How Many Attackers Can Selfish Defenders Catch?

TL;DR

This paper analyzes the maximum protection defenders can achieve against attackers in a distributed system at Nash equilibrium, revealing complex dependencies on the number of defenders and graph-theoretic thresholds.

Contribution

It introduces a combinatorial framework for understanding defense optimization in self-interested attacker-defender models, identifying thresholds affecting Defense-Ratio optimization.

Findings

Defense-Ratio optimization depends on defender count relative to graph thresholds.

Optimization is computationally feasible for many defenders but NP-complete for few.

There exists a middle range of defenders where optimization is impossible.

Abstract

In a distributed system with {\it attacks} and {\it defenses,} both {\it attackers} and {\it defenders} are self-interested entities. We assume a {\it reward-sharing} scheme among {\it interdependent} defenders; each defender wishes to (locally) maximize her own total {\it fair share} to the attackers extinguished due to her involvement (and possibly due to those of others). What is the {\em maximum} amount of protection achievable by a number of such defenders against a number of attackers while the system is in a {\it Nash equilibrium}? As a measure of system protection, we adopt the {\it Defense-Ratio} \cite{MPPS05a}, which provides the expected (inverse) proportion of attackers caught by the defenders. In a {\it Defense-Optimal} Nash equilibrium, the Defense-Ratio is optimized. We discover that the possibility of optimizing the Defense-Ratio (in a Nash equilibrium) depends in a subtle way on how the number of defenders compares to two natural graph-theoretic thresholds we identify. In this vein, we obtain, through a combinatorial analysis of Nash equilibria, a collection of trade-off results: - When the number of defenders is either sufficiently small or sufficiently large, there are cases where the Defense-Ratio can be optimized. The optimization problem is computationally tractable for a large number of defenders; the problem becomes ${\cal NP}$-complete for a small number of defenders and the intractability is inherited from a previously unconsidered combinatorial problem in {\em Fractional Graph Theory}. - Perhaps paradoxically, there is a middle range of values for the number of defenders where optimizing the Defense-Ratio is never possible.