Well-Rounded Lattices: Towards Optimal Coset Codes for Gaussian and Fading Wiretap Channels

Mohamed Taoufiq Damir; Alex Karrila; Laia Amoros; Oliver Gnilke; David Karpuk; Camilla Hollanti

doi:10.1109/TIT.2021.3059749

Well-Rounded Lattices: Towards Optimal Coset Codes for Gaussian and Fading Wiretap Channels

Mohamed Taoufiq Damir, Alex Karrila, Laia Amoros, Oliver Gnilke, David Karpuk, Camilla Hollanti

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

5 Citationer (Scopus)

Abstract

The design of lattice coset codes for wiretap channels is considered. Bounds on the eavesdropper's correct decoding probability and information leakage are first revisited. From these bounds, it is explicit that both the information leakage and error probability are controlled by the average flatness factor of the eavesdropper's lattice, which we further interpret geometrically. It is concluded that the minimization of the (average) flatness factor of the eavesdropper's lattice leads to the study of well-rounded lattices, which are shown to be among the optimal in order to achieve these minima. Constructions of some well-rounded lattices are also provided.

Originalsprog	Engelsk
Artikelnummer	9354828
Tidsskrift	IEEE Transactions on Information Theory
Vol/bind	67
Udgave nummer	6
Sider (fra-til)	3645-3663
Antal sider	19
ISSN	0018-9448
DOI	https://doi.org/10.1109/TIT.2021.3059749
Status	Udgivet - 2021

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10.1109/TIT.2021.3059749

https://arxiv.org/pdf/1609.07723.pdf

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keywords = "Coset codes, flatness factor, information theoretic security, lattices, multiple-input multiple-output (MIMO) channels, number fields, physical layer security, Rayleigh fast-fading channels, single-input single-output (SISO) channels, well-rounded lattices, wiretap channels",

author = "Damir, {Mohamed Taoufiq} and Alex Karrila and Laia Amoros and Oliver Gnilke and David Karpuk and Camilla Hollanti",

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AU - Karrila, Alex

AU - Amoros, Laia

AU - Gnilke, Oliver

AU - Karpuk, David

AU - Hollanti, Camilla

PY - 2021

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N2 - The design of lattice coset codes for wiretap channels is considered. Bounds on the eavesdropper's correct decoding probability and information leakage are first revisited. From these bounds, it is explicit that both the information leakage and error probability are controlled by the average flatness factor of the eavesdropper's lattice, which we further interpret geometrically. It is concluded that the minimization of the (average) flatness factor of the eavesdropper's lattice leads to the study of well-rounded lattices, which are shown to be among the optimal in order to achieve these minima. Constructions of some well-rounded lattices are also provided.

AB - The design of lattice coset codes for wiretap channels is considered. Bounds on the eavesdropper's correct decoding probability and information leakage are first revisited. From these bounds, it is explicit that both the information leakage and error probability are controlled by the average flatness factor of the eavesdropper's lattice, which we further interpret geometrically. It is concluded that the minimization of the (average) flatness factor of the eavesdropper's lattice leads to the study of well-rounded lattices, which are shown to be among the optimal in order to achieve these minima. Constructions of some well-rounded lattices are also provided.

KW - Coset codes

KW - flatness factor

KW - information theoretic security

KW - lattices

KW - multiple-input multiple-output (MIMO) channels

KW - number fields

KW - physical layer security

KW - Rayleigh fast-fading channels

KW - single-input single-output (SISO) channels

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KW - wiretap channels

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Well-Rounded Lattices: Towards Optimal Coset Codes for Gaussian and Fading Wiretap Channels

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