TY - JOUR
T1 - RAP
T2 - 8th IEEE Real-Time and Embedded Technology and Applications Symposium, RTAS 2002
AU - Lu, Chenyang
AU - Blum, Brian M.
AU - Abdelzaher, Tarek F.
AU - Stankovic, John A.
AU - He, Tian
PY - 2002
Y1 - 2002
N2 - Large-scale wireless sensor networks represent a new generation of real-time embedded systems with significantly different communication constraints from traditional networked systems. This paper presents RAP, a new real-time communication architecture for large-scale sensor networks. RAP provides convenient, high-level query and event services for distributed micro-sensing applications. Novel location-addressed communication models are supported by a scalable and light-weight network stack. We present and evaluate a new packet scheduling policy called velocity monotonic scheduling that inherently accounts for both time and distance constraints. We show that this policy is particularly suitable for communication scheduling in sensor networks in which a large number of wireless devices are seamlessly integrated into a physical space to perform real-time monitoring and control. Detailed simulations of representative sensor network environments demonstrate that RAP significantly reduces the end-to-end deadline miss ratio in the sensor network.
AB - Large-scale wireless sensor networks represent a new generation of real-time embedded systems with significantly different communication constraints from traditional networked systems. This paper presents RAP, a new real-time communication architecture for large-scale sensor networks. RAP provides convenient, high-level query and event services for distributed micro-sensing applications. Novel location-addressed communication models are supported by a scalable and light-weight network stack. We present and evaluate a new packet scheduling policy called velocity monotonic scheduling that inherently accounts for both time and distance constraints. We show that this policy is particularly suitable for communication scheduling in sensor networks in which a large number of wireless devices are seamlessly integrated into a physical space to perform real-time monitoring and control. Detailed simulations of representative sensor network environments demonstrate that RAP significantly reduces the end-to-end deadline miss ratio in the sensor network.
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U2 - 10.1109/RTTAS.2002.1137381
DO - 10.1109/RTTAS.2002.1137381
M3 - Conference article
AN - SCOPUS:84884315660
SN - 1080-1812
SP - 55
EP - 66
JO - Real-Time Technology and Applications - Proceedings
JF - Real-Time Technology and Applications - Proceedings
M1 - 1137381
Y2 - 25 September 2002 through 27 September 2002
ER -