PAMAS—power aware multi-access protocol with signalling for ad hoc networks
ACM SIGCOMM Computer Communication Review
Power consumption in packet radio networks
Theoretical Computer Science
Geography-informed energy conservation for Ad Hoc routing
Proceedings of the 7th annual international conference on Mobile computing and networking
Analysis of a cone-based distributed topology control algorithm for wireless multi-hop networks
Proceedings of the twentieth annual ACM symposium on Principles of distributed computing
LANMAR: landmark routing for large scale wireless ad hoc networks with group mobility
MobiHoc '00 Proceedings of the 1st ACM international symposium on Mobile ad hoc networking & computing
Reconsidering wireless systems with multiple radios
ACM SIGCOMM Computer Communication Review
CoolSpots: reducing the power consumption of wireless mobile devices with multiple radio interfaces
Proceedings of the 4th international conference on Mobile systems, applications and services
Self-tuning wireless network power management
Wireless Networks - Special issue: Selected papers from ACM MobiCom 2003
Minimizing energy for wireless web access with bounded slowdown
Wireless Networks
Variable-Range Transmission Power Control in Wireless Ad Hoc Networks
IEEE Transactions on Mobile Computing
Coexistence of IEEE 802.11b and bluetooth: an integrated performance analysis
Mobile Networks and Applications
Hierarchical routing in ad hoc networks using k-dominating sets
ACM SIGMOBILE Mobile Computing and Communications Review
Bluetooth and Wi-Fi wireless protocols: a survey and a comparison
IEEE Wireless Communications
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Modern mobile phones and laptops are equipped with multiple wireless communication interfaces, such as WiFi and Bluetooth (BT), enabling the creation of ad-hoc networks. These interfaces significantly differ from one another in their power requirements, transmission range, bandwidth, etc. For example, BT is an order of magnitude more power efficient than WiFi, but its transmission range is an order of magnitude shorter. This paper introduces a management middleware that establishes a power efficient overlay for such adhoc networks, in which most devices can shut down their long range power hungry wireless interface (e.g., WiFi). Yet, the resulting overlay is fully connected, and for capacity and latency needs, no message ever travels more than 2k short range (e.g., BT) hops, where k is an arbitrary parameter. The paper describes the architecture of the solution and the management protocol, as well as a detailed simulations based performance study. The simulations largely validate the ability of the management infrastructure to obtain considerable power savings while keeping the network connected and maintaining reasonable latency. The performance study covers both static and mobile networks.