In numerical analysis, the Clenshaw algorithm, also called Clenshaw summation, is a recursive method to evaluate a linear combination of Chebyshev polynomials.[1][2] The method was published by Charles William Clenshaw in 1955. It is a generalization of Horner's method for evaluating a linear combination of monomials.

It generalizes to more than just Chebyshev polynomials; it applies to any class of functions that can be defined by a three-term recurrence relation.[3]

Clenshaw algorithm

edit

In full generality, the Clenshaw algorithm computes the weighted sum of a finite series of functions  :   where   is a sequence of functions that satisfy the linear recurrence relation   where the coefficients   and   are known in advance.

The algorithm is most useful when   are functions that are complicated to compute directly, but   and   are particularly simple. In the most common applications,   does not depend on  , and   is a constant that depends on neither   nor  .

To perform the summation for given series of coefficients  , compute the values   by the "reverse" recurrence formula:  

Note that this computation makes no direct reference to the functions  . After computing   and  , the desired sum can be expressed in terms of them and the simplest functions   and  :  

See Fox and Parker[4] for more information and stability analyses.

Examples

edit

Horner as a special case of Clenshaw

edit

A particularly simple case occurs when evaluating a polynomial of the form   The functions are simply   and are produced by the recurrence coefficients   and  .

In this case, the recurrence formula to compute the sum is   and, in this case, the sum is simply   which is exactly the usual Horner's method.

Special case for Chebyshev series

edit

Consider a truncated Chebyshev series  

The coefficients in the recursion relation for the Chebyshev polynomials are   with the initial conditions  

Thus, the recurrence is   and the final sum is  

One way to evaluate this is to continue the recurrence one more step, and compute   (note the doubled a0 coefficient) followed by  

Meridian arc length on the ellipsoid

edit

Clenshaw summation is extensively used in geodetic applications.[2] A simple application is summing the trigonometric series to compute the meridian arc distance on the surface of an ellipsoid. These have the form  

Leaving off the initial   term, the remainder is a summation of the appropriate form. There is no leading term because  .

The recurrence relation for   is   making the coefficients in the recursion relation   and the evaluation of the series is given by   The final step is made particularly simple because  , so the end of the recurrence is simply  ; the   term is added separately:  

Note that the algorithm requires only the evaluation of two trigonometric quantities   and  .

Difference in meridian arc lengths

edit

Sometimes it necessary to compute the difference of two meridian arcs in a way that maintains high relative accuracy. This is accomplished by using trigonometric identities to write   Clenshaw summation can be applied in this case[5] provided we simultaneously compute   and perform a matrix summation,   where   The first element of   is the average value of   and the second element is the average slope.   satisfies the recurrence relation   where   takes the place of   in the recurrence relation, and  . The standard Clenshaw algorithm can now be applied to yield   where   are 2×2 matrices. Finally we have   This technique can be used in the limit   and   to simultaneously compute   and the derivative  , provided that, in evaluating   and  , we take  .

See also

edit

References

edit
  1. ^ Clenshaw, C. W. (July 1955). "A note on the summation of Chebyshev series". Mathematical Tables and Other Aids to Computation. 9 (51): 118. doi:10.1090/S0025-5718-1955-0071856-0. ISSN 0025-5718. Note that this paper is written in terms of the Shifted Chebyshev polynomials of the first kind  .
  2. ^ a b Tscherning, C. C.; Poder, K. (1982), "Some Geodetic applications of Clenshaw Summation" (PDF), Bolletino di Geodesia e Scienze Affini, 41 (4): 349–375, archived from the original (PDF) on 2007-06-12, retrieved 2012-08-02
  3. ^ Press, WH; Teukolsky, SA; Vetterling, WT; Flannery, BP (2007), "Section 5.4.2. Clenshaw's Recurrence Formula", Numerical Recipes: The Art of Scientific Computing (3rd ed.), New York: Cambridge University Press, ISBN 978-0-521-88068-8
  4. ^ Fox, Leslie; Parker, Ian B. (1968), Chebyshev Polynomials in Numerical Analysis, Oxford University Press, ISBN 0-19-859614-6
  5. ^ Karney, C. F. F. (2024). "The area of rhumb polygons". Stud. Geophys. Geod. 68 (3–4): 99–120. doi:10.1007/s11200-024-0709-zAppendix B{{cite journal}}: CS1 maint: postscript (link)