3,866 research outputs found
Algebraic Approach to Physical-Layer Network Coding
The problem of designing physical-layer network coding (PNC) schemes via
nested lattices is considered. Building on the compute-and-forward (C&F)
relaying strategy of Nazer and Gastpar, who demonstrated its asymptotic gain
using information-theoretic tools, an algebraic approach is taken to show its
potential in practical, non-asymptotic, settings. A general framework is
developed for studying nested-lattice-based PNC schemes---called lattice
network coding (LNC) schemes for short---by making a direct connection between
C&F and module theory. In particular, a generic LNC scheme is presented that
makes no assumptions on the underlying nested lattice code. C&F is
re-interpreted in this framework, and several generalized constructions of LNC
schemes are given. The generic LNC scheme naturally leads to a linear network
coding channel over modules, based on which non-coherent network coding can be
achieved. Next, performance/complexity tradeoffs of LNC schemes are studied,
with a particular focus on hypercube-shaped LNC schemes. The error probability
of this class of LNC schemes is largely determined by the minimum inter-coset
distances of the underlying nested lattice code. Several illustrative
hypercube-shaped LNC schemes are designed based on Construction A and D,
showing that nominal coding gains of 3 to 7.5 dB can be obtained with
reasonable decoding complexity. Finally, the possibility of decoding multiple
linear combinations is considered and related to the shortest independent
vectors problem. A notion of dominant solutions is developed together with a
suitable lattice-reduction-based algorithm.Comment: Submitted to IEEE Transactions on Information Theory, July 21, 2011.
Revised version submitted Sept. 17, 2012. Final version submitted July 3,
201
Efficient Decoding Algorithms for the Compute-and-Forward Strategy
We address in this paper decoding aspects of the Compute-and-Forward (CF)
physical-layer network coding strategy. It is known that the original decoder
for the CF is asymptotically optimal. However, its performance gap to optimal
decoders in practical settings are still not known. In this work, we develop
and assess the performance of novel decoding algorithms for the CF operating in
the multiple access channel. For the fading channel, we analyze the ML decoder
and develop a novel diophantine approximation-based decoding algorithm showed
numerically to outperform the original CF decoder. For the Gaussian channel, we
investigate the maximum a posteriori (MAP) decoder. We derive a novel MAP
decoding metric and develop practical decoding algorithms proved numerically to
outperform the original one
- …