Photonics-based de-chirping and leakage cancellation for frequency-modulated continuous-wave radar system

TL;DR

This paper presents a photonics-based method using a dual-drive Mach-Zehnder modulator for effective leakage cancellation and de-chirping in FMCW radar systems, significantly improving imaging clarity and measurement accuracy.

Contribution

It introduces a novel optical leakage cancellation and de-chirping technique using a DD-MZM, enhancing radar performance by reducing leakage interference.

Findings

Leakage cancellation depth of around 23 dB achieved.

Significant improvement in radar imaging clarity.

Distance measurement error reduced to 10 cm.

Abstract

A photonics-based leakage cancellation and echo signal de-chirping approach for frequency-modulated continuous-wave radar systems is proposed based on a dual-drive Mach-Zehnder modulator (DD-MZM), with its performance evaluated by the radar measurement and imaging. The de-chirp reference signal and the leakage cancellation reference signal are combined and applied to the upper arm of the DD-MZM, while the received signal including the leakage signal and echo signals is applied to the lower arm of the DD-MZM. When the amplitudes and delays of the leakage cancellation reference signal and the leakage signal are precisely matched and the DD-MZM is biased at the minimum transmission point, the leakage signal is canceled in the optical domain. The de-chirped signals are obtained after the leakage-free optical signal is detected in a photodetector. An experiment is performed. The cancellation depth of the de-chirped leakage signal is around 23 dB when the center frequency and bandwidth of the linearly frequency-modulated signal are 11.5 and 2 GHz. The leakage cancellation scheme is used in a radar system. When the leakage cancellation is not employed, the leakage signal will seriously affect the imaging results and distance measurement accuracy of the radar system. When the leakage cancellation is applied, the imaging results of multiple targets can be clearly distinguished, and the error of the distance measurement results is significantly reduced to 10 cm.