Continuous phase modulation: Difference between revisions

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m per WP:HYPHEN, sub-subsection 3, points 3,4,5, replaced: commonly- → commonly , nearly- → nearly , finitely- → finitely (2) using AWB
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In [[numerical analysis]], the '''Clenshaw algorithm'''<ref name="Clenshaw55">{{Cite doi|10.1090/S0025-5718-1955-0071856-0}}  Note that this paper is written in terms of the ''Shifted'' Chebyshev polynomials of the first kind <math>T^*_n(x) = T_n(2x-1)</math>.</ref> is a [[Recursion|recursive]] method to evaluate a linear combination of [[Chebyshev polynomials]]. It is a generalization of [[Horner's method]] for evaluating a linear combination of [[monomial]]s.
Oscar is what my wife loves to contact me and I completely dig that name. Doing ceramics is what my family and I enjoy. Years ago we moved to North Dakota. For years he's been operating as a meter reader and it's some thing he really enjoy.<br><br>my site [https://Tomjones1190.wordpress.com/ https://Tomjones1190.wordpress.com/]
 
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]].<ref>{{Citation |last1=Press |first1=WH |last2=Teukolsky |first2=SA |last3=Vetterling |first3=WT |last4=Flannery |first4=BP |year=2007 |title=Numerical Recipes: The Art of Scientific Computing |edition=3rd |publisher=Cambridge University Press |publication-place=New York |isbn=978-0-521-88068-8 |chapter=Section 5.4.2. Clenshaw's Recurrence Formula |chapter-url=http://apps.nrbook.com/empanel/index.html?pg=222}}</ref>
 
==Clenshaw algorithm==
 
Suppose that <math>\phi_k,\; k=0, 1, \ldots</math> is a sequence of functions that satisfy the linear recurrence relation
 
:<math>\phi_{k+1}(x) = \alpha_k(x)\,\phi_k(x) + \beta_k(x)\,\phi_{k-1}(x),</math>
 
where the coefficients <math>\alpha_k</math> and <math>\beta_k</math> are known in advance.  Note that in the most common applications, <math>\alpha(x)</math> does not depend on <math>k</math>, and <math>\beta</math> is a constant that depends on neither <math>x</math> nor <math>k</math>.
 
Our goal is to evaluate a weighted sum of these functions
:<math>S(x) = \sum_{k=0}^n a_k \phi_k(x)</math>
 
Given the coefficients <math>a_0, \ldots, a_n</math>, compute the values <math>b_k(x)</math> by the "reverse" recurrence formula:
 
:<math>\begin{align}
  b_{n+1}(x) &= b_{n+2}(x) = 0, \\[.5em]
  b_{k}(x) &= a_k + \alpha_k(x)\,b_{k+1}(x) + \beta_{k+1}(x)\,b_{k+2}(x).
\end{align}</math>
 
The linear combination of the <math>\phi_k</math> satisfies:
 
:<math>S(x) = \phi_0(x)a_0 + \phi_1(x)b_1(x) + \beta_1(x)\phi_0(x)b_2(x).</math>
 
See Fox and Parker<ref name="FoxParker">{{Citation |author1=L. Fox |author2=I. B. Parker |title=Chebyshev Polynomials in Numerical Analysis |publisher=Oxford University Press |year=1968 |isbn=0-19-859614-6}}</ref> for more information and stability analyses.
 
===Horner as a special case of Clenshaw===
A particularly simple case occurs when evaluating a polynomial of the form
:<math>S(x) = \sum_{k=0}^n a_k x^k</math>.
The functions are simply
:<math>\begin{align}
  \phi_0(x) &= 1, \\
  \phi_k(x) &= x^k = x\phi_{k-1}(x)
\end{align}</math>
and are produced by the recurrence coefficients <math>\alpha(x) = x</math> and <math>\beta = 0</math>.
 
In this case, the recurrence formula to compute the sum is
:<math>b_k(x) = a_k + x b_{k+1}(x)</math>
and, in this case, the sum is simply
:<math>S(x) = a_0 + x b_1(x) = b_0(x)</math>,
which is exactly the usual [[Horner's method]].
 
===Special case for Chebyshev series===
Consider a truncated [[Chebyshev series]]
 
:<math>p_n(x) = a_0 + a_1T_1(x) + a_2T_2(x) + \cdots + a_nT_n(x).</math>
 
The coefficients in the recursion relation for the [[Chebyshev polynomials]] are
 
:<math>\alpha(x) = 2x, \quad \beta = -1,</math>
with the initial conditions
:<math>T_0(x) = 1, \quad T_1(x) = x.</math>
 
Thus, the recurrence is
:<math>b_k(x) = a_k + 2xb_{k+1}(x) - b_{k+2}(x)</math>
and the final sum is
:<math>p_n(x) = a_0 + xb_1(x) - b_2(x).</math>
 
One way to evaluate this is to continue the recurrence one more step, and compute
:<math>b_0(x) = 2a_0 + 2xb_1(x) - b_2(x),</math>
(note the doubled ''a''<sub>0</sub> coefficient) followed by
:<math>p_n(x) = b_0(x)-x b_1(x)-a_0=\frac{1}{2}\left[b_0(x) - b_2(x)\right].</math>
 
===Geodetic applications===
 
Clenshaw's algorithm is extensively used in geodetic applications
where it is usually referred to as '''Clenshaw summation'''.<ref>
{{Citation
| last1=Tscherning
| first1=C. C.
| last2=Poder
| first2=K.
| year=1982
| title=Some Geodetic applications of Clenshaw Summation
| journal=Bolletino di Geodesia e Scienze Affini
| volume=41
| number=4
| pages=349–375
| url=http://cct.gfy.ku.dk/publ_cct/cct80.pdf
}}</ref> A simple application is summing the trigonometric series to compute
the [[meridian arc]].  These have the form
 
:<math>m(\theta) = C_0\,\theta + C_1\sin \theta + C_2\sin 2\theta + \cdots + C_n\sin n\theta.</math>
 
Leaving off the initial <math>C_0\,\theta</math> term, the remainder is a summation of the appropriate form. There is no leading term because <math>\phi_0(\theta) = \sin 0\theta = \sin 0 = 0</math>.
 
The [[List of trigonometric identities#Chebyshev method|recurrence relation for <math>\sin k\theta</math>]] is
:<math>\sin k\theta = 2 \cos\theta \sin (k-1)\theta - \sin (k-2)\theta</math>,
 
making the coefficients in the recursion relation
 
:<math>\alpha_k(\theta) = 2\cos\theta, \quad \beta_k = -1.</math>
 
and the evaluation of the series is given by
 
:<math>\begin{align}
  b_{n+1}(\theta) &= b_{n+2}(\theta) = 0,\\[.3em]
  b_k(\theta) &= C_k + 2 b_{k+1}(\theta)\cos \theta - b_{k+2}(\theta)\quad(n\ge k \ge 1).
\end{align}</math>
 
The final step is made particularly simple because <math>\phi_0(\theta) = \sin 0 = 0</math>, so the end of the recurrence is simply <math>b_1(\theta)\sin(\theta)</math>; the <math>C_0\,\theta</math> term is added separately:
 
:<math>m(\theta) = C_0\,\theta + b_1(\theta)\sin \theta.</math>
 
Note that the algorithm requires only the evaluation of two trigonometric quantities <math>\cos \theta</math> and <math>\sin \theta</math>.
 
==See also==
*[[Horner scheme]] to evaluate polynomials in [[monomial form]]
*[[De Casteljau's algorithm]] to evaluate polynomials in [[Bézier form]]
 
==References==
<references/>
 
{{DEFAULTSORT:Clenshaw Algorithm}}
[[Category:Numerical analysis]]

Latest revision as of 14:21, 6 March 2014

Oscar is what my wife loves to contact me and I completely dig that name. Doing ceramics is what my family and I enjoy. Years ago we moved to North Dakota. For years he's been operating as a meter reader and it's some thing he really enjoy.

my site https://Tomjones1190.wordpress.com/