Introduction to the probability integrals and inverses
General
The probability integral (error function) has a long history beginning with the articles of A. de Moivre (1718–1733) and P.‐S. Laplace (1774) where it was expressed through the following integral:
Later C. Kramp (1799) used this integral for the definition of the complementary error function . P.‐S. Laplace (1812) derived an asymptotic expansion of the error function.
The probability integrals were so named because they are widely applied in the theory of probability, in both normal and limit distributions.
To obtain, say, a normal distributed random variable from a uniformly distributed random variable, the inverse of the error function, namely is needed. The inverse was systematically investigated in the second half of the twentieth century, especially by J. R. Philip (1960) and A. J. Strecok (1968).
Definitions of probability integrals and inverses
The probability integral (error function) , the generalized error function , the complementary error function , the imaginary error function , the inverse error function , the inverse of the generalized error function , and the inverse complementary error function are defined through the following formulas:
These seven functions are typically called probability integrals and their inverses.
Instead of using definite integrals, the three univariate error functions can be defined through the following infinite series.
A quick look at the probability integrals and inverses Here is a quick look at the graphics for the probability integrals and inverses along the real axis.
Connections within the group of probability integrals and inverses and with other function groups
Representations through more general functions
The probability integrals , , , and are the particular cases of two more general functions: hypergeometric and Meijer G functions.
For example, they can be represented through the confluent hypergeometric functions and :
Representations of the probability integrals , , , and through classical Meijer G functions are rather simple:
The factor in the last four formulas can be removed by changing the classical Meijer G functions to the generalized one:
The probability integrals , , , and are the particular cases of the incomplete gamma function, regularized incomplete gamma function, and exponential integral :
Representations through related equivalent functions
The probability integrals , , and can be represented through Fresnel integrals by the following formulas:
Representations through other probability integrals and inverses
The probability integrals and their inverses , , , , , , and are interconnected by the following formulas:
The best-known properties and formulas for probability integrals and inverses
Real values for real arguments
For real values of argument , the values of the probability integrals , , , and are real. For real arguments , the values of the inverse error function are real; for real arguments , the values of the inverse of the generalized error function are real; and for real arguments , the values of the inverse complementary error function are real.
Simple values at zero and one
The probability integrals , , , and , and their inverses , , and have simple values for zero or unit arguments:
Simple values at infinity
The probability integrals , , and have simple values at infinity:
Specific values for specialized arguments
In cases when or is equal to or , the generalized error function and its inverse can be expressed through the probability integrals , , or their inverses by the following formulas:
Analyticity
The probability integrals , , and , and their inverses , and are defined for all complex values of , and they are analytical functions of over the whole complex ‐plane. The probability integrals , , and are entire functions with an essential singular point at , and they do not have branch cuts or branch points.
The generalized error function is an analytical function of and , which is defined in . For fixed , it is an entire function of . For fixed , it is an entire function of . It does not have branch cuts or branch points.
The inverse of the generalized error function is an analytical function of and , which is defined in .
Poles and essential singularities
The probability integrals , , and have only one singular point at . It is an essential singular point.
The generalized error function has singular points at and . They are essential singular points.
Periodicity
The probability integrals , , , and , and their inverses , , and do not have periodicity.
Parity and symmetry
The probability integrals , , and are odd functions and have mirror symmetry:
The generalized error function has permutation symmetry:
The complementary error function has mirror symmetry:
Series representations
The probability integrals , , , and , and their inverses and have the following series expansions:
The series for functions , , , and converge for all complex values of their arguments.
Interestingly, closed-form expressions for the truncated version of the Taylor series at the origin can be expressed through generalized hypergeometric function , for example:
Asymptotic series expansions
The asymptotic behavior of the probability integrals , , and can be described by the following formulas (only the main terms of the asymptotic expansion are given):
The previous formulas are valid in any direction approaching infinity (z∞). In particular cases, these formulas can be simplified to the following relations:
Integral representations
The probability integrals , , , and can also be represented through the following equivalent integrals:
The symbol in the preceding integral means that the integral evaluates as the Cauchy principal value: .
Transformations
If the arguments of the probability integrals , , and contain square roots, the arguments can sometimes be simplified:
Representations of derivatives
The derivative of the probability integrals , , , and , and their inverses , , and have simple representations through elementary functions:
The symbolic -order derivatives from the probability integrals , , , and have the following simple representations through the regularized generalized hypergeometric function :
But the symbolic -order derivatives from the inverse probability integrals , , and have very complicated structures in which the regularized generalized hypergeometric function appears in the multidimensional sums, for example:
Differential equations
The probability integrals , , , and satisfy the following second-order linear differential equations:
where and are arbitrary constants.
The inverses of the probability integrals , , and satisfy the following ordinary second-order nonlinear differential equations:
Applications of probability integrals and inverses
Applications of probability integrals include solutions of linear partial differential equations, probability theory, Monte Carlo simulations, and the Ewald method for calculating electrostatic lattice constants.
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