Estimate of Passive Time Reversal Communication Performance in Shallow Water

Kim, Sunhyo; Son, Su-Uk; Kim, Hyeonsu; Choi, Kang‐Hoon; Choi, Jee Woong

doi:10.3390/app8010023

Cited by 5 publications

(3 citation statements)

References 26 publications

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“…Time-reversal processes represent a scheme to generate a spatio-temporal focus at a source location by transmitting a time-reversed version of a received signal, reducing inter-symbol interference at the receiver, and improving communication performance, in the harsh environment characterized by significant multipath channels. Time-reversal beamforming is a well-known approach in practice, and Kim et al proposed in [10] a passive time-reversal communication system for shallow water applications. Specifically, they introduced a new measure Eq of an estimate of how much of the q-function lies within one symbol duration, where the q-function is estimated by a sum of the autocorrelation of the channel impulse response for each channel in the receiver array.…”

Section: Underwater Acoustic Communication Systemsmentioning

confidence: 99%

Editorial for Special Issue: Underwater Acoustics, Communications, and Information Processing

et al. 2019

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Section: Underwater Acoustic Communication Systemsmentioning

confidence: 99%

Editorial for Special Issue: Underwater Acoustics, Communications, and Information Processing

et al. 2019

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“…The need for system identification in engineering is interesting [12], because of its ability to describe phenomena, which are not able to be fully explained by analytic approaches in complex problems. Fitting a transfer function (TF) or complex impulse response (CIR) is often used in modern wireless communications in order to characterize wireless channels [13]-citeR16. The advantage of such a response is to improve the performance of the channel with monitoring the transient responses of the system to various input signals over time-efficient signal processing operations.…”

Section: Introductionmentioning

confidence: 99%

Terahertz Waveguide-Based Pulse-Shaper System Analysis and Modeling

Razavizadeh¹,

Sadeghzadeh²,

Kashani³

2021

Preprint

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In this paper, the transfer function of a passive waveguide-based terahertz pulse shaper is achieved using the time domain data provided by the full-wave simulation of the structure. The fractional order of the transfer function is determined based on the time response resulting from an arbitrary excitation of the proposed pulse shaper. The full-wave electromagnetic numerical analyses are applied to attain the time-domain output data of the helical gold-ribbon dielectric-lined waveguide as the terahertz pulse shaper. In order to verify the simulation results, the proposed device has been examined using two different numerical methods which are the Finite Element Method (FEM) and the Finite Integral Technique (FIT). A good agreement was found between the results of FIT and FEM methods. The use of the system transfer function to analyze the structure is preferable to the full-wave simulation because of saving the execution time. Once the transfer function is determined, one could apply it for the subsequent time-domain analysis of the pulse shaper with various inputs.

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“…ISI causes issues related to communication demodulation. In addition, underwater communication is characterized by a time-varying channel, which produces large Doppler spreading and a short coherence time [9,10,11]. In addition, marine organisms such as barnacles and algae might build up on a transducer as time goes on, which can block the communication signals, causing data corruption.…”

Section: Introductionmentioning

confidence: 99%

Optimal Deployment of Vector Sensor Nodes in Underwater Acoustic Sensor Networks

Kim

Choi

2019

Sensors

Self Cite

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Underwater acoustic sensor networks have recently attracted considerable attention as demands on the Internet of Underwater Things (IoUT) increase. In terms of efficiency, it is important to achieve the maximum communication coverage using a limited number of sensor nodes while maintaining communication connectivity. In 2017, Kim and Choi proposed a new deployment algorithm using the communication performance surface, which is a geospatial information map representing the underwater acoustic communication performance of a targeted underwater area. In that work, each sensor node was a vertically separated hydrophone array, which measures acoustic pressure (a scalar quantity). Although an array receiver is an effective system to eliminate inter-symbol interference caused by multipath channel impulse responses in underwater communication environments, a large-scale receiver system degrades the spatial efficiency. In this paper, single-vector sensors measuring the particle velocity are used as underwater sensor nodes. A single-vector sensor can be considered to be a single-input multiple-output communication system because it measures the three directional components of particle velocity. Our simulation results show that the optimal deployment obtained using single-vector sensor nodes is more effective than that obtained using a hydrophone (three-channel vertical-pressure sensor) array.

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Estimate of Passive Time Reversal Communication Performance in Shallow Water

Cited by 5 publications

References 26 publications

Editorial for Special Issue: Underwater Acoustics, Communications, and Information Processing

Editorial for Special Issue: Underwater Acoustics, Communications, and Information Processing

Terahertz Waveguide-Based Pulse-Shaper System Analysis and Modeling

Optimal Deployment of Vector Sensor Nodes in Underwater Acoustic Sensor Networks

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