Title :
A mean-field game approach for distributed interference and resource management in heterogeneous cellular networks
Author :
Al-Zahrani, Ali Y. ; Yu, F. Richard ; Minyi Huang
Author_Institution :
Dept. of Syst. & Comput. Eng., Carleton Univ., Ottawa, ON, Canada
Abstract :
Intercell interference has been known as a crucial issue in heterogeneous networks where different transmitter-receiver pairs compete for system resources. We solve this problem in two steps. We firstly assign the macrocell user with the optimum number of subchannels, which just guarantee the required quality of service. Then, the remaining subchannels are left to be shared by a large number of small cells using mean field game theory, which is proved to be more tractable than conventional game theory. Using recent advances of mean field approximation techniques, we convert the entangled traditional game of small cells system into a mean-field game where resources allocation is much easier and simpler. With different network topologies, simulation results show the effectiveness of our proposed scheme.
Keywords :
cellular radio; game theory; interference (signal); quality of service; radio networks; radio transceivers; distributed interference; game theory; heterogeneous cellular networks; intercell interference; macrocell user; mean field approximation techniques; mean-field game approach; network topology; quality of service; resource allocation; resource management; subchannel number; system resources; transmitter-receiver pairs; wireless networks; Games; Interference; Macrocell networks; Quality of service; Topology; Vectors; Wireless communication; Interference management; heterogeneous cellular networks; mean-field game;
Conference_Titel :
Global Communications Conference (GLOBECOM), 2013 IEEE
Conference_Location :
Atlanta, GA
DOI :
10.1109/GLOCOMW.2013.6855737
