Hermite polynomial: Difference between revisions
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\frac{d^2 H_n}{dx^2}-2x\,\frac{dH_n}{dx}+ 2n H_n=0. | \frac{d^2 H_n}{dx^2}-2x\,\frac{dH_n}{dx}+ 2n H_n=0. | ||
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==Symmetry== | |||
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H_n(-x) = (-1)^n H_n(x)\;, | |||
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the functions of even ''n'' are symmetric under ''x'' → −''x'' and those of odd ''n'' are antisymmetric under this substitution. | |||
==References== | ==References== | ||
[http://www.math.sfu.ca/~cbm/aands/ | M. Abramowitz and I.A. Stegun (Eds), ''Handbook of Mathematical Functions", Dover, New York (1972). Chapter 22 | ||
[http://www.math.sfu.ca/~cbm/aands/ Abramowitz and Stegun online] |
Revision as of 05:03, 30 January 2009
Template:TOC-right In mathematics and physics, Hermite polynomials form a well-known class of orthogonal polynomials. In quantum mechanics they appear as eigenfunctions of the harmonic oscillator and in numerical analysis they play a role in Gauss-Hermite quadrature. The functions are named after the French mathematician Charles Hermite (1822–1901).
- See Catalogs for a table of Hermite polynomials through n = 12.
Orthonormality
The Hermite polynomials Hn(x) are orthogonal in the sense of the following inner product:
That is, the polynomials are defined on the full real axis and have weight w(x) = exp(−x²). Their orthogonality is expressed by the appearance of the Kronecker delta δn'n. The normalization constant is given by
Normalization is to unity
The polynomials NnHn(x) are orthonormal, which means that they are orthogonal and normalized to unity.
Explicit expression
here if N even and if N odd.
Recursion relation
Orthogonal polynomials can be constructed recursively by means of a Gram-Schmidt orthogonalization pocedure. This procedure yields the following relation
The first few follow immediately from this relation,
Differential equation
The polynomials satisfy the Hermite differential equation for the special case that the coefficient of Hn(x) is equal to the even integer 2n,
Symmetry
the functions of even n are symmetric under x → −x and those of odd n are antisymmetric under this substitution.
References
M. Abramowitz and I.A. Stegun (Eds), Handbook of Mathematical Functions", Dover, New York (1972). Chapter 22