2 D simulation with the FDTD method of GPR modelling applied to the detection in stratified lossy medium using the frequency effect pulse

2 D simulation with the FDTD method of GPR modelling applied to the detection in stratified lossy medium using the frequency effect pulse

In this paper we are interested in the implementation of the Yee finite-difference in time domain (FDTD) of a ground penetrating radar (GPR) model using an electromagnetic differentiated Gaussian pulse (EDGP) propagation by using the MATLAB code and taking into account the: stability criterion and t...

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Hauptverfasser: Ziani, T., Laour, M., Derobert, X., Benslama, M.
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Buried object detection
detection
disperrssive multilayer media
electromagnetic wave
Finite difference methods
Finite-difference in time domain (FDTD)
Frequency
Ground penetrating radar
ground penetrating radar (GPR)
Mathematical model
Object detection
pulse and PML
Radar detection
Slabs
Soil
Time domain analysis
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creator Ziani, T.
Laour, M.
Derobert, X.
Benslama, M.
description In this paper we are interested in the implementation of the Yee finite-difference in time domain (FDTD) of a ground penetrating radar (GPR) model using an electromagnetic differentiated Gaussian pulse (EDGP) propagation by using the MATLAB code and taking into account the: stability criterion and the perfect matched layer (PML). The source emits an (EDGP) from a free space and hits a slab which is formed by a dispersive multilayer media. Our objective is to assess the modelling and the detection of buried objects when using the (GPR) and to see the frequency effect excitation source on the medium. It is clearly shown that with the increase of the frequency, the pulse attenuation increases too. Our code, which can be used to detect metal or plastic materials in a slab like concrete or soil (with every electrical conductivity and permittivity of each layer such as used in non destructive techniques in civilian engineering) is well commented, relatively easy to understand and can be easily modified for user's specific purpose such as taking any kind of soil for detecting any kind of objects.
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The source emits an (EDGP) from a free space and hits a slab which is formed by a dispersive multilayer media. Our objective is to assess the modelling and the detection of buried objects when using the (GPR) and to see the frequency effect excitation source on the medium. It is clearly shown that with the increase of the frequency, the pulse attenuation increases too. 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subjects Buried object detection
detection
disperrssive multilayer media
electromagnetic wave
Finite difference methods
Finite-difference in time domain (FDTD)
Frequency
Ground penetrating radar
ground penetrating radar (GPR)
Mathematical model
Object detection
pulse and PML
Radar detection
Slabs
Soil
Time domain analysis
title 2 D simulation with the FDTD method of GPR modelling applied to the detection in stratified lossy medium using the frequency effect pulse
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