Successive Local and Successive Global Omniscience

Abstract

This paper considers two generalizations of the cooperative data exchange problem, referred to as the successive local omniscience (SLO) and the successive global omniscience (SGO). The users are divided into nested sub-groups. Each user initially knows a subset of packets in a ground set X of size k, and all users wish to learn all packets in X. The users exchange their packets by broadcasting coded or uncoded packets. In SLO or SGO, in the lth (1≤ l≤ ) round of transmissions, the lth smallest sub-group of users need to learn all packets they collectively hold or all packets in X, respectively. The problem is to find the minimum sum-rate (i.e., the total transmission rate by all users) for each round, subject to minimizing the sum-rate for the previous round. To solve this problem, we use a linear-programming approach. For the cases in which the packets are randomly distributed among users, we construct a system of linear equations whose solution characterizes the minimum sum-rate for each round with high probability as k tends to infinity. Moreover, for the special case of two nested groups, we derive closed-form expressions, which hold with high probability as k tends to infinity, for the minimum sum-rate for each round.