Zero-Error Distributed Function Compression for Binary Arithmetic Sum

TL;DR

This paper fully characterizes the zero-error distributed function compression capacity for binary arithmetic sum under various source observation and channel constraints, introducing a novel graph coloring approach.

Contribution

It provides a complete characterization of compression capacities for all source observation configurations, including a novel method for complex cases, and applies results to network function computation.

Findings

Complete capacity characterization for all source observation cases.

Development of a novel graph coloring approach for complex scenarios.

Application of capacity results to open problems in network function computation.

Abstract

In this paper, we put forward the model of zero-error distributed function compression system of two binary memoryless sources X and Y, where there are two encoders En1 and En2 and one decoder De, connected by two channels (En1, De) and (En2, De) with the capacity constraints C1 and C2, respectively. The encoder En1 can observe X or (X,Y) and the encoder En2 can observe Y or (X,Y) according to the two switches s1 and s2 open or closed (corresponding to taking values 0 or 1). The decoder De is required to compress the binary arithmetic sum f(X,Y)=X+Y with zero error by using the system multiple times. We use (s1s2;C1,C2;f) to denote the model in which it is assumed that C1 \geq C2 by symmetry. The compression capacity for the model is defined as the maximum average number of times that the function f can be compressed with zero error for one use of the system, which measures the efficiency of using the system. We fully characterize the compression capacities for all the four cases of the model (s1s2;C1,C2;f) for s1s2= 00,01,10,11. Here, the characterization of the compression capacity for the case (01;C1,C2;f) with C1>C2 is highly nontrivial, where a novel graph coloring approach is developed. Furthermore, we apply the compression capacity for (01;C1,C2;f) to an open problem in network function computation that whether the best known upper bound of Guang et al. on computing capacity is in general tight.