In the last decade, Underwater Wireless Sensor Networks have been widely studied because of their peculiar aspects that distinguish them from common wireless terrestrial networks. Their applications range from environmental monitoring to military defense. The definition of efficient routing protocols in underwater sensor networks is a challenging topic of research because of the intrinsic characteristics of these networks, such as the need of handling the node mobility and the difficulty in balancing the energy consumed by the nodes. Depth-Based Routing protocol is an opportunistic routing protocol for Underwater Sensor Networks which provides good performance both under high and low node mobility scenarios. The main contribution of our work is presenting a novel simulator for studying Depth-Based Routing protocol and its variants as well as novel routing protocols. Our simulator is based on AquaSim-Next-Generation which is a specialized tool for studying underwater networks. With our work, we improve the state of the art of underwater routing protocol simulators by implementing, among other features, a detailed cross-layer communication and an accurate model of the operational modes of acoustic modem and their energy consumption. The simulator is open source and freely downloadable. Moreover, we propose a novel and completely distributed routing protocol, named Residual energy-Depth based routing. It takes into account the residual energy at the nodes’ batteries to select the forwarder nodes and improves the network lifetime by providing a more uniform energy consumption among them. We compare its performance with that of Depth-Based Routing protocol and a receiver-based routing protocol implementing a probabilistic opportunistic forwarding scheme.

In the last decade, underwater wireless sensor networks have been widely studied because of their peculiar aspects that distinguish them from common terrestrial wireless networks. Their applications range from environmental monitoring to military defense. The definition of efficient routing protocols in underwater sensor networks is a challenging topic of research because of the intrinsic characteristics of these networks, such as the need of handling the node mobility and the difficulty in balancing the energy consumed by the nodes. Depth-based routing protocol is an opportunistic routing protocol for underwater sensor networks, which provides good performance both under high and low node mobility scenarios. The main contribution of our work is presenting a novel simulator for studying depth-based routing protocol and its variants as well as novel routing protocols. Our simulator is based on AquaSim–Next Generation, which is a specialized tool for studying underwater networks. With our work, we improve the state of the art of underwater routing protocol simulators by implementing, among other features, a detailed cross-layer communication and an accurate model of the operational modes of acoustic modem and their energy consumption. The simulator is open source and freely downloadable. Moreover, we propose a novel and completely distributed routing protocol, named residual energy–depth-based routing. It takes into account the residual energy at the nodes' batteries to select the forwarder nodes and improve the network lifetime by providing a more uniform energy consumption among them. We compare its performance with that of depth-based routing protocol and a receiver-based routing protocol implementing a probabilistic opportunistic forwarding scheme.

Implementation of Depth-based routing and its enhancement in Aqua-Sim Next Generation for Underwater Wireless Sensor Networks

Mohsin Raza Jafri
;
Simonetta Balsamo;Andrea Marin;
2018-01-01

Abstract

In the last decade, underwater wireless sensor networks have been widely studied because of their peculiar aspects that distinguish them from common terrestrial wireless networks. Their applications range from environmental monitoring to military defense. The definition of efficient routing protocols in underwater sensor networks is a challenging topic of research because of the intrinsic characteristics of these networks, such as the need of handling the node mobility and the difficulty in balancing the energy consumed by the nodes. Depth-based routing protocol is an opportunistic routing protocol for underwater sensor networks, which provides good performance both under high and low node mobility scenarios. The main contribution of our work is presenting a novel simulator for studying depth-based routing protocol and its variants as well as novel routing protocols. Our simulator is based on AquaSim–Next Generation, which is a specialized tool for studying underwater networks. With our work, we improve the state of the art of underwater routing protocol simulators by implementing, among other features, a detailed cross-layer communication and an accurate model of the operational modes of acoustic modem and their energy consumption. The simulator is open source and freely downloadable. Moreover, we propose a novel and completely distributed routing protocol, named residual energy–depth-based routing. It takes into account the residual energy at the nodes' batteries to select the forwarder nodes and improve the network lifetime by providing a more uniform energy consumption among them. We compare its performance with that of depth-based routing protocol and a receiver-based routing protocol implementing a probabilistic opportunistic forwarding scheme.
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Descrizione: Implementation of depth‐based routing and its enhancement in AquaSim–Next Generation for underwater wireless sensor networks
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10278/3700617
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