Redefining the limits of real-time noise cancellation in optical fiber links

TL;DR

This paper demonstrates that the traditional limit on real-time noise cancellation in optical fiber links can be surpassed by exploiting temporal correlations, leading to significantly improved noise suppression in practical applications.

Contribution

The authors develop a new framework that optimizes noise cancellation by considering temporal correlations, enabling surpassing the standard noise suppression limit without additional hardware.

Findings

Achieved approximately 6 dB noise suppression beyond the standard limit in an urban fiber link.

Demonstrated over 10 dB noise suppression beyond the standard limit in a lab testbed for certain noise distributions.

The new method requires only digital signal processing, compatible with existing systems.

Abstract

A broad and growing array of applications rely on the faithful transmission of ultrastable optical signals over noisy paths, requiring cancellation of environmentally induced noise. A generally accepted limit constrains how well the path length noise can be suppressed in real time. Here, we show that this standard limit is not fundamental and can be improved upon. By considering the temporal correlations between the round-trip and one-way signals, we develop a new framework for optimizing the noise cancellation feedback signal for any spatial distribution of noise along the signal path. We use this framework to surpass the standard limit in two sets of experiments. First, we demonstrate noise cancellation in a deployed urban optical fiber, where we achieve noise suppression approximately 6 dB beyond the standard limit. Then, in a reconfigurable lab-based fiber-optic testbed, we show that, for certain spatial distributions of noise, suppression of well over 10 dB beyond the standard limit is readily achievable. With the use of digital signal processing to generate the correction signal, our new technique requires no new electro-optic hardware relative to the field-standard noise cancellation scheme. This will allow for widespread adoption of these improved limits in existing systems, with applications in optical clock distribution, optical clock comparisons for fundamental physics and geodesy, and quantum networking.