Difference between revisions of "Gegenbauer C"

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The Gegenbauer polynomial $C_n^{\lambda}$ of degree $n \in \{0,1,2,\ldots\}$ and order $\lambda$ defined by
 
The Gegenbauer polynomial $C_n^{\lambda}$ of degree $n \in \{0,1,2,\ldots\}$ and order $\lambda$ defined by
$$C_n^{\lambda}(z)=\displaystyle\sum_{k=0}^{\lfloor \frac{n}{2} \rfloor} \dfrac{(-1)^k\Gamma(n-k+\lambda)}{\Gamma(\lambda)k!(n-2k)!} (2z)^{n-2k},$$
+
$$C_n^{\lambda}(x)=\displaystyle\sum_{k=0}^{\left\lfloor \frac{n}{2} \right\rfloor} \dfrac{(-1)^k\Gamma(n-k+\lambda)}{\Gamma(\lambda)k!(n-2k)!} (2x)^{n-2k},$$
where $\lfloor \frac{n}{2} \rfloor$ denotes the [[floor]] function, $\Gamma$ denotes [[gamma]], and $k!$ denotes the [[factorial]].
+
where $\left\lfloor \frac{n}{2} \right\rfloor$ denotes the [[floor]] function, $\Gamma$ denotes [[gamma]], and $k!$ denotes the [[factorial]].
  
 
=Properties=
 
=Properties=
 
[[Orthogonality of Gegenbauer C on (-1,1)]]<br />
 
[[Orthogonality of Gegenbauer C on (-1,1)]]<br />
 
[[(n+2)C_(n+2)^(lambda)(x)=2(lambda+n+1)xC_(n+1)^(lambda)(x)-(2lambda+n)C_n^(lambda)(x)]]<br />
 
[[(n+2)C_(n+2)^(lambda)(x)=2(lambda+n+1)xC_(n+1)^(lambda)(x)-(2lambda+n)C_n^(lambda)(x)]]<br />
 
+
[[nC_n^(lambda)(x)=2lambda(xC_(n-1)^(lambda+1)(x)-C_(n-2)^(lambda+1)(x))]]<br />
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[[(n+2lambda)C_n^(lambda)(x)=2lambda(C_n^(lambda+1)(x)-xC_(n-1)^(lambda+1)(x))]]<br />
<strong>Theorem:</strong> The following formula holds:
+
[[nC_n^(lambda)(x)=(n-1+2lambda)xC_(n-1)^(lambda)(x)-2lambda(1-x^2)C_(n-2)^(lambda-1)(x)]]<br />
$$nC_n^{\lambda}(x) = 2\lambda(xC_{n-1}^{\lambda+1}(x) - C_{n-2}^{\lambda+1}(x)).$$
+
[[C_n^(lambda)'(x)=2lambda C_(n+1)^(lambda+1)(x)]]<br />
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<strong>Proof:</strong> █
 
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<strong>Theorem:</strong> The following formula holds:
 
$$(n+2\lambda)C_n^{\lambda}(x) = 2\lambda(C_n^{\lambda+1}(x)-xC_{n-1}^{\lambda+1}(x))$$.
 
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<strong>Proof:</strong> █
 
</div>
 
</div>
 
 
 
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<strong>Theorem:</strong> The following formula holds:
 
$$nC_n^{\lambda}(x) = (n-1+2\lambda)xC_{n-1}^{\lambda}(x) - 2\lambda(1-x^2)C_{n-2}^{\lambda-1}(x).$$
 
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<strong>Proof:</strong> █
 
</div>
 
</div>
 
 
 
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<strong>Theorem:</strong> The following formula holds:
 
$$C_n^{\lambda '}(x) = 2\lambda C_{n+1}^{\lambda+1}(x).$$
 
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<strong>Proof:</strong> █
 
</div>
 
</div>
 
 
 
 
[[Relationship between the Gegenbauer C polynomials and the Jacobi P polynomials]]<br />
 
[[Relationship between the Gegenbauer C polynomials and the Jacobi P polynomials]]<br />
 
[[Relationship between Chebyshev T and Gegenbauer C]]<br />
 
[[Relationship between Chebyshev T and Gegenbauer C]]<br />

Latest revision as of 01:29, 20 December 2017

The Gegenbauer polynomial $C_n^{\lambda}$ of degree $n \in \{0,1,2,\ldots\}$ and order $\lambda$ defined by $$C_n^{\lambda}(x)=\displaystyle\sum_{k=0}^{\left\lfloor \frac{n}{2} \right\rfloor} \dfrac{(-1)^k\Gamma(n-k+\lambda)}{\Gamma(\lambda)k!(n-2k)!} (2x)^{n-2k},$$ where $\left\lfloor \frac{n}{2} \right\rfloor$ denotes the floor function, $\Gamma$ denotes gamma, and $k!$ denotes the factorial.

Properties

Orthogonality of Gegenbauer C on (-1,1)
(n+2)C_(n+2)^(lambda)(x)=2(lambda+n+1)xC_(n+1)^(lambda)(x)-(2lambda+n)C_n^(lambda)(x)
nC_n^(lambda)(x)=2lambda(xC_(n-1)^(lambda+1)(x)-C_(n-2)^(lambda+1)(x))
(n+2lambda)C_n^(lambda)(x)=2lambda(C_n^(lambda+1)(x)-xC_(n-1)^(lambda+1)(x))
nC_n^(lambda)(x)=(n-1+2lambda)xC_(n-1)^(lambda)(x)-2lambda(1-x^2)C_(n-2)^(lambda-1)(x)
C_n^(lambda)'(x)=2lambda C_(n+1)^(lambda+1)(x)
Relationship between the Gegenbauer C polynomials and the Jacobi P polynomials
Relationship between Chebyshev T and Gegenbauer C
Relationship between Chebyshev U and Gegenbauer C

Orthogonal polynomials