# A Low-Cost Two-Dimensional Scalable Active Receive Phased Array with 8 Simultaneously Reconfigurable Beams

**Authors:** Haifu Zhang, Li-Xin Guo, Shubo Dun, Xiaoming Li, Wei Mei, Xiaolong Xu, Dinuo Bu

PMC · DOI: 10.3390/mi17030348 · Micromachines · 2026-03-12

## TL;DR

This paper introduces a cost-effective, scalable phased array system that can generate eight reconfigurable beams for improved signal reception in the 10.7–12.7 GHz range.

## Contribution

The paper presents a novel phased array architecture using full-aperture multiplexing and heterogeneous integration for compact, scalable, and cost-effective multi-beam systems.

## Key findings

- The prototype achieved a 30% reduction in array footprint while maintaining system performance.
- The array gain reduction was no more than 4 dB at a 60° scanning angle.
- All beams had a G/T value of at least 0.9 dB/K at 11.7 GHz in the boresight direction.

## Abstract

This paper presents a compact multi-beam dual-circularly polarized phased array receiving system operating in the 10.7–12.7 GHz frequency band is designed and implemented, which can generate eight reconfigurable receiving beams with independently configurable polarization modes and scanning directions for each beam. To improve the aperture utilization efficiency of the array and reduce the array size, the proposed phased array architecture adopts a “full-aperture multiplexing” beamforming method, where all beams share the same array aperture. For cost-effective phased array architecture with two-dimensional scalability, the array is divided into several identical receiving subarrays, with the control and power supply modules arranged beneath the array aperture. In addition, a heterogeneous integration scheme is introduced to realize high-density integration of various receiving functional chips, which reduces the overall array footprint by approximately 30% while maintaining the basic performance of the system gain-to-noise-temperature ratio (G/T). Meanwhile, different dielectric substrates are adopted to implement multi-level combining networks, optimizing the trade-off between overall efficiency and cost. To verify the feasibility of the proposed architecture, a prototype with a 16 × 16 array configuration is developed and tested. The measured results show that the array gain reduction is no more than 4 dB at a maximum scanning angle of 60°, and the G/T value of all beams in the boresight direction is not less than 0.9 dB/K at 11.7 GHz. The experimental results validate the effectiveness of the proposed multi-beam dual-circularly polarized phased array architecture in terms of engineering implementation and system performance.

## Full text

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## Figures

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## References

33 references — full list in the complete paper: https://tomesphere.com/paper/PMC13028748/full.md

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Source: https://tomesphere.com/paper/PMC13028748