Proceedings of the 12th annual international conference on Mobile computing and networking
Local solutions for global problems in wireless networks
Journal of Discrete Algorithms
Energy-efficient geographic multicast routing for Sensor and Actuator Networks
Computer Communications
Hierarchical geographic multicast routing for wireless sensor networks
Wireless Networks
Localized mobility control routing in robotic sensor wireless networks
MSN'07 Proceedings of the 3rd international conference on Mobile ad-hoc and sensor networks
An intelligent agent for fault reconnaissance in sensor networks
Proceedings of the 11th International Conference on Information Integration and Web-based Applications & Services
Fault reconnaissance agent for sensor networks
Mobile Information Systems
From real neighbors to imaginary destination: emulation of large scale wireless sensor networks
ADHOC-NOW'12 Proceedings of the 11th international conference on Ad-hoc, Mobile, and Wireless Networks
Mesh-based sensor relocation for coverage maintenance in mobile sensor networks
UIC'07 Proceedings of the 4th international conference on Ubiquitous Intelligence and Computing
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We present a simple framework for designing network layer protocols for sensor networks including localized routing, broadcasting, area coverage, and so on. The framework is general enough and is applicable to a variety of problems, network assumptions, and optimality criteria. Our simple framework is based on optimizing the ratio of the cost of making certain decisions (e.g., selecting a forwarding neighbor for routing) to the progress made in doing so (e.g., reduction in distance to destination). We show how to apply this general guideline for the design of hop count, power awareness, maximal lifetime, beaconless and physical-layer-based routing, minimal energy broadcasting, sensor area coverage, and multicasting protocols. Moreover, we show that in the case of routing, the best known strictly localized position-based techniques are, in almost all cases, special cases of the described general cost-to-progress ratio paradigm