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Special functions

 
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(′spesh·əl ′fəŋk·shənz)

(mathematics) The various families of solution functions corresponding to cases of the hypergeometric equation or functions used in the equation's study, such as the gamma function.

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Sci-Tech Encyclopedia: Special functions
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Functions which occur often enough to acquire a name. Some of these, such as the exponential, logarithmic, and the various trigonometric functions, are extensively taught in school and occur so frequently that routines for calculating them are built into many pocket calculators. See also Differentiation; Logarithm; Trigonometry.

The more complicated special functions, or higher transcendental functions as they are often called, have been extensively studied by many mathematicians because they arose in the problems which were being studied. Among the more useful functions are the following: the gamma function defined by Eq. (1), which generalizes the factorial; the related beta function defined by Eq. (2),
1. \Gamma (x) = \int^\infty_0 t^{x-1}e^{-t}dt

2. B(x,y) = \int^1_0 t^{x-1}(1-t)^{y-1}dt
which generalizes the binomial coefficient; and elliptic integrals, which arose when mathematicians tried to determine the arc length of an ellipse, and their inverses, the elliptic functions. The hypergeometric function and its generalizations includes many of the special functions which occur in mathematical physics, such as Bessel functions, Legendre functions, error functions, and the classical orthogonal polynomials of Jacobi, Laguerre, and Hermite. The zeta function defined by Eq. (3)
3. \zeta (s) = \sum^\infty_{n\,=\,1} n^{-s}
has many applications in number theory, and it also arises in M. Planck's work on radiation. See also Bessel functions; Elliptic function and integral; Gamma function; Heat radiation; Hypergeometric functions; Legendre functions; Number theory; Orthogonal polynomials.

Wikipedia: Special functions
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Special functions are particular mathematical functions which have more or less established names and notations due to their importance in mathematical analysis, functional analysis, physics, or other applications.

There is no general formal definition, but the list of mathematical functions contains functions which are commonly accepted as special. In particular, elementary functions are also considered as special functions.

Contents

Tables of special functions

Many special functions appear as solutions of differential equations or integrals of elementary functions. Therefore, tables of integrals [1] usually include descriptions of special functions, and tables of special functions [2] include most important integrals; at least, the integral representation of special functions.

Languages for analytical calculus such as Mathematica[3] usually recognize the majority of special functions. Not all such systems have efficient algorithms for the evaluation, especially in the complex plane.

Notations used in special functions

In most cases, the standard notation is used for indication of a special function: the name of function (printed with Roman font), subscripts, if any, open parenthesis, then arguments, separated with comma, and then close parenthesis. Such a notation allows easy translation of the expressions to algorithmic languages avoiding ambiguities. Functions with established international notations are sin, cos, exp, erf, erfc.

Sometimes, a special function has several names. The natural logarithm can be called as Log, log or ln, depending on the context. For example, the tangent function may be denoted Tan, tan or tg (especially in Russian literature); arctangent may be called atan, arctg, or tan − 1. Bessel functions may be written ~J_n(x)~; usually, ~J_n(x)~, ~{\rm besselj}(n,x) ~, ~ {\rm BesselJ}[n,x]~ refer to the same function.

Subscripts are often used to indicate arguments, typically integers. In a few cases, the semicolon (;) or even backslash (\) is used as a separator. In this case, the translation to algorithmic languages admits ambiguity and may lead to confusion.

Superscripts may indicate not only exponentiation, but modification of a function. Examples include:

  • ~\cos^{3}(x)~ usually indicates ~\cos(x)^3~
  • ~\cos^{2}(x)~ is typically ~\cos(x)^2~, but almost never ~\cos(\cos(x))~
  • ~\cos^{-1}(x)~ usually means ~\arccos(x)~, and not ~\cos(x)^{-1}~; this one typically causes the most confusion, as it is inconsistent with the others.

Evaluation of special functions

Most special functions are considered as a function of a complex variable. They are analytic; the singularities and cuts are described; the differential and integral representations are known and the expansion to the Taylor or asymptotic series are available. In addition, sometimes there exist relations with other special functions; a complicated special function can be expressed in terms of simpler functions. Various representations can be used for the evaluation; the simplest way to evaluate a function is to expand it into a Taylor series. However, such representation may converge slowly if at all. In algorithmic languages, rational approximations are typically used, although they may behave badly in the case of complex argument(s).

History of special functions

Classical theory

While trigonometry can be codified, as was clear already to expert mathematicians of the eighteenth century (if not before), the search for a complete and unified theory of special functions has continued since the nineteenth century. The high point of special function theory in the period 1850-1900 was the theory of elliptic functions; treatises that were essentially complete, such as that of Tannery and Molk, could be written as handbooks to all the basic identities of the theory. They were based on techniques from complex analysis .

From that time onwards it would be assumed that analytic function theory, which had already unified the trigonometric and exponential functions, was a fundamental tool. The end of the century also saw a very detailed discussion of spherical harmonics.

Changing and fixed motivations

Of course the wish for a broad theory including as many as possible of the known special functions has its intellectual appeal, but it is worth noting other motivations. For a long time, the special functions were in the particular province of applied mathematics; applications to the physical sciences and engineering determined the relative importance of functions. In the days before the electronic computer, the ultimate compliment to a special function was the computation, by hand, of extended tables of its values. This was a capital-intensive process, intended to make the function available by look-up, as for the familiar logarithm tables. The aspects of the theory that then mattered might then be two:

In contrast, one might say, there are approaches typical of the interests of pure mathematics: asymptotic analysis, analytic continuation and monodromy in the complex plane, and the discovery of symmetry principles and other structure behind the façade of endless formulae in rows. There is not a real conflict between these approaches, in fact.

Twentieth century

The twentieth century saw several waves of interest in special function theory. The classic Whittaker and Watson textbook sought to unify the theory by using complex variables; the G. N. Watson tome A Treatise on the Theory of Bessel Functions pushed the techniques as far as possible for one important type that particularly admitted asymptotics to be studied.

The later Bateman manuscript project, under the editorship of Arthur Erdélyi, attempted to be encyclopedic, and came around the time when electronic computation was coming to the fore and tabulation ceased to be the main issue.

Contemporary theories

The modern theory of orthogonal polynomials is of a definite but limited scope. Hypergeometric series became an intricate theory, in need of later conceptual arrangement. Lie groups, and in particular their representation theory, explain what a spherical function can be in general; from 1950 onwards substantial parts of classical theory could be recast in terms of Lie groups. Further, work on algebraic combinatorics also revived interest in older parts of the theory. Conjectures of Ian G. Macdonald helped to open up large and active new fields with the typical special function flavour. Difference equations have begun to take their place besides differential equations as a source for special functions.

Special functions in number theory

In number theory, certain special functions have traditionally been studied, such as particular Dirichlet series and modular forms. Almost all aspects of special function theory are reflected there, as well as some new ones, such as came out of the monstrous moonshine theory.

See also

References

  1. ^ Gradshtein, Israel Solomonovich; Iosif Moiseevich Ryzhik.. Table of integrals, sums, series and products. Academic press. 
  2. ^ Abramovitz, Milton; Irene Stegun. Table of mathematical functions. 
  3. ^ List of special functions in Mathematica

External links


This entry is from Wikipedia, the leading user-contributed encyclopedia. It may not have been reviewed by professional editors (see full disclaimer)

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