A framework for multiple object tracking in underwater acoustic MIMO communication channels

Domingo Rodriguez; Cesar Aceros; Juan Valera; Edwin Anaya; Hongchi Shi; Yi Shang; Xiao Chen

doi:10.3390/jsan6010002

A framework for multiple object tracking in underwater acoustic MIMO communication channels

Domingo Rodriguez
, Cesar Aceros
, Juan Valera
, Edwin Anaya
, Hongchi Shi
, Yi Shang
, Xiao Chen

Research output: Contribution to scientific journal › Article in an indexed scientific journal › peer-review

5 Scopus citations

Abstract

This work presents a computational framework for the analysis and design of large-scale algorithms utilized in the estimation of acoustic, doubly-dispersive, randomly time-variant, underwater communication channels. Channel estimation results are used, in turn, in the proposed framework for the development of efficient high performance algorithms, based on fast Fourier transformations, for the search, detection, estimation and tracking (SDET) of underwater moving objects through acoustic wavefront signal analysis techniques associated with real-time electronic surveillance and acoustic monitoring (eSAM) operations. Particular importance is given in this work to the estimation of the range and speed of deep underwater moving objects modeled as point targets. The work demonstrates how to use Kronecker products signal algebra (KSA), a branch of finite-dimensional tensor signal algebra, as a mathematical language for the formulation of novel variants of parallel orthogonal matching pursuit (POMP) algorithms, as well as a programming aid for mapping these algorithms to large-scale computational structures, using a modified Kuck's paradigm for parallel computation.

Original language	English
Article number	2
Journal	Journal of Sensor and Actuator Networks
Volume	6
Issue number	1
DOIs	https://doi.org/10.3390/jsan6010002
State	Published - 1 Mar 2017

Bibliographical note

Publisher Copyright:
© 2017 by the authors; licensee MDPI, Basel, Switzerland.

Keywords

Acoustic signal
Delay-Doppler MIMO estimation
Kronecker products signal algebra
Kuck's paradigm
Multiple object tracking
Orthogonal matching pursuit

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10.3390/jsan6010002

Cite this

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title = "A framework for multiple object tracking in underwater acoustic MIMO communication channels",

abstract = "This work presents a computational framework for the analysis and design of large-scale algorithms utilized in the estimation of acoustic, doubly-dispersive, randomly time-variant, underwater communication channels. Channel estimation results are used, in turn, in the proposed framework for the development of efficient high performance algorithms, based on fast Fourier transformations, for the search, detection, estimation and tracking (SDET) of underwater moving objects through acoustic wavefront signal analysis techniques associated with real-time electronic surveillance and acoustic monitoring (eSAM) operations. Particular importance is given in this work to the estimation of the range and speed of deep underwater moving objects modeled as point targets. The work demonstrates how to use Kronecker products signal algebra (KSA), a branch of finite-dimensional tensor signal algebra, as a mathematical language for the formulation of novel variants of parallel orthogonal matching pursuit (POMP) algorithms, as well as a programming aid for mapping these algorithms to large-scale computational structures, using a modified Kuck's paradigm for parallel computation.",

keywords = "Acoustic signal, Delay-Doppler MIMO estimation, Kronecker products signal algebra, Kuck's paradigm, Multiple object tracking, Orthogonal matching pursuit",

author = "Domingo Rodriguez and Cesar Aceros and Juan Valera and Edwin Anaya and Hongchi Shi and Yi Shang and Xiao Chen",

note = "Publisher Copyright: {\textcopyright} 2017 by the authors; licensee MDPI, Basel, Switzerland.",

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month = mar,

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doi = "10.3390/jsan6010002",

language = "Ingl{\'e}s",

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T1 - A framework for multiple object tracking in underwater acoustic MIMO communication channels

AU - Rodriguez, Domingo

AU - Aceros, Cesar

AU - Valera, Juan

AU - Anaya, Edwin

AU - Shi, Hongchi

AU - Shang, Yi

AU - Chen, Xiao

PY - 2017/3/1

Y1 - 2017/3/1

N2 - This work presents a computational framework for the analysis and design of large-scale algorithms utilized in the estimation of acoustic, doubly-dispersive, randomly time-variant, underwater communication channels. Channel estimation results are used, in turn, in the proposed framework for the development of efficient high performance algorithms, based on fast Fourier transformations, for the search, detection, estimation and tracking (SDET) of underwater moving objects through acoustic wavefront signal analysis techniques associated with real-time electronic surveillance and acoustic monitoring (eSAM) operations. Particular importance is given in this work to the estimation of the range and speed of deep underwater moving objects modeled as point targets. The work demonstrates how to use Kronecker products signal algebra (KSA), a branch of finite-dimensional tensor signal algebra, as a mathematical language for the formulation of novel variants of parallel orthogonal matching pursuit (POMP) algorithms, as well as a programming aid for mapping these algorithms to large-scale computational structures, using a modified Kuck's paradigm for parallel computation.

AB - This work presents a computational framework for the analysis and design of large-scale algorithms utilized in the estimation of acoustic, doubly-dispersive, randomly time-variant, underwater communication channels. Channel estimation results are used, in turn, in the proposed framework for the development of efficient high performance algorithms, based on fast Fourier transformations, for the search, detection, estimation and tracking (SDET) of underwater moving objects through acoustic wavefront signal analysis techniques associated with real-time electronic surveillance and acoustic monitoring (eSAM) operations. Particular importance is given in this work to the estimation of the range and speed of deep underwater moving objects modeled as point targets. The work demonstrates how to use Kronecker products signal algebra (KSA), a branch of finite-dimensional tensor signal algebra, as a mathematical language for the formulation of novel variants of parallel orthogonal matching pursuit (POMP) algorithms, as well as a programming aid for mapping these algorithms to large-scale computational structures, using a modified Kuck's paradigm for parallel computation.

KW - Acoustic signal

KW - Delay-Doppler MIMO estimation

KW - Kronecker products signal algebra

KW - Kuck's paradigm

KW - Multiple object tracking

KW - Orthogonal matching pursuit

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U2 - 10.3390/jsan6010002

DO - 10.3390/jsan6010002

M3 - Artículo en revista científica indexada

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SN - 2224-2708

VL - 6

JO - Journal of Sensor and Actuator Networks

JF - Journal of Sensor and Actuator Networks

IS - 1

M1 - 2

ER -

A framework for multiple object tracking in underwater acoustic MIMO communication channels

Abstract

Bibliographical note

Keywords

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