Mean-periodic function: Difference between revisions

In mathematical analysis, the concept of a mean-periodic function is a generalization introduced in 1935 by Jean Delsarte^[1][2] of the concept of a periodic function. Further results were made by Laurent Schwartz and J-P Kahane.^[3][4]

Consider a continuous complex-valued function Template:Math of a real variable. The function Template:Math is periodic with period Template:Math precisely if for all real Template:Math, we have Template:Math. This can be written as

${\displaystyle \int f(x-t)d\mu (t)=0(1)}$

where ${\displaystyle \mu }$ is the difference between the Dirac measures at 0 and a. The function Template:Math is mean-periodic if it satisfies the same equation (1), but where ${\displaystyle \mu }$ is some arbitrary nonzero measure with compact (hence bounded) support.

Equation (1) can be interpreted as a convolution, so that a mean-periodic function is a function Template:Math for which there exists a compactly supported (signed) Borel measure ${\displaystyle \mu }$ for which ${\displaystyle f*\mu =0}$.^[4]

There are several well-known equivalent definitions.^[2]

Mean-periodic functions are a separate generalization of periodic functions from the almost periodic functions. For instance, exponential functions are mean-periodic since Template:Math, but they are not almost periodic as they are unbounded. Still, there is a theorem which states that any uniformly continuous bounded mean-periodic function is almost periodic (in the sense of Bohr). In the other direction, there exist almost periodic functions which are not mean-periodic.^[2]

If f is a mean periodic function, then it is the limit of a certain sequence of exponential polynomials which are finite linear combinations of term t^^n exp(at) where n is any non-negative integer and a is any complex number; also Df is a mean periodic function (ie mean periodic) and if h is an exponential polynomial, then the pointwise product of f and h is mean periodic).

If f and g are mean periodic then f + g and the truncated convolution product of f and g is mean periodic. However, the pointwise product of f and g need not be mean periodic.

If L(D) is a linear differential operator with constant co-efficients, and L(D)f = g, then f is mean periodic if and only if g is mean periodic.

For linear differential difference equations such as Df(t) - af(t - b) = g where a is any complex number and b is a positive real number, then f is mean periodic if and only if g is mean periodic.^[5]

In work related to the Langlands correspondence, the mean-periodicity of certain (functions related to) zeta functions associated to an arithmetic scheme have been suggested to correspond to automorphicity of the related L-function.^[6] There is a certain class of mean-periodic functions arising from number theory.

• 　almost periodic functions

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