Orthogonal functions

In mathematics, orthogonal functions belong to a function space that is a vector space equipped with a bilinear form. When the function space has an interval as the domain, the bilinear form may be the integral of the product of functions over the interval:

\langle f,g\rangle =\int {\overline {f(x)}}g(x)\,dx.

The functions $f$ and $g$ are orthogonal when this integral is zero, i.e. $\langle f,\,g\rangle =0$ whenever $f\neq g$ . As with a basis of vectors in a finite-dimensional space, orthogonal functions can form an infinite basis for a function space. Conceptually, the above integral is the equivalent of a vector dot product; two vectors are mutually independent (orthogonal) if their dot-product is zero.

Suppose $\{f_{0},f_{1},\ldots \}$ is a sequence of orthogonal functions of nonzero L²-norms ${\textstyle \left\|f_{n}\right\|_{2}={\sqrt {\langle f_{n},f_{n}\rangle }}=\left(\int f_{n}^{2}\ dx\right)^{\frac {1}{2}}}$ . It follows that the sequence $\left\{f_{n}/\left\|f_{n}\right\|_{2}\right\}$ is of functions of L²-norm one, forming an orthonormal sequence. To have a defined L²-norm, the integral must be bounded, which restricts the functions to being square-integrable.

Trigonometric functions[edit]

Several sets of orthogonal functions have become standard bases for approximating functions. For example, the sine functions sin nx and sin mx are orthogonal on the interval $x\in (-\pi ,\pi )$ when $m\neq n$ and n and m are positive integers. For then

2\sin \left(mx\right)\sin \left(nx\right)=\cos \left(\left(m-n\right)x\right)-\cos \left(\left(m+n\right)x\right),

and the integral of the product of the two sine functions vanishes.^[1] Together with cosine functions, these orthogonal functions may be assembled into a trigonometric polynomial to approximate a given function on the interval with its Fourier series.

Polynomials[edit]

If one begins with the monomial sequence $\left\{1,x,x^{2},\dots \right\}$ on the interval $[-1,1]$ and applies the Gram–Schmidt process, then one obtains the Legendre polynomials. Another collection of orthogonal polynomials are the associated Legendre polynomials.

The study of orthogonal polynomials involves weight functions $w(x)$ that are inserted in the bilinear form:

\langle f,g\rangle =\int w(x)f(x)g(x)\,dx.

For Laguerre polynomials on $(0,\infty )$ the weight function is $w(x)=e^{-x}$ .

Both physicists and probability theorists use Hermite polynomials on $(-\infty ,\infty )$ , where the weight function is $w(x)=e^{-x^{2}}$ or $w(x)=e^{-x^{2}/2}$ .

Chebyshev polynomials are defined on $[-1,1]$ and use weights ${\textstyle w(x)={\frac {1}{\sqrt {1-x^{2}}}}}$ or ${\textstyle w(x)={\sqrt {1-x^{2}}}}$ .

Zernike polynomials are defined on the unit disk and have orthogonality of both radial and angular parts.

Binary-valued functions[edit]

Walsh functions and Haar wavelets are examples of orthogonal functions with discrete ranges.

Rational functions[edit]

Plot of the Chebyshev rational functions of order n=0,1,2,3 and 4 between x=0.01 and 100.

Legendre and Chebyshev polynomials provide orthogonal families for the interval [−1, 1] while occasionally orthogonal families are required on [0, ∞). In this case it is convenient to apply the Cayley transform first, to bring the argument into [−1, 1]. This procedure results in families of rational orthogonal functions called Legendre rational functions and Chebyshev rational functions.

In differential equations[edit]

Solutions of linear differential equations with boundary conditions can often be written as a weighted sum of orthogonal solution functions (a.k.a. eigenfunctions), leading to generalized Fourier series.

References[edit]

^ Antoni Zygmund (1935) Trigonometrical Series, page 6, Mathematical Seminar, University of Warsaw

George B. Arfken & Hans J. Weber (2005) Mathematical Methods for Physicists, 6th edition, chapter 10: Sturm-Liouville Theory — Orthogonal Functions, Academic Press.
Price, Justin J. (1975). "Topics in orthogonal functions". American Mathematical Monthly. 82: 594–609. doi:10.2307/2319690.
Giovanni Sansone (translated by Ainsley H. Diamond) (1959) Orthogonal Functions, Interscience Publishers.

External links[edit]

Orthogonal Functions, on MathWorld.

[1] Antoni Zygmund (1935) Trigonometrical Series, page 6, Mathematical Seminar, University of Warsaw

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