Login / Signup

Self-Coexistence among IEEE 802.22 Networks: Distributed Allocation of Power and Channel.

Sayef Azad SakinMd Abdur RazzaqueMohammad Mehedi HassanAtif AlamriNguyen H TranGiancarlo Fortino
Published in: Sensors (Basel, Switzerland) (2017)
Ensuring self-coexistence among IEEE 802.22 networks is a challenging problem owing to opportunistic access of incumbent-free radio resources by users in co-located networks. In this study, we propose a fully-distributed non-cooperative approach to ensure self-coexistence in downlink channels of IEEE 802.22 networks. We formulate the self-coexistence problem as a mixed-integer non-linear optimization problem for maximizing the network data rate, which is an NP-hard one. This work explores a sub-optimal solution by dividing the optimization problem into downlink channel allocation and power assignment sub-problems. Considering fairness, quality of service and minimum interference for customer-premises-equipment, we also develop a greedy algorithm for channel allocation and a non-cooperative game-theoretic framework for near-optimal power allocation. The base stations of networks are treated as players in a game, where they try to increase spectrum utilization by controlling power and reaching a Nash equilibrium point. We further develop a utility function for the game to increase the data rate by minimizing the transmission power and, subsequently, the interference from neighboring networks. A theoretical proof of the uniqueness and existence of the Nash equilibrium has been presented. Performance improvements in terms of data-rate with a degree of fairness compared to a cooperative branch-and-bound-based algorithm and a non-cooperative greedy approach have been shown through simulation studies.
Keyphrases
  • electronic health record
  • mental health
  • machine learning
  • big data
  • healthcare
  • molecular dynamics
  • deep learning
  • molecular dynamics simulations
  • neural network
  • quality improvement
  • newly diagnosed