Faster Closest-Point Algorithms for the $E_6^*$ and $E_7^*$ Lattices
摘要
The dual lattices and are of particular interest in source coding and data compression applications. Among all known lattices in dimensions six and seven they attain the smallest normalized second moments, i.e., the smallest average quantization error. Their use in practice requires fast closest-point (nearest-lattice-point) algorithms. The known approach, due to Conway and Sloane and completed for and by Takizawa, Yagi, and Kawabata (TYK), decodes these lattices as unions of cosets of root lattices : each coset is decoded separately, and the best result is kept. This requires four coset decodings for and six for , together with explicit distance computations. This paper shows that all these coset decodings can be collapsed into a single sweep. Reformulated in terms of glue vectors, the TYK decompositions state that is the union of the even glue classes of , and that is a parity-matched sublattice of . The candidate chain constructed by the closest-point algorithm of McKilliam, Clarkson, and Quinn (MCQ) for visits every glue class of exactly once and is optimal within each class. Consequently, one sorted sweep per coordinate block yields the closest points of all glue cosets simultaneously, and and are decoded at roughly the cost of a single or quantization. Rough operation counts indicate a -- reduction for and -- for relative to coset-by-coset decoding. We also discuss further constant-factor improvements available from recent refinements of the algorithms, and an open question concerning sort-free linear-time decoding.
引用
@article{arxiv.2607.10885,
title = {Faster Closest-Point Algorithms for the $E_6^*$ and $E_7^*$ Lattices},
author = {Yuriy A. Reznik},
journal= {arXiv preprint arXiv:2607.10885},
year = {2026}
}