A mmWave Transmitting Time Modulated Array Using Bespoke GaAs Integrated Circuits—Prototype Design and Laboratory Trials at 73 GHz

IF 3.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Open Journal of Antennas and Propagation Pub Date : 2024-10-16 DOI:10.1109/OJAP.2024.3481991

Edward A. Ball;Sumin David Joseph

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Abstract

The prototype design and testing of an E band mmWave Time Modulated Array (TMA) is presented. The PCB based array has a 3 dB RF bandwidth of 71-73 GHz and a peak gain of −2 dBi on the first harmonic steered beam. The TMA second harmonic beam gain is within 0.9 dB of a conventional phase-shifter based array, in a like-for-like theoretical comparison. An array gain of +11.5 dBi is predicted for a full on-chip implementation. Good agreement between theoretical and prototype measured gains and array patterns are reported. Beam steering and phase correction are implemented using an FPGA, requiring only 2 digital lines per array element. A dedicated, bespoke GaAs mmWave Monolithic Integrated Circuit (MMIC) to realize the TMA is presented. A key feature of the MMIC is a sub 400 ps phase inversion switch. The MMICs provide a measured average gain of 4.4 dB and draw 61.2 mW. The TMA is demonstrated steering the first harmonic beam to +/−12 degrees and the second harmonic beam to +/−30 degrees. The maxim steer possible is +/−16 degrees for the first and +/−35 degrees for the second harmonic beams. The full hardware demonstrator platform is presented and laboratory measurements provided, confirming good operation of the array compared to theory. Our work is the first demonstration of a steerable TX TMA operating in E band.

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使用定制GaAs集成电路的毫米波发射时间调制阵列- 73 GHz的原型设计和实验室试验

介绍了一种E波段毫米波时间调制阵列（TMA）的原型设计和测试。基于PCB的阵列具有71-73 GHz的3db射频带宽和−2 dBi的一谐波操纵波束峰值增益。在类似的理论比较中，TMA二次谐波波束增益与传统的移相器阵列相比在0.9 dB以内。对于全片上实现，预计阵列增益为+11.5 dBi。据报道，理论和原型测量的增益和阵列模式之间的一致性很好。波束控制和相位校正使用FPGA实现，每个阵列元件只需要2条数字线。提出了一种专用的定制GaAs毫米波单片集成电路（MMIC）来实现TMA。MMIC的一个关键特征是一个低于400ps的相位反转开关。mmic的测量平均增益为4.4 dB，功耗为61.2 mW。演示了TMA将第一谐波波束转向+/−12度，将第二谐波波束转向+/−30度。第一次谐波光束的最大可能转向为+/ - 16度，第二次谐波光束的最大可能转向为+/ - 35度。给出了完整的硬件演示平台，并提供了实验室测量，与理论相比，证实了阵列的良好运行。我们的工作是在E波段操作的可操纵TX TMA的首次演示。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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