Abstract
Coherent frequency division of high-stability optical sources permits the extraction of microwave signals with ultra-low phase noise, enabling their application to systems with stringent timing precision. To date, the highest performance systems have required tight phase stabilization of laboratory grade optical frequency combs to Fabry–Pérot optical reference cavities for faithful optical-to-microwave frequency division. This requirement limits the technology to highly controlled laboratory environments. Here, we employ a transfer oscillator technique, which employs digital and RF analog electronics to coherently suppress additive optical frequency comb noise. This relaxes the stabilization requirements and allows for the extraction of multiple independent microwave outputs from a single comb, while at the same time, permitting low-noise microwave generation from combs with higher noise profiles. Using this method, we transferred the phase stability of two high-finesse optical sources at 1157 and 1070 nm to two independent 10 GHz signals using a single frequency comb. We demonstrated absolute phase noise below −106 dBc/Hz at 1 Hz from the carrier with corresponding 1 s fractional frequency instability below 2 × 10−15. Finally, the latter phase noise levels were attainable for comb linewidths broadened up to 2 MHz, demonstrating the potential for out-of-lab use with low SWaP lasers.
Highlights
High-stability microwave sources are ubiquitous in modern technology, underpinning communication, computing, and radar and sensing systems
Photonics-based microwave generation can be separated into three distinct experimental stages: (1) the optical reference that defines a lower limit to the system stability and phase noise, (2) the phase-coherent division performed by the optical frequency comb that enables faithful transfer of the optical reference stability and phase noise to the microwave domain, and (3) the electronic detection and synthesis, which includes photodetection as a means to demodulate the optical signals, and here, a digital transfer oscillator technique that enables electronic removal of optical frequency combs (OFC) noise from the photodetected X-band microwave signals
We assess the difference in performance between optical frequency division (OFD) derived via transfer oscillator (TO)-OFD and tight phase locking (PL-OFD) and characterize the limiting sources of noise in our TO scheme
Summary
High-stability microwave sources are ubiquitous in modern technology, underpinning communication, computing, and radar and sensing systems. Most of the latter systems rely on roomtemperature crystal oscillators as local oscillators and frequency references. These commercially available electronic sources, exhibit phase noise that is unlikely to support next-generation systems that will require improved resolution and signal-to-noise ratios for higher density communications, micro-Doppler radar, and quantum sensing. Sources with lower timing jitter could increase the resolution in analog-to-digital converters.[6]
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