Coherent and Noncoherent Joint Processing of Sonar for Detection of Small Targets in Shallow Water

Pan, Xiaoyong; Jiang, Jingning; Li, Si; Ding, Zhenping; Chen, Pan; Gong, Xiaojin

doi:10.3390/s18041154

Cited by 5 publications

(3 citation statements)

References 28 publications

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“…The method uses a passive sonar system to analyze the features of AUV. Likewise, for active sonar, a coherentnoncoherent joint processing framework is proposed in [8] to detect a small target in shallow water.…”

Section: A Autonomous Underwater Vehicles (Auvs)mentioning

confidence: 99%

“…Three different types of active sonar systems are used to detect and track the target: monostatic (both transmitter and receiver are co-located), bistatic (receiver is separated from transmitter), and multi-static (one transmitter and multiple receivers). To estimate the target bearing and range with special diversity, a broadband signal model is used that has been proved in the simulation results of [8]. Passive sonar systems only provide bearing information.…”

Section: Introductionmentioning

confidence: 99%

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An Overview of Next-Generation Underwater Target Detection and Tracking: An Integrated Underwater Architecture

Ghafoor

Noh

2019

IEEE Access

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Military forces of every country are trying their best to protect their motherland from the attackers. With advancement in marine technology, it has become critical to detect and track the target by obtaining active measurements before it is close enough to attack. The utilization of unmanned underwater vehicles for target tracking behavior is gaining great attention due to continuous advancement of underwater vehicular technology. Nevertheless, safe and stable communications issues among different acoustic devices are still under active investigation to reach a robust, secure, and flexible underwater networking. Moreover, due to harsh underwater environment, acoustic simulations are also time-consuming; therefore, an accurate model for target detection and tracking is a necessity. Apart from the harsh environment of underwater networks, various technologies emerging for terrestrial networking are also becoming the part of underwater networking. For instance, cognitive acoustic networks, software-defined networks, network function virtualization, cloud computing, fog computing, and internet of underwater things; all are leading to trusted next-generation underwater networks. In this paper, we first provide a comprehensive survey of unmanned underwater vehicles and different ray tracing models essential in target detection and tracking that answers several questions regarding the current necessities of underwater networks and finally, provides a solution that opens several doors for research community to excel in this area.INDEX TERMS Internet of underwater things (IoUT), ray tracing models, underwater acoustic networks (UAN), unmanned underwater vehicles (UUV).

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Section: A Autonomous Underwater Vehicles (Auvs)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Overview of Next-Generation Underwater Target Detection and Tracking: An Integrated Underwater Architecture

Ghafoor

Noh

2019

IEEE Access

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“…Detailed descriptions about distributed sonar system can be found in Refs. [2,3,4] and “Distributed Agile Submarine Hunting (DASH)” program disclosed by the Defense Advanced Research Projects Agency (DARPA) [5]. To accurately measure the direction of arrival (DOA) of echoed signals, all sensor nodes share a highly stable reference signal.…”

Section: Introductionmentioning

confidence: 99%

Reference Phase Stabilizer for Distributed Underwater Sonar Systems

Yang

Dang

Song

et al. 2018

Sensors

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An optical fiber is a promising approach for data and clock transmission in distributed underwater sonar systems. However, synchronization is a critical challenge in distributed sonar systems, which mandates accurate clock synchronization down to a sub degree. Potential phase misalignment is caused by fiber length variations. In this paper, we propose a fiber-based phase stabilizer method to achieve accurate clock synchronization among sensor nodes. We use fiber-based feedback loop between sensor nodes and central station unit to monitor phase variations. Subsequently, we leverage phase shifters symmetrically arranged on the forward lane and feedback lane to compensate real-time phase variation and maintain high-precision synchronization. Besides, an ambiguity eliminator circuit is designed to remove the clock’s cyclic ambiguity. Both analysis and experimental results suggest that the proposed phase stabilizer can achieve 10 MHz reference clock synchronization within 0.4 degree. We also analyze the impact of the reference clock’s phase error on the system range detection accuracy, which indicates that the proposed phase stabilizer can greatly improve detection accuracy of sonar systems.

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Energy-Efficient and Reliable Deployment Models for Hybrid Underwater Acoustic Sensor Networks with a Mobile Gateway

Fedorova,

Ryzhov,

Safronov

et al. 2024

J. Marine. Sci. Appl.

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Coherent and Noncoherent Joint Processing of Sonar for Detection of Small Targets in Shallow Water

Cited by 5 publications

References 28 publications

An Overview of Next-Generation Underwater Target Detection and Tracking: An Integrated Underwater Architecture

An Overview of Next-Generation Underwater Target Detection and Tracking: An Integrated Underwater Architecture

Reference Phase Stabilizer for Distributed Underwater Sonar Systems

Energy-Efficient and Reliable Deployment Models for Hybrid Underwater Acoustic Sensor Networks with a Mobile Gateway

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