Rapidly Tunable Synthetic Wavelength Ranging with an RFSoC

TL;DR

This paper introduces a digitally tunable synthetic wavelength interferometry technique using RFSoC and electro-optic frequency combs, enabling precise optical range measurements over varying distances with reduced system complexity.

Contribution

It presents a novel, software-defined approach for dynamic synthetic wavelength sweeping and absolute optical range measurement using electro-optic frequency combs and RFSoC.

Findings

Achieved sub-60 nm precision over 1 m delay line.

Maintained 15 μm precision over 40 km fiber link.

Demonstrated simple implementation relying on continuous-wave interference.

Abstract

Measurements of optical range and time-of-flight are crucial for a variety of high-precision technologies. Competitive optical measurement techniques have been developed that balance precision with accuracy and system complexity. Here, we present a continuous-wave synthetic wavelength interferometry technique that employs digitally tunable electro-optic frequency combs. With a software-defined radio, our approach can dynamically sweep the synthetic wavelength and measure absolute optical range. We demonstrate this digital approach over a free-space optical delay line of 1 m and over an 40 km fiber link. The best obtained precision over the delay line is better than 60 nm (0.2 fs). Through a 40 km fiber spool, this precision degrades to 15 um (50 fs), which is a fractional error on the order of 2e-10 m/m. Our design is simple to implement, and only relies on continuous-wave interference, decreasing system complexity.