residual energy aware channel assignment in cognitive radio sensor networks wireless communications...
TRANSCRIPT
Residual Energy Aware Channel Assignment in Cognitive Radio Sensor Networks
Wireless Communications and Networking Conference
(WCNC), 2011 IEEE Xiaoyuan Li ; Dexiang Wang ; McNair, J. ; Jianmin Chen
Outline
• Introduction• Related work• System model• Channel assignment approaches• Simulation results• Conclusion
Introduction
• Existing WSNs are traditionally characterized by fixed spectrum allocation over crowded bands.
• The event-driven nature often generates bursty traffic, which increases the probability of collision and packet loss.
• Cognitive radio allows opportunistic spectrum access to multiple available channels, which gives potential advantages to WSNs by increasing the communication reliability and improving the energy efficiency.
Introduction (cont.)
• Most of the studies concentrate on sensing channel availability to improve spectrum utilization, modeling PU activity to avoid collision or analyzing QoS performance such as delay and throughput.
• However, only a few of the current studies for channel assignment in cognitive radio networks consider energy consumption problem, which is the critical concern for energy-constrained WSNs.
Introduction (cont.)
• In this paper, we consider a multi-channel CRSN, in which a cognitive radio is installed in each sensor.
• The radio can be tuned to any available channel. The channel assignment problem is investigated from the aspect of energy consumption and network lifetime.
Related Work
• OSA-MAC protocol based on IEEE 802.11 model is proposed for opportunistic spectrum access.
• It provides both uniformly random channel selection and spectrum opportunity-based channel selection.
• However, it does not consider the state change of PU behavior, which is studied in our work.
Network Model (cont.)
• In each time slot, CMs will be in one of the three states, listen, transmit or sleep.
Energy Consumption Model
Ecir: RF radio circuit energy consumption
ε: the amplifier energy required at the receiver
D : the distance between CM and CH
α: path loss coefficient depending on the path characteristics
l : number of slots
R-Coefficient
• The probability that sensor i only transmits for l slots on channel j due to the collision with PU:
• the statistically expected energy consumption for sensor i transmitting on channel j:
Optimization-based channel assignment
10
9
10
810
: Listen
: Sleep
: Transmit
: Listen
: Sleep
: Transmit
Conclusion
• In this paper, we study the channel assignment problem in a cluster-based multi-channel CRSN with consideration of energy consumption, residual energy balancing and network lifetime.
• The simulation results show evident improvement coming from the R-coefficient based channel assignment on both energy consumption and residual energy balance.