Impact of interference on multi-hop wireless network performance
Proceedings of the 9th annual international conference on Mobile computing and networking
Topology control meets SINR: the scheduling complexity of arbitrary topologies
Proceedings of the 7th ACM international symposium on Mobile ad hoc networking and computing
A Distributed Channel Access Protocol for Ad Hoc Networks with Feedback Power Control
IEEE Transactions on Mobile Computing
A potential game approach to distributed power control and scheduling
Computer Networks: The International Journal of Computer and Telecommunications Networking
Utility-optimal random access: reduced complexity, fast convergence, and robust performance
IEEE Transactions on Wireless Communications
Performance of random access scheduling schemes in multi-hop wireless networks
IEEE/ACM Transactions on Networking (TON)
Optimal SINR-based random access
INFOCOM'10 Proceedings of the 29th conference on Information communications
A power control game based on outage probabilities for multicell wireless data networks
IEEE Transactions on Wireless Communications
The capacity of wireless networks
IEEE Transactions on Information Theory
Performance analysis of the IEEE 802.11 distributed coordination function
IEEE Journal on Selected Areas in Communications
Distributed interference compensation for wireless networks
IEEE Journal on Selected Areas in Communications
Non-Cooperative Power Control for Wireless Ad Hoc Networks with Repeated Games
IEEE Journal on Selected Areas in Communications
Joint Algorithm of Channel Allocation and Power Control in Multi-channel Wireless Sensor Network
Wireless Personal Communications: An International Journal
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We consider a distributed joint random access and power control scheme for interference management in wireless ad hoc networks. To derive decentralized solutions that do not require any cooperation among the users, we formulate this problem as noncooperative joint random access and power control game, in which each user minimizes its average transmission cost with a given rate constraint. Using supermodular game theory, the existence and uniqueness of Nash equilibrium are established. Furthermore, we present an asynchronous distributed algorithm to compute the solution of the game based on myopic best response updates, which converges to Nash equilibrium globally. Finally, a link admission algorithm is carried out to guarantee the reliability of the active users. Performance evaluations via simulations show that the game-theoretical based cross-layer design achieves high performance in terms of energy consumption and network stability.