Abstract
An output arm is the first subsystem in the microwave components chain connected immediately after the power amplifier. These arms are responsible for transferring the signal from the output port of the power amplifier to the standard line of the system. The second objective is to obtain directive samples for both forward and backward signals. The typical design process for such a subsystem is carried out through the design of separate components, independently. This limits the achievable performance of the entire system and introduces excessive losses at intermediate flanges. In this work, we present a novel approach to design such a subsystem using a global optimization procedure. Specifically, we address both compactness and full-band operation of output arms deployed in radar applications. Analysis and design of each component in the proposed subsystem are illustrated. The presented subsystem achieves a deep matching level of 19 dB within an overall length below $2\lambda _{g}$ . Moreover, the directive sample obtained through the presented design has an ultra-flat response of 20 dB ± 0.5 dB over the entire band of operation, while the directivity of the samples exceeds 18 dB. The measured results of the fabricated prototype have an excellent agreement with the simulations.
Highlights
A mong all microwave subsystems, the output arms have significant importance
The major specifications of output arms are the deep matching provided by the adapter, the flat coupling, and the high directivity extracted through the coupler [6], [7]
OUTPUT ARM SPECIFICATIONS The design objective of this work is to provide an output arm for radar applications working in the extended S-band
Summary
A mong all microwave subsystems, the output arms have significant importance. These arms are connected directly to the power source to provide a standard interface [1], [2]. The major specifications of output arms are the deep matching provided by the adapter, the flat coupling, and the high directivity extracted through the coupler [6], [7] These major characteristics have to be satisfied over the full band of operation. The end-launch type is more convenient for the system installation as it ensures the alignment between the power source and the rest of the system This configuration is more difficult in achieving the electrical specifications in terms of the matching level and the wide operating bandwidth. We present a complete subsystem incorporating both an end-launch adapter and a loop coupler in one unit With this configuration, we eliminate inter-flange reflections and provide optimized overall performance.
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