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NAG Toolbox

NAG Toolbox: nag_specfun_bessel_y1_real_vector (s17ar)

 Contents

    1  Purpose
    2  Syntax
    7  Accuracy
    9  Example

Purpose

nag_specfun_bessel_y1_real_vector (s17ar) returns an array of values of the Bessel function Y1x.

Syntax

[f, ivalid, ifail] = s17ar(x, 'n', n)
[f, ivalid, ifail] = nag_specfun_bessel_y1_real_vector(x, 'n', n)

Description

nag_specfun_bessel_y1_real_vector (s17ar) evaluates an approximation to the Bessel function of the second kind Y1xi for an array of arguments xi, for i=1,2,,n.
Note:  Y1x is undefined for x0 and the function will fail for such arguments.
The function is based on four Chebyshev expansions:
For 0<x8,
Y1 x = 2π lnx x8 r=0 ar Tr t - 2πx + x8 r=0 br Tr t ,   with ​ t = 2 x8 2 - 1 .  
For x>8,
Y1 x = 2πx P1 x sin x - 3 π4 + Q1 x cos x - 3 π4  
where P1 x = r=0 cr Tr t ,
and Q1 x = 8x r=0 dr Tr t , with t = 2 8x 2 - 1 .
For x near zero, Y1 x - 2 πx . This approximation is used when x is sufficiently small for the result to be correct to machine precision. For extremely small x, there is a danger of overflow in calculating - 2 πx  and for such arguments the function will fail.
For very large x, it becomes impossible to provide results with any reasonable accuracy (see Accuracy), hence the function fails. Such arguments contain insufficient information to determine the phase of oscillation of Y1x; only the amplitude, 2πx , can be determined and this is returned on soft failure. The range for which this occurs is roughly related to machine precision; the function will fail if x1/machine precision.

References

Abramowitz M and Stegun I A (1972) Handbook of Mathematical Functions (3rd Edition) Dover Publications
Clenshaw C W (1962) Chebyshev Series for Mathematical Functions Mathematical tables HMSO

Parameters

Compulsory Input Parameters

1:     xn – double array
The argument xi of the function, for i=1,2,,n.
Constraint: xi>0.0, for i=1,2,,n.

Optional Input Parameters

1:     n int64int32nag_int scalar
Default: the dimension of the array x.
n, the number of points.
Constraint: n0.

Output Parameters

1:     fn – double array
Y1xi, the function values.
2:     ivalidn int64int32nag_int array
ivalidi contains the error code for xi, for i=1,2,,n.
ivalidi=0
No error.
ivalidi=1
On entry,xi is too large. fi contains the amplitude of the Y1 oscillation, 2πxi .
ivalidi=2
On entry,xi0.0, Y1 is undefined. fi contains 0.0.
ivalidi=3
xi is too close to zero, there is a danger of overflow. On soft failure, fi contains the value of Y1x at the smallest valid argument.
3:     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:

Cases prefixed with W are classified as warnings and do not generate an error of type NAG:error_n. See nag_issue_warnings.

W  ifail=1
On entry, at least one value of x was invalid.
Check ivalid for more information.
   ifail=2
Constraint: n0.
   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

Let δ be the relative error in the argument and E be the absolute error in the result. (Since Y1x oscillates about zero, absolute error and not relative error is significant, except for very small x.)
If δ is somewhat larger than the machine precision (e.g., if δ is due to data errors etc.), then E and δ are approximately related by:
E x Y0 x - Y1 x δ  
(provided E is also within machine bounds). Figure 1 displays the behaviour of the amplification factor xY0x-Y1x.
However, if δ is of the same order as machine precision, then rounding errors could make E slightly larger than the above relation predicts.
For very small x, absolute error becomes large, but the relative error in the result is of the same order as δ.
For very large x, the above relation ceases to apply. In this region, Y1 x 2 πx sin x - 3π 4 . The amplitude 2 πx  can be calculated with reasonable accuracy for all x, but sinx- 3π4  cannot. If x- 3π4  is written as 2Nπ+θ where N is an integer and 0θ<2π, then sinx- 3π4 is determined by θ only. If x>δ-1, θ cannot be determined with any accuracy at all. Thus if x is greater than, or of the order of, the inverse of the machine precision, it is impossible to calculate the phase of Y1x and the function must fail.
Figure 1
Figure 1

Further Comments

None.

Example

This example reads values of x from a file, evaluates the function at each value of xi and prints the results.
function s17ar_example


fprintf('s17ar example results\n\n');

x = [0.5; 1; 3; 6; 8; 10; 1000];

[f, ivalid, ifail] = s17ar(x);

fprintf('     x          Y_1(x)   ivalid\n');
for i=1:numel(x)
  fprintf('%12.3e%12.3e%5d\n', x(i), f(i), ivalid(i));
end


s17ar example results

     x          Y_1(x)   ivalid
   5.000e-01  -1.471e+00    0
   1.000e+00  -7.812e-01    0
   3.000e+00   3.247e-01    0
   6.000e+00  -1.750e-01    0
   8.000e+00  -1.581e-01    0
   1.000e+01   2.490e-01    0
   1.000e+03  -2.478e-02    0

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