Laguerre polynomials: Difference between revisions
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Carl McBride (talk | contribs) (New page: Laguerre polynomials are solutions <math>L_n(x)</math> to the Laguerre differential equation with <math>\nu =0</math>. The Laguerre polynomial <math>H_n(z)</math> can be defined by the con...) |
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The first four Laguerre polynomials are: | The first four Laguerre polynomials are: | ||
<math>\left. L_0 (x) \right.=1</math> | :<math>\left. L_0 (x) \right.=1</math> | ||
<math>\left. L_1 (x) \right.=-x +1</math> | :<math>\left. L_1 (x) \right.=-x +1</math> | ||
<math>L_2 (x) =\frac{1}{2}(x^2 -4x +2)</math> | :<math>L_2 (x) =\frac{1}{2}(x^2 -4x +2)</math> | ||
<math>L_3 (x) =\frac{1}{6}(-x^3 +9x^2 -18x +6)</math> | :<math>L_3 (x) =\frac{1}{6}(-x^3 +9x^2 -18x +6)</math> | ||
===Generalized Laguerre function=== | ===Generalized Laguerre function=== | ||
<math>L_n^{\alpha}(x)= \frac{(\alpha + 1)_n}{n!} ~_1F_1(-n; \alpha + 1;x)</math> | :<math>L_n^{\alpha}(x)= \frac{(\alpha + 1)_n}{n!} ~_1F_1(-n; \alpha + 1;x)</math> | ||
where <math>(a)_n</math> is the Pochhammer symbol | where <math>(a)_n</math> is the Pochhammer symbol | ||
Latest revision as of 11:48, 31 May 2007
Laguerre polynomials are solutions to the Laguerre differential equation with . The Laguerre polynomial can be defined by the contour integral
The first four Laguerre polynomials are:
Generalized Laguerre function[edit]
where is the Pochhammer symbol and is a confluent hyper-geometric function.
