, the result is set directly to ber0=1.0.
For large x, there is a danger of the result being totally inaccurate, as the error amplification factor grows in an essentially exponential manner; therefore the function must fail.

References

Abramowitz M and Stegun I A (1972) Handbook of Mathematical Functions (3rd Edition) Dover Publications

Parameters

Compulsory Input Parameters

1:     x – double scalar
The argument x of the function.

Optional Input Parameters

None.

Output Parameters

1:     result – double scalar
The result of the function.
2:     ifail int64int32nag_int scalar
ifail=0 unless the function detects an error (see Error Indicators and Warnings).

Error Indicators and Warnings

Errors or warnings detected by the function:
   ifail=1
On entry, absx is too large for an accurate result to be returned. On soft failure, the function returns zero.
   ifail=-99
An unexpected error has been triggered by this routine. Please contact NAG.
   ifail=-399
Your licence key may have expired or may not have been installed correctly.
   ifail=-999
Dynamic memory allocation failed.

Accuracy

Since the function is oscillatory, the absolute error rather than the relative error is important. Let E be the absolute error in the result and δ be the relative error in the argument. If δ is somewhat larger than the machine precision, then we have:
E x2 ber1x+ bei1x δ  
(provided E is within machine bounds).
For small x the error amplification is insignificant and thus the absolute error is effectively bounded by the machine precision.
For medium and large x, the error behaviour is oscillatory and its amplitude grows like x2π ex/2. Therefore it is not possible to calculate the function with any accuracy when xex/2> 2πδ . Note that this value of x is much smaller than the minimum value of x for which the function overflows.

Further Comments

None.

Example

This example reads values of the argument x from a file, evaluates the function at each value of x and prints the results.

Open in the MATLAB editor: s19aa_example

function s19aa_example


fprintf('s19aa example results\n\n');

x = [0.1   1    2.5   5   10   15   -1];
n = size(x,2);
result = x;

for j=1:n
  [result(j), ifail] = s19aa(x(j));
end

disp('      x          ber(x)');
fprintf('%12.3e%12.3e\n',[x; result]);



s19aa example results

      x          ber(x)
   1.000e-01   1.000e+00
   1.000e+00   9.844e-01
   2.500e+00   4.000e-01
   5.000e+00  -6.230e+00
   1.000e+01   1.388e+02
   1.500e+01  -2.967e+03
  -1.000e+00   9.844e-01
PDF version (NAG web site, 64-bit version, 64-bit version)
Chapter Contents
Chapter Introduction
NAG Toolbox
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