On the Energy Complexity of LDPC Decoder Circuits

Abstract

It is shown that in a sequence of randomly generated bipartite configurations with number of left nodes approaching infinity, the probability that a particular configuration in the sequence has a minimum bisection width proportional to the number of vertices in the configuration approaches 1 so long as a sufficient condition on the node degree distribution is satisfied. This graph theory result implies an almost sure (n2) scaling rule for the energy of capacity-approaching LDPC decoder circuits that directly instantiate their Tanner Graphs and are generated according to a uniform configuration model, where n is the block length of the code. For a sequence of circuits that have a full set of check nodes but do not necessarily directly instantiate a Tanner graph, this implies an (n1.5) scaling rule. In another theorem, it is shown that all (as opposed to almost all) capacity-approaching LDPC decoding circuits that directly implement their Tanner graphs must have energy that scales as (n( n)2). These results further imply scaling rules for the energy of LDPC decoder circuits as a function of gap to capacity.