Rate Regions of Secret Key Sharing in a New Source Model

TL;DR

This paper analyzes the capacity regions for secret key sharing in a source model involving three users with correlated sources, considering both forward and backward communication strategies, and derives bounds and capacity results.

Contribution

It introduces a new source model for secret key sharing with two strategies and derives inner and outer bounds for the capacity regions, including special cases where bounds coincide.

Findings

Derived inner and outer bounds for secret key capacity regions.

Results align with known models in special cases.

Identified conditions where bounds coincide and capacity is exactly characterized.

Abstract

A source model for secret key generation between terminals is considered. Two users, namely users 1 and 2, at one side communicate with another user, namely user 3, at the other side via a public channel where three users can observe i.i.d. outputs of correlated sources. Each of users 1 and 2 intends to share a secret key with user 3 where user 1 acts as a wiretapper for user 2 and vice versa. In this model, two situations are considered: communication from users 1 and 2 to user 3 (the forward key strategy) and from user 3 to users 1 and 2 (the backward key strategy). In both situations, the goal is sharing a secret key between user 1 and user 3 while leaking no effective information about that key to user 2, and simultaneously, sharing another secret key between user 2 and user 3 while leaking no effective information about the latter key to user 1. This model is motivated by wireless communications when considering user 3 as a base station and users 1 and 2 as network users. In this paper, for both the forward and backward key strategies, inner and outer bounds of secret key capacity regions are derived. In special situations where one of users 1 and 2 is only interested in wiretapping and not key sharing, our results agree with that of Ahlswede and Csiszar. Also, we investigate some special cases in which the inner bound coincides with the outer bound and secret key capacity region is deduced.