"Convolution power"@en . . . . . . "In mathematics, the convolution power is the n-fold iteration of the convolution with itself. Thus if is a function on Euclidean space Rd and is a natural number, then the convolution power is defined by where \u2217 denotes the convolution operation of functions on Rd and \u03B40 is the Dirac delta distribution. This definition makes sense if x is an integrable function (in L1), a rapidly decreasing distribution (in particular, a compactly supported distribution) or is a finite Borel measure."@en . . . . . . . . "In mathematics, the convolution power is the n-fold iteration of the convolution with itself. Thus if is a function on Euclidean space Rd and is a natural number, then the convolution power is defined by where \u2217 denotes the convolution operation of functions on Rd and \u03B40 is the Dirac delta distribution. This definition makes sense if x is an integrable function (in L1), a rapidly decreasing distribution (in particular, a compactly supported distribution) or is a finite Borel measure. If x is the distribution function of a random variable on the real line, then the nth convolution power of x gives the distribution function of the sum of n independent random variables with identical distribution x. The central limit theorem states that if x is in L1 and L2 with mean zero and variance \u03C32, then where \u03A6 is the cumulative standard normal distribution on the real line. Equivalently, tends weakly to the standard normal distribution. In some cases, it is possible to define powers x*t for arbitrary real t > 0. If \u03BC is a probability measure, then \u03BC is infinitely divisible provided there exists, for each positive integer n, a probability measure \u03BC1/n such that That is, a measure is infinitely divisible if it is possible to define all nth roots. Not every probability measure is infinitely divisible, and a characterization of infinitely divisible measures is of central importance in the abstract theory of stochastic processes. Intuitively, a measure should be infinitely divisible provided it has a well-defined \"convolution logarithm.\" The natural candidate for measures having such a logarithm are those of (generalized) Poisson type, given in the form In fact, the states that a necessary and sufficient condition for a measure to be infinitely divisible is that it must lie in the closure, with respect to the vague topology, of the class of Poisson measures . Many applications of the convolution power rely on being able to define the analog of analytic functions as formal power series with powers replaced instead by the convolution power. Thus if is an analytic function, then one would like to be able to define If x \u2208 L1(Rd) or more generally is a finite Borel measure on Rd, then the latter series converges absolutely in norm provided that the norm of x is less than the radius of convergence of the original series defining F(z). In particular, it is possible for such measures to define the convolutional exponential It is not generally possible to extend this definition to arbitrary distributions, although a class of distributions on which this series still converges in an appropriate weak sense is identified by ."@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "12101596"^^ . "1123904445"^^ . . . . . . . "7649"^^ . .