Wireless Sensor and Actuator Networks: Algorithms and Protocols for Scalable Coordination and Data Communication by

9.12 COORDINATED ACTUATOR MOVEMENT FOR ENERGY-EFFICIENT SENSOR REPORTING

Mobility of robots is utilized to save energy in long-term communication tasks (e.g., video monitoring) in Liu et al. (2007). In such long-term communication tasks, the traffic will be regular and large enough in volume to warrant nodes expending energy moving in order to forward traffic in a more energy-efficient manner. Given a communication request between a source-destination pair, the problem is to find an initial route between them if possible (using current robot locations), and move each node on the route to its desired final location (while maintaining the route if possible). The objective is to minimize the total transmission power of nodes for this long-term communication, while keeping low movement distances from the initial to the final positions of intermediate nodes (robots).

Suppose a source S needs to find a route to a destination D. According to Goldenberg et al. (2004), the optimal locations of relay nodes must lie evenly on the line between S and D. Theorem 9.1 shows the optimal number of hops and optimal distance of adjacent nodes on the line. Assume that the energy needed for transmitting and receiving between two nodes at distance d is proportional to d^α + c for some constant α (between 2 and 6) and c > 0. Let d(S, D) be the Euclidean distance between S and D.