Characterization of the Complexity of Computing the Minimum Mean Square Error of Causal Prediction

Holger Boche; Volker Pohl; H. Vincent Poor

doi:10.1109/TIT.2024.3431695

Characterization of the Complexity of Computing the Minimum Mean Square Error of Causal Prediction

Holger Boche, Volker Pohl, H. Vincent Poor

Chair of Theoretical Information Technology

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Abstract

This paper investigates the complexity of computing the minimum mean square prediction error for wide-sense stationary stochastic processes. It is shown that if the spectral density of the stationary process is a strictly positive, computable continuous function then the minimum mean square error (MMSE) is always a computable number. Nevertheless, we also show that the computation of the MMSE is a #P1 complete problem on the set of strictly positive, polynomial-time computable, continuous spectral densities. This means that if, as widely assumed, FP1 ≠ #P1, then there exist strictly positive, polynomial-time computable continuous spectral densities for which the computation of the MMSE is not polynomial-time computable. These results show in particular that under the widely accepted assumptions of complexity theory, the computation of the MMSE is generally much harder than an NP1 complete problem.

Original language	English
Pages (from-to)	6627-6638
Number of pages	12
Journal	IEEE Transactions on Information Theory
Volume	70
Issue number	9
DOIs	https://doi.org/10.1109/TIT.2024.3431695
State	Published - 2024

Keywords

Turing machine
Wiener prediction filter
complexity blowup
complexity theory
computability
minimum mean square error

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10.1109/TIT.2024.3431695

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title = "Characterization of the Complexity of Computing the Minimum Mean Square Error of Causal Prediction",

abstract = "This paper investigates the complexity of computing the minimum mean square prediction error for wide-sense stationary stochastic processes. It is shown that if the spectral density of the stationary process is a strictly positive, computable continuous function then the minimum mean square error (MMSE) is always a computable number. Nevertheless, we also show that the computation of the MMSE is a #P1 complete problem on the set of strictly positive, polynomial-time computable, continuous spectral densities. This means that if, as widely assumed, FP1 ≠ #P1, then there exist strictly positive, polynomial-time computable continuous spectral densities for which the computation of the MMSE is not polynomial-time computable. These results show in particular that under the widely accepted assumptions of complexity theory, the computation of the MMSE is generally much harder than an NP1 complete problem.",

keywords = "Turing machine, Wiener prediction filter, complexity blowup, complexity theory, computability, minimum mean square error",

author = "Holger Boche and Volker Pohl and Poor, {H. Vincent}",

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AU - Pohl, Volker

AU - Poor, H. Vincent

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N2 - This paper investigates the complexity of computing the minimum mean square prediction error for wide-sense stationary stochastic processes. It is shown that if the spectral density of the stationary process is a strictly positive, computable continuous function then the minimum mean square error (MMSE) is always a computable number. Nevertheless, we also show that the computation of the MMSE is a #P1 complete problem on the set of strictly positive, polynomial-time computable, continuous spectral densities. This means that if, as widely assumed, FP1 ≠ #P1, then there exist strictly positive, polynomial-time computable continuous spectral densities for which the computation of the MMSE is not polynomial-time computable. These results show in particular that under the widely accepted assumptions of complexity theory, the computation of the MMSE is generally much harder than an NP1 complete problem.

AB - This paper investigates the complexity of computing the minimum mean square prediction error for wide-sense stationary stochastic processes. It is shown that if the spectral density of the stationary process is a strictly positive, computable continuous function then the minimum mean square error (MMSE) is always a computable number. Nevertheless, we also show that the computation of the MMSE is a #P1 complete problem on the set of strictly positive, polynomial-time computable, continuous spectral densities. This means that if, as widely assumed, FP1 ≠ #P1, then there exist strictly positive, polynomial-time computable continuous spectral densities for which the computation of the MMSE is not polynomial-time computable. These results show in particular that under the widely accepted assumptions of complexity theory, the computation of the MMSE is generally much harder than an NP1 complete problem.

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KW - Wiener prediction filter

KW - complexity blowup

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Characterization of the Complexity of Computing the Minimum Mean Square Error of Causal Prediction

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