Abstract
Underwater acoustic networks are widely used in survey missions and environmental monitoring. When an underwater acoustic network (UAN) is deployed in a marine region or two UANs merge, each node hardly knows the entire network and may not have a unique node ID. Therefore, a network topology discovery protocol that can complete node discovery, link discovery, and node ID assignment are necessary and important. Considering the limited node energy and long propagation delay in UANs, it is challenging to obtain the network topology with reduced overheads and a short delay in this initial network state. In this paper, an efficient topology discovery protocol (ETDP) is proposed to achieve adaptive node ID assignment and topology discovery simultaneously. To avoiding packet collision in this initial network state, ETDP controls the transmission of topology discovery (TD) packets, based on a local timer, and divides the network into different layers to make nodes transmit TD packets orderly. Exploiting the received TD packets, each node could obtain the network topology and assign its node ID independently. Simulation results show that ETDP completes network topology discovery for all nodes in the network with significantly reduced energy consumption and short delay; meanwhile, it assigns the shortest unique IDs to all nodes with reduced overheads.
Highlights
Underwater acoustic networks (UANs) have become increasingly important, with the advancements in underwater communication technologies and their applications in environmental monitoring, exploration of the oceans, and military missions [1,2,3]
We investigate a network topology discovery protocol for UANs to address the aforementioned challenges
For the network topology discovery phase, overhead is an indicator of the protocol performance, which has a linear relationship with the energy expenditure
Summary
Underwater acoustic networks (UANs) have become increasingly important, with the advancements in underwater communication technologies and their applications in environmental monitoring, exploration of the oceans, and military missions [1,2,3]. UANs, in general, consist of various sensors and vehicles deployed underwater that are connected via acoustic links to perform collaborative tasks [4]. The network topology discovery is the first step after a UAN is deployed in a marine region because network nodes do not know who are their neighbors or who can communicate with them They cannot perform specific tasks [5,6,7]. The unique features of the underwater acoustic network bring the following key challenges to the topology discovery: (1) The delay caused in topology discovery is required to be as small as possible to ensure a fast and timely UAN establishment [19]. The dynamic topology discovery protocol for UANs is established based on a layered network model, which controls the transmission of TD packets through a random timer design; it significantly suppresses collisions in the initial network state.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
