Abstract
Neighbor discovery is a fundamental function for sensor networking. Sensor nodes discover each other by sending and receiving beacons. Although many time-slotted neighbor discovery protocols (NDPs) have been proposed, the theoretical discovery latency is measured by the number of time slots rather than the unit of time. Generally, the actual discovery latency of a NDP is proportional to its theoretical discovery latency and slot length, and inversely proportional to the discovery probability. Therefore, it is desired to increase discovery probability while reducing slot length. This task, however, is challenging because the slot length and the discovery probability are two conflicting factors, and they mainly depend on the beaconing strategy used. In this paper, we propose a new beaconing strategy, called talk-listen-ack beaconing (TLA). We analyze the discovery probability of TLA by using a fine-grained slot model. Further, we also analyze the discovery probability of TLA that uses random backoff mechanism to avoid persistent collisions. Simulation and experimental results show that, compared with the 2-Beacon approach that has been widely used in time-slotted NDPs, TLA can achieve a high discovery probability even in a short time slot. TLA is a generic beaconing strategy that can be applied to different slotted NDPs to reduce their discovery latency.
Highlights
Recent years have witnessed a large variety applications of wireless sensor networks in industrial Internet of Things, environmental monitoring and protection, smart agriculture, and smart city
With the same goal of improving the actual discovery latency as the works [21,22,24], we study the beaconing strategy that can achieve a better tradeoff between the discovery probability and the slot length
It cannot determine the theoretical performance of a neighbor discovery protocols (NDPs) (i.e., N), the beaconing strategy has a significant impact on the actual performance of the NDP by changing the discovery probability (i.e., P) and the slot length. 2-Beacon integrates beacon sending and receiving into an active time slot
Summary
Recent years have witnessed a large variety applications of wireless sensor networks in industrial Internet of Things, environmental monitoring and protection, smart agriculture, and smart city. In all these applications, neighbor discovery [1] is a fundamental function for sensor networking, because the knowledge of neighboring nodes is the prerequisite for link establishment, routing, and network communication. Sensor nodes are typically low-cost and battery-powered devices They cannot always turn on the radio to communicate with other nodes, because the battery cannot be replaced in most applications. The neighbor discovery protocol (NDP) designed for wireless sensor networks should take duty cycle, mobility, and asynchronous information into account [1]
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