Variable Min-Cut Max-Flow Bounds and Algorithms in Finite Regime

Abstract

The maximum achievable capacity from source to destination in a network is limited by the min-cut max-flow bound; this serves as a converse limit. In practice, link capacities often fluctuate due to dynamic network conditions. In this work, we introduce a novel analytical framework that leverages tools from computational geometry to analyze throughput in heterogeneous networks with variable link capacities in a finite regime. Within this model, we derive new performance bounds and demonstrate that increasing the number of links can reduce throughput variability by nearly 90\%. We formally define a notion of network stability and show that an unstable graph can have an exponential number of different min-cut sets, up to O(2|E|). To address this complexity, we propose an algorithm that enforces stability with time complexity O(|E|2 + |V|), and further suggest mitigating the delay-throughput tradeoff using adaptive rateless random linear network coding (AR-RLNC).