Index Coding Problem with Side Information Repositories

TL;DR

This paper explores how caching helpers in cellular networks can be leveraged to optimize index coding schemes, reducing transmission costs by exploiting side information in a system with multiple users and helpers.

Contribution

It introduces a canonical problem model with fixed helpers, analyzes the complexity of XOR coloring schemes, and demonstrates polynomial-time solutions exploiting graph structures.

Findings

Polynomial complexity for XOR coloring schemes with fixed helpers

Reduction of the general problem to a canonical bipartite graph structure

Exploitation of graph structure for efficient coding scheme computation

Abstract

To tackle the expected enormous increase in mobile video traffic in cellular networks, an architecture involving a base station along with caching femto stations (referred to as helpers), storing popular files near users, has been proposed [1]. The primary benefit of caching is the enormous increase in downloading rate when a popular file is available at helpers near a user requesting that file. In this work, we explore a secondary benefit of caching in this architecture through the lens of index coding. We assume a system with n users and constant number of caching helpers. Only helpers store files, i.e. have side information. We investigate the following scenario: Each user requests a distinct file that is not found in the set of helpers nearby. Users are served coded packets (through an index code) by an omniscient base station. Every user decodes its desired packet from the coded packets and the side information packets from helpers nearby. We assume that users can obtain any file stored in their neighboring helpers without incurring transmission costs. With respect to the index code employed, we investigate two achievable schemes: 1) XOR coloring based on coloring of the side information graph associated with the problem and 2)Vector XOR coloring based on fractional coloring of the side information graph. We show that the general problem reduces to a canonical problem where every user is connected to exactly one helper under some topological constraints. For the canonical problem, with constant number of helpers (k), we show that the complexity of computing the best XOR/vector XOR coloring schemes are polynomial in the number of users n. The result exploits a special complete bi-partite structure that the side information graphs exhibit for any finite k.