TY - GEN
T1 - CACA
T2 - 36th IEEE International Conference on Distributed Computing Systems, ICDCS 2016
AU - Jun, Junghyun
AU - Yeon, Solchan
AU - Kundu, Titir
AU - Agrawal, Dharma P.
AU - Jeong, Jaehoon
N1 - Publisher Copyright:
© 2016 IEEE.
PY - 2016/8/8
Y1 - 2016/8/8
N2 - In this paper, we exploit the capture-effect for channel allocation. We experimentally show the characteristics of capture-effect across different channels, over time, and in different network densities. Then, we introduce CACA, an effective channel assignment protocol for wireless sensor networks. Traditional channel assignment protocols utilize all available channels to minimize interferences between any adjacent links. However, their performances are often not much better than the case of using single channel only. This is mainly due to an assumption that all channels are independent and quality of all channels are similar. However, this is a false assumption. In fact, there are only a few channels that show very good quality at any given time. The CACA avoids this problem by utilizing a few good channels and reuse these channels. When the channels are reused it relies on the capture-effect to ensure at least one of the contending nodes to transmit successfully. Maximizing this capture probability is a main objective of the CACA whenever the channels need to be reused. We evaluate the CACA on a 140-node wireless sensor network testbed and compare its performance with another benchmark protocol. Our results indicate that the CACA can improve the packet reception ratio of every link. As a result of this improvement, end-to-end throughput increases upto 100% in the case of a wireless sensor network with bursty traffic.
AB - In this paper, we exploit the capture-effect for channel allocation. We experimentally show the characteristics of capture-effect across different channels, over time, and in different network densities. Then, we introduce CACA, an effective channel assignment protocol for wireless sensor networks. Traditional channel assignment protocols utilize all available channels to minimize interferences between any adjacent links. However, their performances are often not much better than the case of using single channel only. This is mainly due to an assumption that all channels are independent and quality of all channels are similar. However, this is a false assumption. In fact, there are only a few channels that show very good quality at any given time. The CACA avoids this problem by utilizing a few good channels and reuse these channels. When the channels are reused it relies on the capture-effect to ensure at least one of the contending nodes to transmit successfully. Maximizing this capture probability is a main objective of the CACA whenever the channels need to be reused. We evaluate the CACA on a 140-node wireless sensor network testbed and compare its performance with another benchmark protocol. Our results indicate that the CACA can improve the packet reception ratio of every link. As a result of this improvement, end-to-end throughput increases upto 100% in the case of a wireless sensor network with bursty traffic.
KW - capture-effect
KW - channel diversity
KW - wireless sensor network
UR - https://www.scopus.com/pages/publications/84985995862
U2 - 10.1109/ICDCS.2016.65
DO - 10.1109/ICDCS.2016.65
M3 - Conference contribution
AN - SCOPUS:84985995862
T3 - Proceedings - International Conference on Distributed Computing Systems
SP - 600
EP - 608
BT - Proceedings - 2016 IEEE 36th International Conference on Distributed Computing Systems, ICDCS 2016
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 27 June 2016 through 30 June 2016
ER -