Characteristic function (probability theory)

In probability theory and statistics, the characteristic function of any real-valued random variable completely defines its probability distribution. If a random variable admits a probability density function, then the characteristic function is the Fourier transform (with sign reversal) of the probability density function. Thus it provides an alternative route to analytical results compared with working directly with probability density functions or cumulative distribution functions. There are particularly simple results for the characteristic functions of distributions defined by the weighted sums of random variables.

The characteristic function of a uniform U(–1,1) random variable. This function is real-valued because it corresponds to a random variable that is symmetric around the origin; however characteristic functions may generally be complex-valued.

In addition to univariate distributions, characteristic functions can be defined for vector- or matrix-valued random variables, and can also be extended to more generic cases.

The characteristic function always exists when treated as a function of a real-valued argument, unlike the moment-generating function. There are relations between the behavior of the characteristic function of a distribution and properties of the distribution, such as the existence of moments and the existence of a density function.

Introduction

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The characteristic function is a way to describe a random variable X. The characteristic function,

 

a function of t, determines the behavior and properties of the probability distribution of X. It is equivalent to a probability density function or cumulative distribution function, since knowing one of these functions allows computation of the others, but they provide different insights into the features of the random variable. In particular cases, one or another of these equivalent functions may be easier to represent in terms of simple standard functions.

If a random variable admits a density function, then the characteristic function is its Fourier dual, in the sense that each of them is a Fourier transform of the other. If a random variable has a moment-generating function  , then the domain of the characteristic function can be extended to the complex plane, and

 [1]

Note however that the characteristic function of a distribution is well defined for all real values of t, even when the moment-generating function is not well defined for all real values of t.

The characteristic function approach is particularly useful in analysis of linear combinations of independent random variables: a classical proof of the Central Limit Theorem uses characteristic functions and Lévy's continuity theorem. Another important application is to the theory of the decomposability of random variables.

Definition

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For a scalar random variable X the characteristic function is defined as the expected value of eitX, where i is the imaginary unit, and tR is the argument of the characteristic function:

 

Here FX is the cumulative distribution function of X, fX is the corresponding probability density function, QX(p) is the corresponding inverse cumulative distribution function also called the quantile function,[2] and the integrals are of the Riemann–Stieltjes kind. If a random variable X has a probability density function then the characteristic function is its Fourier transform with sign reversal in the complex exponential[3][page needed].[4] This convention for the constants appearing in the definition of the characteristic function differs from the usual convention for the Fourier transform.[5] For example, some authors[6] define φX(t) = E[e−2πitX], which is essentially a change of parameter. Other notation may be encountered in the literature:   as the characteristic function for a probability measure p, or   as the characteristic function corresponding to a density f.

Generalizations

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The notion of characteristic functions generalizes to multivariate random variables and more complicated random elements. The argument of the characteristic function will always belong to the continuous dual of the space where the random variable X takes its values. For common cases such definitions are listed below:

  • If X is a k-dimensional random vector, then for tRk   where   is the transpose of the vector   ,
  • If X is a k × p-dimensional random matrix, then for tRk×p   where   is the trace operator,
  • If X is a complex random variable, then for tC [7]   where   is the complex conjugate of   and   is the real part of the complex number  ,
  • If X is a k-dimensional complex random vector, then for tCk  [8]   where   is the conjugate transpose of the vector   ,
  • If X(s) is a stochastic process, then for all functions t(s) such that the integral   converges for almost all realizations of X [9]  

Examples

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Distribution Characteristic function  
Degenerate δa  
Bernoulli Bern(p)  
Binomial B(n, p)  
Negative binomial NB(r, p)  
Poisson Pois(λ)  
Uniform (continuous) U(a, b)  
Uniform (discrete) DU(a, b)  
Laplace L(μ, b)  
Logistic Logistic(μ,s)
 
Normal N(μ, σ2)  
Chi-squared χ2k  
Noncentral chi-squared    
Generalized chi-squared    
Cauchy C(μ, θ)  
Gamma Γ(k, θ)  
Exponential Exp(λ)  
Geometric Gf(p)
(number of failures)
 
Geometric Gt(p)
(number of trials)
 
Multivariate normal N(μ, Σ)  
Multivariate Cauchy MultiCauchy(μ, Σ)[10]  

Oberhettinger (1973) provides extensive tables of characteristic functions.

Properties

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  • The characteristic function of a real-valued random variable always exists, since it is an integral of a bounded continuous function over a space whose measure is finite.
  • A characteristic function is uniformly continuous on the entire space.
  • It is non-vanishing in a region around zero: φ(0) = 1.
  • It is bounded: |φ(t)| ≤ 1.
  • It is Hermitian: φ(−t) = φ(t). In particular, the characteristic function of a symmetric (around the origin) random variable is real-valued and even.
  • There is a bijection between probability distributions and characteristic functions. That is, for any two random variables X1, X2, both have the same probability distribution if and only if  . [citation needed]
  • If a random variable X has moments up to k-th order, then the characteristic function φX is k times continuously differentiable on the entire real line. In this case  
  • If a characteristic function φX has a k-th derivative at zero, then the random variable X has all moments up to k if k is even, but only up to k – 1 if k is odd.[11]  
  • If X1, ..., Xn are independent random variables, and a1, ..., an are some constants, then the characteristic function of the linear combination of the Xi variables is   One specific case is the sum of two independent random variables X1 and X2 in which case one has  
  • Let   and   be two random variables with characteristic functions   and  .   and   are independent if and only if  .
  • The tail behavior of the characteristic function determines the smoothness of the corresponding density function.
  • Let the random variable   be the linear transformation of a random variable  . The characteristic function of   is  . For random vectors   and   (where A is a constant matrix and B a constant vector), we have  .[12]

Continuity

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The bijection stated above between probability distributions and characteristic functions is sequentially continuous. That is, whenever a sequence of distribution functions Fj(x) converges (weakly) to some distribution F(x), the corresponding sequence of characteristic functions φj(t) will also converge, and the limit φ(t) will correspond to the characteristic function of law F. More formally, this is stated as

Lévy’s continuity theorem: A sequence Xj of n-variate random variables converges in distribution to random variable X if and only if the sequence φXj converges pointwise to a function φ which is continuous at the origin. Where φ is the characteristic function of X.[13]

This theorem can be used to prove the law of large numbers and the central limit theorem.

Inversion formula

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There is a one-to-one correspondence between cumulative distribution functions and characteristic functions, so it is possible to find one of these functions if we know the other. The formula in the definition of characteristic function allows us to compute φ when we know the distribution function F (or density f). If, on the other hand, we know the characteristic function φ and want to find the corresponding distribution function, then one of the following inversion theorems can be used.

Theorem. If the characteristic function φX of a random variable X is integrable, then FX is absolutely continuous, and therefore X has a probability density function. In the univariate case (i.e. when X is scalar-valued) the density function is given by  

In the multivariate case it is  

where   is the dot product.

The density function is the Radon–Nikodym derivative of the distribution μX with respect to the Lebesgue measure λ:  

Theorem (Lévy).[note 1] If φX is characteristic function of distribution function FX, two points a < b are such that {x | a < x < b} is a continuity set of μX (in the univariate case this condition is equivalent to continuity of FX at points a and b), then

  • If X is scalar:   This formula can be re-stated in a form more convenient for numerical computation as[14]   For a random variable bounded from below one can obtain   by taking   such that   Otherwise, if a random variable is not bounded from below, the limit for   gives  , but is numerically impractical.[14]
  • If X is a vector random variable:  

Theorem. If a is (possibly) an atom of X (in the univariate case this means a point of discontinuity of FX) then

  • If X is scalar:  
  • If X is a vector random variable:[15]  

Theorem (Gil-Pelaez).[16] For a univariate random variable X, if x is a continuity point of FX then

 

where the imaginary part of a complex number   is given by  .

And its density function is:

 

The integral may be not Lebesgue-integrable; for example, when X is the discrete random variable that is always 0, it becomes the Dirichlet integral.

Inversion formulas for multivariate distributions are available.[14][17]

Criteria for characteristic functions

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The set of all characteristic functions is closed under certain operations:

  • A convex linear combination   (with  ) of a finite or a countable number of characteristic functions is also a characteristic function.
  • The product of a finite number of characteristic functions is also a characteristic function. The same holds for an infinite product provided that it converges to a function continuous at the origin.
  • If φ is a characteristic function and α is a real number, then  , Re(φ), |φ|2, and φ(αt) are also characteristic functions.

It is well known that any non-decreasing càdlàg function F with limits F(−∞) = 0, F(+∞) = 1 corresponds to a cumulative distribution function of some random variable. There is also interest in finding similar simple criteria for when a given function φ could be the characteristic function of some random variable. The central result here is Bochner’s theorem, although its usefulness is limited because the main condition of the theorem, non-negative definiteness, is very hard to verify. Other theorems also exist, such as Khinchine’s, Mathias’s, or Cramér’s, although their application is just as difficult. Pólya’s theorem, on the other hand, provides a very simple convexity condition which is sufficient but not necessary. Characteristic functions which satisfy this condition are called Pólya-type.[18]

Bochner’s theorem. An arbitrary function φ : RnC is the characteristic function of some random variable if and only if φ is positive definite, continuous at the origin, and if φ(0) = 1.

Khinchine’s criterion. A complex-valued, absolutely continuous function φ, with φ(0) = 1, is a characteristic function if and only if it admits the representation

 

Mathias’ theorem. A real-valued, even, continuous, absolutely integrable function φ, with φ(0) = 1, is a characteristic function if and only if

 

for n = 0,1,2,..., and all p > 0. Here H2n denotes the Hermite polynomial of degree 2n.

 
Pólya’s theorem can be used to construct an example of two random variables whose characteristic functions coincide over a finite interval but are different elsewhere.

Pólya’s theorem. If   is a real-valued, even, continuous function which satisfies the conditions

  •  ,
  •   is convex for  ,
  •  ,

then φ(t) is the characteristic function of an absolutely continuous distribution symmetric about 0.

Uses

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Because of the continuity theorem, characteristic functions are used in the most frequently seen proof of the central limit theorem. The main technique involved in making calculations with a characteristic function is recognizing the function as the characteristic function of a particular distribution.

Basic manipulations of distributions

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Characteristic functions are particularly useful for dealing with linear functions of independent random variables. For example, if X1, X2, ..., Xn is a sequence of independent (and not necessarily identically distributed) random variables, and

 

where the ai are constants, then the characteristic function for Sn is given by

 

In particular, φX+Y(t) = φX(t)φY(t). To see this, write out the definition of characteristic function:

 

The independence of X and Y is required to establish the equality of the third and fourth expressions.

Another special case of interest for identically distributed random variables is when ai = 1 / n and then Sn is the sample mean. In this case, writing X for the mean,

 

Moments

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Characteristic functions can also be used to find moments of a random variable. Provided that the n-th moment exists, the characteristic function can be differentiated n times:

 

This can be formally written using the derivatives of the Dirac delta function: which allows a formal solution to the moment problem. For example, suppose X has a standard Cauchy distribution. Then φX(t) = e−|t|. This is not differentiable at t = 0, showing that the Cauchy distribution has no expectation. Also, the characteristic function of the sample mean X of n independent observations has characteristic function φX(t) = (e−|t|/n)n = e−|t|, using the result from the previous section. This is the characteristic function of the standard Cauchy distribution: thus, the sample mean has the same distribution as the population itself.

As a further example, suppose X follows a Gaussian distribution i.e.  . Then   and

 

A similar calculation shows   and is easier to carry out than applying the definition of expectation and using integration by parts to evaluate  .

The logarithm of a characteristic function is a cumulant generating function, which is useful for finding cumulants; some instead define the cumulant generating function as the logarithm of the moment-generating function, and call the logarithm of the characteristic function the second cumulant generating function.

Data analysis

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Characteristic functions can be used as part of procedures for fitting probability distributions to samples of data. Cases where this provides a practicable option compared to other possibilities include fitting the stable distribution since closed form expressions for the density are not available which makes implementation of maximum likelihood estimation difficult. Estimation procedures are available which match the theoretical characteristic function to the empirical characteristic function, calculated from the data. Paulson et al. (1975)[19] and Heathcote (1977)[20] provide some theoretical background for such an estimation procedure. In addition, Yu (2004)[21] describes applications of empirical characteristic functions to fit time series models where likelihood procedures are impractical. Empirical characteristic functions have also been used by Ansari et al. (2020)[22] and Li et al. (2020)[23] for training generative adversarial networks.

Example

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The gamma distribution with scale parameter θ and a shape parameter k has the characteristic function

 

Now suppose that we have

 

with X and Y independent from each other, and we wish to know what the distribution of X + Y is. The characteristic functions are

 

which by independence and the basic properties of characteristic function leads to

 

This is the characteristic function of the gamma distribution scale parameter θ and shape parameter k1 + k2, and we therefore conclude

 

The result can be expanded to n independent gamma distributed random variables with the same scale parameter and we get

 

Entire characteristic functions

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As defined above, the argument of the characteristic function is treated as a real number: however, certain aspects of the theory of characteristic functions are advanced by extending the definition into the complex plane by analytic continuation, in cases where this is possible.[24]

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Related concepts include the moment-generating function and the probability-generating function. The characteristic function exists for all probability distributions. This is not the case for the moment-generating function.

The characteristic function is closely related to the Fourier transform: the characteristic function of a probability density function p(x) is the complex conjugate of the continuous Fourier transform of p(x) (according to the usual convention; see continuous Fourier transform – other conventions).

 

where P(t) denotes the continuous Fourier transform of the probability density function p(x). Likewise, p(x) may be recovered from φX(t) through the inverse Fourier transform:

 

Indeed, even when the random variable does not have a density, the characteristic function may be seen as the Fourier transform of the measure corresponding to the random variable.

Another related concept is the representation of probability distributions as elements of a reproducing kernel Hilbert space via the kernel embedding of distributions. This framework may be viewed as a generalization of the characteristic function under specific choices of the kernel function.

See also

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  • Subindependence, a weaker condition than independence, that is defined in terms of characteristic functions.
  • Cumulant, a term of the cumulant generating functions, which are logs of the characteristic functions.

Notes

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  1. ^ named after the French mathematician Paul Lévy

References

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Citations

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  1. ^ Lukacs (1970), p. 196.
  2. ^ Shaw, W. T.; McCabe, J. (2009). "Monte Carlo sampling given a Characteristic Function: Quantile Mechanics in Momentum Space". arXiv:0903.1592 [q-fin.CP].
  3. ^ Statistical and Adaptive Signal Processing (2005)
  4. ^ Billingsley (1995).
  5. ^ Pinsky (2002).
  6. ^ Bochner (1955).
  7. ^ Andersen et al. (1995), Definition 1.10.
  8. ^ Andersen et al. (1995), Definition 1.20.
  9. ^ Sobczyk (2001), p. 20.
  10. ^ Kotz & Nadarajah (2004), p. 37 using 1 as the number of degree of freedom to recover the Cauchy distribution
  11. ^ Lukacs (1970), Corollary 1 to Theorem 2.3.1.
  12. ^ "Joint characteristic function". www.statlect.com. Retrieved 7 April 2018.
  13. ^ Cuppens (1975), Theorem 2.6.9.
  14. ^ a b c Shephard (1991a).
  15. ^ Cuppens (1975), Theorem 2.3.2.
  16. ^ Wendel (1961).
  17. ^ Shephard (1991b).
  18. ^ Lukacs (1970), p. 84.
  19. ^ Paulson, Holcomb & Leitch (1975).
  20. ^ Heathcote (1977).
  21. ^ Yu (2004).
  22. ^ Ansari, Scarlett & Soh (2020).
  23. ^ Li et al. (2020).
  24. ^ Lukacs (1970), Chapter 7.

Sources

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