C
Chenyang Lu
Researcher at Washington University in St. Louis
Publications - 334
Citations - 20342
Chenyang Lu is an academic researcher from Washington University in St. Louis. The author has contributed to research in topics: Wireless sensor network & Scheduling (computing). The author has an hindex of 65, co-authored 309 publications receiving 18996 citations. Previous affiliations of Chenyang Lu include Vanderbilt University & University of Virginia.
Papers
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Proceedings ArticleDOI
Integrated coverage and connectivity configuration in wireless sensor networks
TL;DR: The design and analysis of novel protocols that can dynamically configure a network to achieve guaranteed degrees of Coverage Configuration Protocol (CCP) and integrate SPAN to provide both coverage and connectivity guarantees are presented.
Proceedings ArticleDOI
SPEED: a stateless protocol for real-time communication in sensor networks
TL;DR: SPEED is a highly efficient and scalable protocol for sensor networks where the resources of each node are scarce, and specifically tailored to be a stateless, localized algorithm with minimal control overhead.
Journal ArticleDOI
Wireless Sensor Networks for Healthcare
TL;DR: This review presents representative applications in the healthcare domain and describes the challenges they introduce to wireless sensor networks due to the required level of trustworthiness and the need to ensure the privacy and security of medical data.
Journal ArticleDOI
Feedback Control Real-Time Scheduling: Framework, Modeling, and Algorithms*
TL;DR: Performance evaluation results demonstrate that the analytically tuned FCS algorithms provide robust transient and steady state performance guarantees for periodic and aperiodic tasks even when the task execution times vary by as much as 100% from the initial estimate.
Journal ArticleDOI
Integrated coverage and connectivity configuration for energy conservation in sensor networks
TL;DR: The design and analysis of novel protocols that can dynamically configure a network to achieve guaranteed degrees of coverage and connectivity and demonstrate the capability of these protocols to provide guaranteed Coverage Configuration Protocol configurations through both geometric analysis and extensive simulations are presented.