Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels

Holger Boche; Andrea Grigorescu; Rafael F. Schaefer; H. Vincent Poor

doi:10.1109/ICC51166.2024.10622861

Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels

Holger Boche, Andrea Grigorescu, Rafael F. Schaefer, H. Vincent Poor

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

This paper investigates the computational complexity involved in determining the capacity of the band-limited additive colored Gaussian noise (ACGN) channel and its capacity-achieving input power spectral density (p.s.d.). A band-limited polynomial time computable continuous and strictly positive noise p.s.d. is constructed for the ACGN channel such that the computation of its corresponding capacity is ≠P1-complete. This means that it is even more complex than problems that are ≠P1-complete. Additionally, it is shown that computing the capacity-achieving input p.s.d. is also ≠≠P1-complete. Furthermore, under the widely accepted assumption that ≠P1≠P1, there are two significant implications for the ACGN channel. First, there exists a polynomial time computable noise p.s.d. for which computing its capacity is not polynomial-time feasible, meaning the number of computational steps on a Turing Machine grows faster than any polynomial. Second, there is a polynomial time computable noise p.s.d. where determining its capacity-achieving input p.s.d. is also not achievable in polynomial time.

Original language	English (US)
Title of host publication	ICC 2024 - IEEE International Conference on Communications
Editors	Matthew Valenti, David Reed, Melissa Torres
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	4114-4119
Number of pages	6
ISBN (Electronic)	9781728190549
DOIs	https://doi.org/10.1109/ICC51166.2024.10622861
State	Published - 2024
Externally published	Yes
Event	59th Annual IEEE International Conference on Communications, ICC 2024 - Denver, United States Duration: Jun 9 2024 → Jun 13 2024

Publication series

Name	IEEE International Conference on Communications
ISSN (Print)	1550-3607

Conference

Conference	59th Annual IEEE International Conference on Communications, ICC 2024
Country/Territory	United States
City	Denver
Period	6/9/24 → 6/13/24

All Science Journal Classification (ASJC) codes

Computer Networks and Communications
Electrical and Electronic Engineering

Access to Document

10.1109/ICC51166.2024.10622861

Cite this

Boche, H., Grigorescu, A., Schaefer, R. F., & Poor, H. V. (2024). Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels. In M. Valenti, D. Reed, & M. Torres (Eds.), ICC 2024 - IEEE International Conference on Communications (pp. 4114-4119). (IEEE International Conference on Communications). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICC51166.2024.10622861

Boche, Holger ; Grigorescu, Andrea ; Schaefer, Rafael F. et al. / Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels. ICC 2024 - IEEE International Conference on Communications. editor / Matthew Valenti ; David Reed ; Melissa Torres. Institute of Electrical and Electronics Engineers Inc., 2024. pp. 4114-4119 (IEEE International Conference on Communications).

@inproceedings{7e41763adfc542399752ba1364d345ff,

title = "Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels",

abstract = "This paper investigates the computational complexity involved in determining the capacity of the band-limited additive colored Gaussian noise (ACGN) channel and its capacity-achieving input power spectral density (p.s.d.). A band-limited polynomial time computable continuous and strictly positive noise p.s.d. is constructed for the ACGN channel such that the computation of its corresponding capacity is ≠P1-complete. This means that it is even more complex than problems that are ≠P1-complete. Additionally, it is shown that computing the capacity-achieving input p.s.d. is also ≠≠P1-complete. Furthermore, under the widely accepted assumption that ≠P1≠P1, there are two significant implications for the ACGN channel. First, there exists a polynomial time computable noise p.s.d. for which computing its capacity is not polynomial-time feasible, meaning the number of computational steps on a Turing Machine grows faster than any polynomial. Second, there is a polynomial time computable noise p.s.d. where determining its capacity-achieving input p.s.d. is also not achievable in polynomial time.",

author = "Holger Boche and Andrea Grigorescu and Schaefer, \{Rafael F.\} and Poor, \{H. Vincent\}",

note = "Publisher Copyright: {\textcopyright} 2024 IEEE.; 59th Annual IEEE International Conference on Communications, ICC 2024 ; Conference date: 09-06-2024 Through 13-06-2024",

year = "2024",

doi = "10.1109/ICC51166.2024.10622861",

language = "English (US)",

series = "IEEE International Conference on Communications",

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Boche, H, Grigorescu, A, Schaefer, RF & Poor, HV 2024, Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels. in M Valenti, D Reed & M Torres (eds), ICC 2024 - IEEE International Conference on Communications. IEEE International Conference on Communications, Institute of Electrical and Electronics Engineers Inc., pp. 4114-4119, 59th Annual IEEE International Conference on Communications, ICC 2024, Denver, United States, 6/9/24. https://doi.org/10.1109/ICC51166.2024.10622861

Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels. / Boche, Holger; Grigorescu, Andrea; Schaefer, Rafael F. et al.
ICC 2024 - IEEE International Conference on Communications. ed. / Matthew Valenti; David Reed; Melissa Torres. Institute of Electrical and Electronics Engineers Inc., 2024. p. 4114-4119 (IEEE International Conference on Communications).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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T1 - Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels

AU - Boche, Holger

AU - Grigorescu, Andrea

AU - Schaefer, Rafael F.

AU - Poor, H. Vincent

PY - 2024

Y1 - 2024

N2 - This paper investigates the computational complexity involved in determining the capacity of the band-limited additive colored Gaussian noise (ACGN) channel and its capacity-achieving input power spectral density (p.s.d.). A band-limited polynomial time computable continuous and strictly positive noise p.s.d. is constructed for the ACGN channel such that the computation of its corresponding capacity is ≠P1-complete. This means that it is even more complex than problems that are ≠P1-complete. Additionally, it is shown that computing the capacity-achieving input p.s.d. is also ≠≠P1-complete. Furthermore, under the widely accepted assumption that ≠P1≠P1, there are two significant implications for the ACGN channel. First, there exists a polynomial time computable noise p.s.d. for which computing its capacity is not polynomial-time feasible, meaning the number of computational steps on a Turing Machine grows faster than any polynomial. Second, there is a polynomial time computable noise p.s.d. where determining its capacity-achieving input p.s.d. is also not achievable in polynomial time.

AB - This paper investigates the computational complexity involved in determining the capacity of the band-limited additive colored Gaussian noise (ACGN) channel and its capacity-achieving input power spectral density (p.s.d.). A band-limited polynomial time computable continuous and strictly positive noise p.s.d. is constructed for the ACGN channel such that the computation of its corresponding capacity is ≠P1-complete. This means that it is even more complex than problems that are ≠P1-complete. Additionally, it is shown that computing the capacity-achieving input p.s.d. is also ≠≠P1-complete. Furthermore, under the widely accepted assumption that ≠P1≠P1, there are two significant implications for the ACGN channel. First, there exists a polynomial time computable noise p.s.d. for which computing its capacity is not polynomial-time feasible, meaning the number of computational steps on a Turing Machine grows faster than any polynomial. Second, there is a polynomial time computable noise p.s.d. where determining its capacity-achieving input p.s.d. is also not achievable in polynomial time.

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M3 - Conference contribution

AN - SCOPUS:85202822030

T3 - IEEE International Conference on Communications

SP - 4114

EP - 4119

BT - ICC 2024 - IEEE International Conference on Communications

A2 - Valenti, Matthew

A2 - Reed, David

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PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 59th Annual IEEE International Conference on Communications, ICC 2024

Y2 - 9 June 2024 through 13 June 2024

ER -

Boche H, Grigorescu A, Schaefer RF, Poor HV. Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels. In Valenti M, Reed D, Torres M, editors, ICC 2024 - IEEE International Conference on Communications. Institute of Electrical and Electronics Engineers Inc. 2024. p. 4114-4119. (IEEE International Conference on Communications). doi: 10.1109/ICC51166.2024.10622861

Characterization of the Complexity of Computing the Capacity of Colored Noise Gaussian Channels

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