Abstract
Abstract Non-destructive evaluation of multilayer media represents an electromagnetic inverse problem, usually solved with analysis techniques in the time and frequency domains. The time- domain analysis technique depends directly on the accurate detection of reflected peaks measured by ground-penetrating radar (GPR), which limits this technique when the reflected pulses overlap with each other or the transmitted signal. Therefore, this paper presents a new practical methodology to obtain the antenna design requirements (operating frequency and temporal response) that avoid overlapping reflected pulses. The major finding is that the proposed methodology enables the production of specific antennas for the analyzed homogeneous and low-loss dielectric multilayer problem, serving as a practical guide for GPR antenna design. A typical pavement example is analyzed to apply the methodology, and, as a result, an ultra-wideband (UWB) directive antenna with tolerable dispersion is obtained according to the design specifications. Finally, the antenna simulations were compared and validated with measurements.
Highlights
Nondestructive testing (NDT) techniques have emerged with the intention of examining any object, material, or system without affecting its future utility
PROPOSED METHODOLOGY As was pointed out in the introduction, the antenna design is dependent on the ground penetrating radar (GPR) operating frequency, which in turn depends on the type of analyzed multilayer structure and the inquiring signal
Simulation of antenna performance The new antenna geometry was simulated in High-Frequency Structure Simulator (HFSS) where the microstrip line, patch, arms, ground, and reflector plane were modeled as perfect electric conductors (PECs), and a port was connected to the microstrip line as the feed
Summary
Nondestructive testing (NDT) techniques have emerged with the intention of examining any object, material, or system without affecting its future utility. The GPR technique represents a faster alternative to assess the interior of different structures and contributes to their preservation. GPR detects the reflections originating from electromagnetic discontinuities on the structure In this way, the information obtained by GPR can be used to determine the characteristics of each layer, e.g. thickness and relative electric permittivity. The information obtained by GPR can be used to determine the characteristics of each layer, e.g. thickness and relative electric permittivity This process represents an inverse electromagnetic problem that can be solved using two broad approaches: analysis techniques in the frequency and time domains [6]. Brazilian Microwave and Optoelectronics Society-SBMO received 14 June 2019; for review 19 June 2019; accepted 18 Feb 2020
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