Abstract
Polarimetric radar systems are beneficial to identifying and classifying targets but require multiple transmit or receive channels with different polarizations. This leads to a high hardware effort and thus higher costs. To use a single, linear polarized radar sensor as a polarimetric system, a frequency-dependent, polarization rotating reflector which can be placed in front of the radar antenna is presented. The reflector is based on a frequency selective surface (FSS) consisting of slot-excited substrate integrated waveguide (SIW) resonators. Resonator modes are analyzed and an equivalent circuit diagram to describe the filter functionality is developed. For using the described FSS as reflective structure, the design focuses on 45° oblique incidence. Different field vectors for normal and oblique incident angles are considered and different cavity modes for these cases are analyzed. An undesired mode is suppressed by an additional plated through via hole and slot impedances are matched. Reflector designs for normal and oblique incident angles are presented for $15 GHz$ ( $Ku$ -band) and afterward adapted to $35 GHz$ ( $Ka$ -band). The frequency band of operation with ${12\%}$ fractional bandwidth is divided into two ${4.5\%}$ subbands which allows a frequency-dependent polarization rotation of a linear polarized electromagnetic wave. Investigations on the fabrication accuracies are presented and reflectors for both bands are manufactured. Measurements are performed with a vector network analyzer and results fit well to the simulated curves. In the band of polarization rotation reflection, the matching is better than $- 13 dB$ and dielectric losses of less than $1 dB$ are achieved.
Highlights
R ADAR systems are multidimensional measurement devices that are capable of reliably measuring distances, angles velocities, or scattering parameters
An equivalent circuit diagram (ECD) with a fifth-order filter was presented for describing the bandpass filter behavior of the unit cell
Due to the limited filter order of the introduced structure, the performance in the polarization preserving reflection band is low in terms of polarization decoupling
Summary
R ADAR systems are multidimensional measurement devices that are capable of reliably measuring distances, angles velocities, or scattering parameters. The demands on radars are constantly increasing nowadays. Examples are the need for higher resolutions, improved efficiencies, lower false alarm rates, and smaller sensor dimensions in applications. Manuscript received September 24, 2019; revised January 10, 2020; accepted May 18, 2020. Date of publication June 16, 2020; date of current version October 29, 2020. Thomas Bertuch is with AEM, Fraunhofer Institute for High Frequency Physics and Radar Techniques FHR, 53343 Wachtberg, Germany. L. Vorst are with HRA, Fraunhofer Institute for High Frequency Physics and Radar Techniques FHR, 53343 Wachtberg, Germany
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