Trigonometric moment problem

In mathematics, the trigonometric moment problem is formulated as follows: given a finite sequence $\{c_{0},\dotsc ,c_{n}\}$ , does there exist a distribution function $\mu$ on the interval $[0,2\pi ]$ such that:^[1]

c_{k}={\frac {1}{2\pi }}\int _{0}^{2\pi }e^{-ik\theta }\,d\mu (\theta ).

In other words, an affirmative answer to the problems means that $\{c_{0},\dotsc ,c_{n}\}$ are the first $n + 1$ Fourier coefficients of some measure $\mu$ on $[0,2\pi ]$ .

Characterization[edit]

The trigonometric moment problem is solvable, that is, $\{c_{k}\}_{k=0}^{n}$ is a sequence of Fourier coefficients, if and only if the $(n + 1) \times (n + 1)$ Hermitian Toeplitz matrix

T=\left({\begin{matrix}c_{0}&c_{1}&\cdots &c_{n}\\c_{-1}&c_{0}&\cdots &c_{n-1}\\\vdots &\vdots &\ddots &\vdots \\c_{-n}&c_{-n+1}&\cdots &c_{0}\\\end{matrix}}\right)

with

c_{-k}={\overline {c_{k}}}

for

k\geq 1

,

is positive semi-definite.^[2]

The "only if" part of the claims can be verified by a direct calculation. We sketch an argument for the converse. The positive semidefinite matrix $T$ defines a sesquilinear product on $\mathbb {C} ^{n+1}$ , resulting in a Hilbert space

({\mathcal {H}},\langle \;,\;\rangle )

of dimensional at most $n + 1$ . The Toeplitz structure of $T$ means that a "truncated" shift is a partial isometry on ${\mathcal {H}}$ . More specifically, let $\{e_{0},\dotsc ,e_{n}\}$ be the standard basis of $\mathbb {C} ^{n+1}$ . Let ${\mathcal {E}}$ and ${\mathcal {F}}$ be subspaces generated by the equivalence classes $\{[e_{0}],\dotsc ,[e_{n-1}]\}$ respectively $\{[e_{1}],\dotsc ,[e_{n}]\}$ . Define an operator

V:{\mathcal {E}}\rightarrow {\mathcal {F}}

by

V[e_{k}]=[e_{k+1}]\quad {\mbox{for}}\quad k=0\ldots n-1.

Since

\langle V[e_{j}],V[e_{k}]\rangle =\langle [e_{j+1}],[e_{k+1}]\rangle =T_{j+1,k+1}=T_{j,k}=\langle [e_{j}],[e_{k}]\rangle ,

$V$ can be extended to a partial isometry acting on all of ${\mathcal {H}}$ . Take a minimal unitary extension $U$ of $V$ , on a possibly larger space (this always exists). According to the spectral theorem, there exists a Borel measure $m$ on the unit circle $\mathbb {T}$ such that for all integer $k$

\langle (U^{*})^{k}[e_{n+1}],[e_{n+1}]\rangle =\int _{\mathbb {T} }z^{k}dm.

For $k=0,\dotsc ,n$ , the left hand side is

\langle (U^{*})^{k}[e_{n+1}],[e_{n+1}]\rangle =\langle (V^{*})^{k}[e_{n+1}],[e_{n+1}]\rangle =\langle [e_{n+1-k}],[e_{n+1}]\rangle =T_{n+1,n+1-k}=c_{-k}={\overline {c_{k}}}.

So

c_{k}=\int _{\mathbb {T} }z^{-k}dm=\int _{\mathbb {T} }{\bar {z}}^{k}dm

which is equivalent to

c_{k}={\frac {1}{2\pi }}\int _{0}^{2\pi }e^{-ik\theta }d\mu (\theta )

for some suitable measure $\mu$ .

Parametrization of solutions[edit]

The above discussion shows that the trigonometric moment problem has infinitely many solutions if the Toeplitz matrix $T$ is invertible. In that case, the solutions to the problem are in bijective correspondence with minimal unitary extensions of the partial isometry $V$ .

Notes[edit]

^ Geronimus 1946.
^ Schmüdgen 2017, p. 260.

References[edit]

Akhiezer, Naum I. (1965). The classical moment problem and some related questions in analysis. New York: Hafner Publishing Co. (translated from the Russian by N. Kemmer)
Akhiezer, N.I.; Kreĭn, M.G. (1962). Some Questions in the Theory of Moments. Translations of mathematical monographs. American Mathematical Society. ISBN 978-0-8218-1552-6.
Geronimus, J. (1946). "On the Trigonometric Moment Problem". Annals of Mathematics. 47 (4): 742–761. doi:10.2307/1969232. ISSN 0003-486X. JSTOR 1969232.
Schmüdgen, Konrad (2017). The Moment Problem. Graduate Texts in Mathematics. Vol. 277. Cham: Springer International Publishing. doi:10.1007/978-3-319-64546-9. ISBN 978-3-319-64545-2. ISSN 0072-5285.

[FOOTNOTEGeronimus1946-1] Geronimus 1946.

[FOOTNOTESchmüdgen2017260-2] Schmüdgen 2017, p. 260.

[1]

[2]

Characterization[edit]

Parametrization of solutions[edit]

See also[edit]

Notes[edit]

References[edit]