Abstract
One of the important yet insufficiently studied subjects in fair allocation is the externality effect among agents. For a resource allocation problem, externalities imply that the share allocated to an agent may affect the utilities of other agents. In this paper, we conduct a study of fair allocation of indivisible goods with positive externalities. Inspired by the models in the context of network diffusion, we present a simple and natural model, namely network externalities, to capture the externalities. To evaluate fairness in the network externalities model, we generalize the idea behind the notion of maximin-share (
(mathsf {MMS})
) to achieve a new criterion, namely, extended-maximin-share (
(mathsf {EMMS})
). Next, we consider two problems concerning our model. First, we discuss the computational aspects of finding the value of
(mathsf {EMMS})
for every agent. For this, we introduce a generalized form of partitioning problem that includes many famous partitioning problems such as maximin, minimax, and leximin. We further show that a 1/2-approximation algorithm exists for this partitioning problem. Next, we investigate approximate
(mathsf {EMMS})
allocations, i.e., allocations that guarantee each agent a utility of at least a fraction of his extended-maximin-share. We show that under a natural assumption that the agents are
(alpha)
-self-reliant, an
(alpha /2)
–
(mathsf {EMMS})
allocation always exists. This, combined with the former result yields a polynomial-time
(alpha /4)
–
(mathsf {EMMS})
allocation algorithm.