Large-scale photonic chip based pulse interleaver for low-noise microwave generation

TL;DR

This paper presents a large-scale photonic integrated circuit interleaver that significantly enhances low-noise microwave generation by increasing repetition rate and power while reducing size and phase noise.

Contribution

It introduces a compact, stable, all-on-chip photonic interleaver achieving 64-fold repetition rate multiplication and improved microwave signal quality, surpassing fiber-based methods.

Findings

64-fold repetition rate increase from 216 MHz to 14 GHz

Microwave power improved by 36 dB

Phase noise floor reduced to -160 dBc/Hz

Abstract

Microwaves generated by optical techniques have demonstrated unprecedentedly low noise and hold significance in various applications such as communication, radar, instrumentation, and metrology. To date, the purest microwave signals are generated using optical frequency division with femtosecond mode-locked lasers. However, many femtosecond laser combs have a radio frequency (RF) repetition rate in the hundreds of megahertz range, necessitating methods to translate the generated low-noise RF signal to the microwave domain. Benchtop pulse interleavers can multiply the pulse repetition rate, avoid saturation of photodetectors, and facilitate the generation of high-power low-noise microwave signals, which have to date only been demonstrated using optical fibers or free space optics. Here, we introduce a large-scale photonic integrated circuit-based interleaver, offering size reduction and enhanced stability. The all-on-chip interleaver attains a 64-fold multiplication of the repetition rate, directly translated from 216 MHz to 14 GHz in microwave Ku-Band. By overcoming photodetector saturation, the generated microwave power was improved by 36 dB, with a phase noise floor reduced by more than 10 folds to -160 dBc/Hz on the 14 GHz carrier. The device is based on a low-loss and high-density photonic integrated circuit fabricated by the photonic Damascene process. Six cascaded stages of Mach-Zehnder interferometers with optical delay lines up to 33 centimeters long are fully integrated into a compact footprint of 8.5 mmx1.7 mm. The lithographically defined precision of the optical waveguide path length enables the scaling up of the interleaved frequency to millimeter-wave bands, which is challenging the fiber-based counterparts. This interleaver has the potential to reduce the cost and footprint of mode-locked-laser-based microwave generation, allowing for field deployment.