Random Subsampling and Data Preconditioning for Ground Penetrating Radars

Edison Cristofani; Mathias Becquaert; Sebastien Lambot; Marijke Vandewal; Johan H. Stiens; Nikos Deligiannis

doi:10.1109/ACCESS.2018.2831905

Random Subsampling and Data Preconditioning for Ground Penetrating Radars

Edison Cristofani
, Mathias Becquaert
, Sebastien Lambot
, Marijke Vandewal
, Johan H. Stiens
, Nikos Deligiannis

Vrije Universiteit Brussel
Université Catholique de Louvain
Interuniversitair Micro-Electronica Centrum vzw

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

8 Zitate (Scopus)

Abstract

Ground penetrating radars (GPRs) for mine detection can profit from the many advantages that compressed sensing can offer through random subsampling in terms of hardware simplification, reduced data volume and measurement time, or imagery simplification. An intrinsic antenna-ground model is used, canceling the undesired reverberation effects and the very strong reflection from the air-soil interface, producing higher detection rates, or even unmasking shallowly buried mines. Extensive Monte Carlo simulations on real GPR measurements (800-2200 MHz) show an increase in the probability of detection, yielding globally promising exploitable results, whenever the principal component analysis technique is used a as preconditioner, as well as providing lower random subsampling bounds for frequency and spatial measurements (cross range), whether applied individually or combined.

Originalsprache	Englisch
Seiten (von - bis)	26866-26880
Seitenumfang	15
Fachzeitschrift	IEEE Access
Jahrgang	6
DOIs	https://doi.org/10.1109/ACCESS.2018.2831905
Publikationsstatus	Veröffentlicht - 7 Mai 2018

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title = "Random Subsampling and Data Preconditioning for Ground Penetrating Radars",

abstract = "Ground penetrating radars (GPRs) for mine detection can profit from the many advantages that compressed sensing can offer through random subsampling in terms of hardware simplification, reduced data volume and measurement time, or imagery simplification. An intrinsic antenna-ground model is used, canceling the undesired reverberation effects and the very strong reflection from the air-soil interface, producing higher detection rates, or even unmasking shallowly buried mines. Extensive Monte Carlo simulations on real GPR measurements (800-2200 MHz) show an increase in the probability of detection, yielding globally promising exploitable results, whenever the principal component analysis technique is used a as preconditioner, as well as providing lower random subsampling bounds for frequency and spatial measurements (cross range), whether applied individually or combined.",

keywords = "Basis pursuit denoising, compressed sensing, ground penetrating radar, landmines, principal component analysis, stepped-frequency continuous-wave, synthetic aperture radar",

author = "Edison Cristofani and Mathias Becquaert and Sebastien Lambot and Marijke Vandewal and Stiens, \{Johan H.\} and Nikos Deligiannis",

note = "Publisher Copyright: {\textcopyright} 2013 IEEE.",

year = "2018",

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doi = "10.1109/ACCESS.2018.2831905",

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T1 - Random Subsampling and Data Preconditioning for Ground Penetrating Radars

AU - Cristofani, Edison

AU - Becquaert, Mathias

AU - Lambot, Sebastien

AU - Vandewal, Marijke

AU - Stiens, Johan H.

AU - Deligiannis, Nikos

PY - 2018/5/7

Y1 - 2018/5/7

N2 - Ground penetrating radars (GPRs) for mine detection can profit from the many advantages that compressed sensing can offer through random subsampling in terms of hardware simplification, reduced data volume and measurement time, or imagery simplification. An intrinsic antenna-ground model is used, canceling the undesired reverberation effects and the very strong reflection from the air-soil interface, producing higher detection rates, or even unmasking shallowly buried mines. Extensive Monte Carlo simulations on real GPR measurements (800-2200 MHz) show an increase in the probability of detection, yielding globally promising exploitable results, whenever the principal component analysis technique is used a as preconditioner, as well as providing lower random subsampling bounds for frequency and spatial measurements (cross range), whether applied individually or combined.

AB - Ground penetrating radars (GPRs) for mine detection can profit from the many advantages that compressed sensing can offer through random subsampling in terms of hardware simplification, reduced data volume and measurement time, or imagery simplification. An intrinsic antenna-ground model is used, canceling the undesired reverberation effects and the very strong reflection from the air-soil interface, producing higher detection rates, or even unmasking shallowly buried mines. Extensive Monte Carlo simulations on real GPR measurements (800-2200 MHz) show an increase in the probability of detection, yielding globally promising exploitable results, whenever the principal component analysis technique is used a as preconditioner, as well as providing lower random subsampling bounds for frequency and spatial measurements (cross range), whether applied individually or combined.

KW - Basis pursuit denoising

KW - compressed sensing

KW - ground penetrating radar

KW - landmines

KW - principal component analysis

KW - stepped-frequency continuous-wave

KW - synthetic aperture radar

UR - https://www.scopus.com/pages/publications/85046792259

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DO - 10.1109/ACCESS.2018.2831905

M3 - Article

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VL - 6

SP - 26866

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Random Subsampling and Data Preconditioning for Ground Penetrating Radars

Abstract

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