Mean integrated squared error

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In mathematics, the Babenko–Beckner inequality (after K. Ivan Babenko and William E. Beckner) is a sharpened form of the Hausdorff–Young inequality having applications to uncertainty principles in the Fourier analysis of Lp spaces. The (qp)-norm of the n-dimensional Fourier transform is defined to be[1]

q,p=supfLp(n)fqfp, where 1<p2, and 1p+1q=1.

In 1961, Babenko[2] found this norm for even integer values of q. Finally, in 1975, using Hermite functions as eigenfunctions of the Fourier transform, Beckner[3] proved that the value of this norm for all q2 is

q,p=(p1/p/q1/q)n/2.

Thus we have the Babenko–Beckner inequality that

fq(p1/p/q1/q)n/2fp.

To write this out explicitly, (in the case of one dimension,) if the Fourier transform is normalized so that

g(y)e2πixyf(x)dx and f(x)e2πixyg(y)dy,

then we have

(|g(y)|qdy)1/q(p1/p/q1/q)1/2(|f(x)|pdx)1/p

or more simply

(q|g(y)|qdy)1/q(p|f(x)|pdx)1/p.

Main ideas of proof

Throughout this sketch of a proof, let

1<p2,1p+1q=1,andω=1p=ip1.

(Except for q, we will more or less follow the notation of Beckner.)

The two-point lemma

Let dν(x) be the discrete measure with weight 1/2 at the points x=±1. Then the operator

C:a+bxa+ωbx

maps Lp(dν) to Lq(dν) with norm 1; that is,

[|a+ωbx|qdν(x)]1/q[|a+bx|pdν(x)]1/p,

or more explicitly,

[|a+ωb|q+|aωb|q2]1/q[|a+b|p+|ab|p2]1/p

for any complex a, b. (See Beckner's paper for the proof of his "two-point lemma".)

A sequence of Bernoulli trials

The measure dν that was introduced above is actually a fair Bernoulli trial with mean 0 and variance 1. Consider the sum of a sequence of n such Bernoulli trials, independent and normalized so that the standard deviation remains 1. We obtain the measure dνn(x) which is the n-fold convolution of dν(nx) with itself. The next step is to extend the operator C defined on the two-point space above to an operator defined on the (n + 1)-point space of dνn(x) with respect to the elementary symmetric polynomials.

Convergence to standard normal distribution

The sequence dνn(x) converges weakly to the standard normal probability distribution dμ(x)=12πex2/2dx with respect to functions of polynomial growth. In the limit, the extension of the operator C above in terms of the elementary symmetric polynomials with respect to the measure dνn(x) is expressed as an operator T in terms of the Hermite polynomials with respect to the standard normal distribution. These Hermite functions are the eigenfunctions of the Fourier transform, and the (qp)-norm of the Fourier transform is obtained as a result after some renormalization.

See also

References

  1. Iwo Bialynicki-Birula. Formulation of the uncertainty relations in terms of the Renyi entropies. arXiv:quant-ph/0608116v2
  2. K.I. Babenko. An ineqality in the theory of Fourier analysis. Izv. Akad. Nauk SSSR, Ser. Mat. 25 (1961) pp. 531–542 English transl., Amer. Math. Soc. Transl. (2) 44, pp. 115–128
  3. W. Beckner, Inequalities in Fourier analysis. Annals of Mathematics, Vol. 102, No. 6 (1975) pp. 159–182.