Minimum Target Sets in Non-Progressive Threshold Models: When Timing Matters
Abstract
Let be a graph, which represents a social network, and suppose each node has a threshold value . Consider an initial configuration, where each node is either positive or negative. In each discrete time step, a node becomes/remains positive if at least of its neighbors are positive and negative otherwise. A node set is a Target Set (TS) whenever the following holds: if is fully positive initially, all nodes in the graph become positive eventually. We focus on a generalization of TS, called Timed TS (TTS), where it is permitted to assign a positive state to a node at any step of the process, rather than just at the beginning. We provide graph structures for which the minimum TTS is significantly smaller than the minimum TS, indicating that timing is an essential aspect of successful target selection strategies. Furthermore, we prove tight bounds on the minimum size of a TTS in terms of the number of nodes and maximum degree when the thresholds are assigned based on the majority rule. We show that the problem of determining the minimum size of a TTS is NP-hard and provide an Integer Linear Programming formulation and a greedy algorithm. We evaluate the performance of our algorithm by conducting experiments on various synthetic and real-world networks. We also present a linear-time exact algorithm for trees.
Cite
@article{arxiv.2307.09111,
title = {Minimum Target Sets in Non-Progressive Threshold Models: When Timing Matters},
author = {Hossein Soltani and Ahad N. Zehmakan and Ataabak B. Hushmandi},
journal= {arXiv preprint arXiv:2307.09111},
year = {2023}
}
Comments
Accepted in ECAI-23 (26th European Conference on Artificial Intelligence)