Sleeping on the Job: Energy-Efficient Broadcast for Radio Networks

TL;DR

This paper presents energy-efficient algorithms for reliable broadcast in radio networks, minimizing node wake-up time even under adversarial node deletions, with proven optimality bounds and extensions to Byzantine fault tolerance.

Contribution

It introduces algorithms that significantly reduce node awake time for reliable broadcast under worst-case adversarial conditions, achieving near-optimal resource usage.

Findings

Nodes can be awake for only 1/√n of the time with high reliability.

Lower bounds match the algorithms' efficiency, proving optimality.

Extensions handle Byzantine faults in energy-efficient broadcast.

Abstract

We address the problem of minimizing power consumption when performing reliable broadcast on a radio network under the following popular model. Each node in the network is located on a point in a two dimensional grid, and whenever a node sends a message, all awake nodes within distance r receive the message. In the broadcast problem, some node wants to successfully send a message to all other nodes in the network even when up to a 1/2 fraction of the nodes within every neighborhood can be deleted by an adversary. The set of deleted nodes is carefully chosen by the adversary to foil our algorithm and moreover, the set of deleted nodes may change periodically. This models worst-case behavior due to mobile nodes, static nodes losing power or simply some points in the grid being unoccupied. A trivial solution requires each node in the network to be awake roughly 1/2 the time, and a trivial lower bound shows that each node must be awake for at least a 1/n fraction of the time. Our first result is an algorithm that requires each node to be awake for only a 1/sqrt(n) fraction of the time in expectation. Our algorithm achieves this while ensuring correctness with probability 1, and keeping optimal values for other resource costs such as latency and number of messages sent. We give a lower-bound that shows that this reduction in power consumption is asymptotically optimal when latency and number of messages sent must be optimal. If we can increase the latency and messages sent by only a log*n factor we give a Las Vegas algorithm that requires each node to be awake for only a (log*n)/n expected fraction of the time; we give a lower-bound showing that this second algorithm is near optimal. Finally, we show how to ensure energy-efficient broadcast in the presence of Byzantine faults.