Abstract
Ultra-high resolution (UHR) radar imaging is used to analyze the internal structure of objects and to identify and classify their shapes based on ultra-wideband (UWB) signals using a vector network analyzer (VNA). However, radar-based imaging is limited by microwave propagation effects, wave scattering, and transmit power, thus the received signals are inevitably weak and noisy. To overcome this problem, the radar may be operated in the near-field. The focusing of UHR radar signals over a close distance requires precise geometry in order to accommodate the spherical waves. In this paper, a geometric estimation and compensation method that is based on the minimum entropy of radar images with sub-centimeter resolution is proposed and implemented. Inverse synthetic aperture radar (ISAR) imaging is used because it is applicable to several fields, including medical- and security-related applications, and high quality images of various targets have been produced to verify the proposed method. For ISAR in the near-field, the compensation for the time delay depends on the distance from the center of rotation and the internal RF circuits and cables. Required parameters for the delay compensation algorithm that can be used to minimize the entropy of the radar images are determined so that acceptable results can be achieved. The processing speed can be enhanced by performing the calculations in the time domain without the phase values, which are removed after upsampling. For comparison, the parameters are also estimated by performing random sampling in the data set. Although the reduced data set contained only 5% of the observed angles, the parameter optimization method is shown to operate correctly.
Highlights
Electromagnetic wave-based imaging is used in a variety of fields, such as medical- and security-related applications [1]
This method is used to identify or recognize a target based on ultra-high resolution (UHR) radar images
This study suggests a geometric calibration approach for radar images based on the experimental data received in the close-range
Summary
Electromagnetic wave-based imaging is used in a variety of fields, such as medical- and security-related applications [1]. The images are produced by very weak signals due to the limited microwave transmit power, wave scattering, and propagation characteristics To overcome these limitations, ISAR is often used at a close distance [7,8]. This paper presents a method for obtaining radar images by calculating and correcting the precise non–plane geometry based on the received data. A method of minimum entropy based on contrast optimization is used In this method, it is necessary to estimate both the propagation time and the RF component delays. Contrast-based autofocusing is precise, but it has a heavy computational cost [20] and the contrast optimization requires imaging of each distance between the antenna and the center of rotation. The sparse sampling method and the results will be discussed
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