DocumentCode
67551
Title
A Classification of Unimodular Lattice Wiretap Codes in Small Dimensions
Author
Fuchun Lin ; Oggier, Frederique
Author_Institution
Div. of Math. Sci., Nanyang Technol. Univ., Singapore, Singapore
Volume
59
Issue
6
fYear
2013
fDate
Jun-13
Firstpage
3295
Lastpage
3303
Abstract
Lattice coding over a Gaussian wiretap channel, where an eavesdropper listens to transmissions between a transmitter and a legitimate receiver, is considered. A new lattice invariant called the secrecy gain is used as a code design criterion for wiretap lattice codes since it was shown to characterize the confusion that a chosen lattice can cause at the eavesdropper: the higher the secrecy gain of the lattice, the more confusion. In this paper, secrecy gains of extremal odd unimodular lattices as well as unimodular lattices in dimension n, 16 ≤ n ≤ 23, are computed, covering the four extremal odd unimodular lattices and all the 111 nonextremal unimodular lattices (both odd and even), providing thus a classification of the best wiretap lattice codes coming from unimodular lattices in dimension n, 8 <; n ≤ 23. Finally, to permit lattice encoding via Construction A, the corresponding error correction codes of the best lattices are determined.
Keywords
Gaussian channels; encoding; error correction codes; radio receivers; radio transmitters; Gaussian wiretap channel; code design criterion; eavesdropper; error correction codes; lattice coding; lattice invariant; legitimate receiver; secrecy gains; transmitter; unimodular lattice wiretap code classification; wiretap lattice codes; Argon; Encoding; Equations; Gain; Jacobian matrices; Lattices; Vectors; Gaussian channel; lattice codes; secrecy gain; theta series; unimodular lattices; wiretap codes;
fLanguage
English
Journal_Title
Information Theory, IEEE Transactions on
Publisher
ieee
ISSN
0018-9448
Type
jour
DOI
10.1109/TIT.2013.2246814
Filename
6469232
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