Sleeping Beauty: Efficient Communication for Node Scheduling

Chayan Sarkar, R. Venkatesha Prasad, Raj Thilak Rajan, and Koen Langendoen, "Sleeping Beauty: Efficient Communication for Node Scheduling", 13th International Conference on Mobile Ad Hoc and Sensor Systems (MASS), IEEE, 2016.


Typical Wireless Sensor Networks (WSN) deployments use more nodes than needed to accurately sense the phenomena of interest. This redundancy can be leveraged by switching-on only a subset of nodes at any time instant (node-scheduling) and putting the remaining nodes sleep. This effectively extends the network lifetime. In addition to sensing coverage, node-scheduling schemes must also ensure that (i) the network stays connected, and (ii) the time needed to wake-up the complete protocol stack after sleeping is minimized. We present Sleeping Beauty, a highly-efficient data collection protocol that aids node-scheduling schemes in both aspects.
     Sleeping Beauty uses a slotted and tightly synchronized communication primitive, where a node keeps its radio off for most of the time, except in the slots when it needs to participate for successful communication. Further, an efficient neighbor-discovery mechanism is included that provides partial, but sufficient topology information (potential parents) to avoid network partitions. Furthermore, Sleeping Beauty employs a novel, yet simple clock-offset estimation technique that maintains highly-accurate time synchronization over long radio-off periods (i.e., less than 500 us deviation even after 45 min of sleeping). This minimizes time wasted in resynchronizing the network in between data collection rounds. Through experiments on two different testbeds, we verified that Sleeping Beauty decreases the duty cycle up to a factor of 3 compared to state-of-the-art techniques, while achieving similar delivery ratios.

BibTex entry

    title={Sleeping Beauty: Efficient Communication for Node Scheduling},
    author={Sarkar, Chayan and Venkatesha Prasad, R and Rajan, Raj Thilak and Langendoen, Koen},
    booktitle={Mobile Ad Hoc and Sensor Systems (MASS), 2016 IEEE 13th International Conference on},