Frequency-comb-steered ultrawideband quasi-true-time-delay beamformer for integrated sensing and communication

TL;DR

This paper introduces a novel frequency-comb-steered photonic quasi-TTD beamformer that achieves ultrawideband, squint-free beamforming for integrated radar and communication systems, with reduced hardware complexity and high-resolution imaging capabilities.

Contribution

It presents a new frequency-comb-steered photonic quasi-TTD beamformer that eliminates delay lines, enabling ultrawideband, squint-free beamforming with scalable hardware.

Findings

Achieved 6 GHz instantaneous bandwidth across Ku-band.

Demonstrated high-resolution radar imaging with 2.6 cm * 3.0 cm resolution.

Supported 3 Gbps high-speed communication.

Abstract

Phased array antennas (PAAs) possessing broadband beamforming capabilities are crucial for advanced radar and wireless communication systems. Nevertheless, traditional phase-shifter-based PAA beamformers frequently encounter the beam-squint issue, which substantially restricts their instantaneous bandwidth. Photonic true-time-delay (TTD) beamformers have the potential to overcome this challenge, offering ultrawide bandwidth and immunity to electromagnetic interference. However, their practical application is impeded by the high complexity, which typically involves a vast array of optical switches and delay lines. Here, we introduce a novel frequency-comb-steered photonic quasi-TTD beamformer that eliminates the need for delay lines by leveraging the concepts of frequency-diverse arrays and photonic microwave mixing arrays. This beamformer enables squint-free beamforming of ultrawideband linear frequency modulation waveforms, which is essential for high-resolution radar applications. It ensures seamless and continuous beam steering, effectively delivering infinite spatial resolution. We present a prototype with an 8-element PAA, demonstrating an instantaneous bandwidth of 6 GHz across the entire Ku-band. Additionally, we explore the system's capabilities in integrated inverse synthetic aperture radar imaging and high-speed communication, achieving a high imaging resolution of 2.6 cm * 3.0 cm and a transmission rate of 3 Gbps. Compared to conventional delay-line-based beamformers, our new concept markedly reduces hardware complexity and enhances scalability, positioning it as a potent enabler for future integrated sensing and communication applications.