1 research outputs found
On the Total-Power Capacity of Regular-LDPC Codes with Iterative Message-Passing Decoders
Motivated by recently derived fundamental limits on total (transmit +
decoding) power for coded communication with VLSI decoders, this paper
investigates the scaling behavior of the minimum total power needed to
communicate over AWGN channels as the target bit-error-probability tends to
zero. We focus on regular-LDPC codes and iterative message-passing decoders. We
analyze scaling behavior under two VLSI complexity models of decoding. One
model abstracts power consumed in processing elements ("node model"), and
another abstracts power consumed in wires which connect the processing elements
("wire model"). We prove that a coding strategy using regular-LDPC codes with
Gallager-B decoding achieves order-optimal scaling of total power under the
node model. However, we also prove that regular-LDPC codes and iterative
message-passing decoders cannot meet existing fundamental limits on total power
under the wire model. Further, if the transmit energy-per-bit is bounded, total
power grows at a rate that is worse than uncoded transmission. Complementing
our theoretical results, we develop detailed physical models of decoding
implementations using post-layout circuit simulations. Our theoretical and
numerical results show that approaching fundamental limits on total power
requires increasing the complexity of both the code design and the
corresponding decoding algorithm as communication distance is increased or
error-probability is lowered.Comment: 21 pages, 6 figures. To appear in JSAC Recent Advances In Capacity
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