Refractive-index-sensing optical comb based on photonic radio-frequency conversion with intracavity multi-mode interference fiber sensor.

Ryo Oe,Takeshi Yasui,Takeo Minamikawa,Kaoru Minoshima,Hideki Fukano,Kyuki Shibuya,Tetsuo Iwata,Shuji Taue,Yasuhiro Mizutani,Kosuke Nagai,Yoshiaki Nakajima,Hirotsugu Yamamoto,Masatomo Yamagiwa,Takahiko Mizuno

doi:10.1364/oe.26.019694

Abstract

Optical frequency combs (OFCs) have attracted attention as optical frequency rulers due to their tooth-like discrete spectra together with their inherent mode-locking nature and phase-locking control to a frequency standard. Based on this concept, their applications until now have been demonstrated in the fields of optical frequency metrology. However, if the utility of OFCs can be further expanded beyond their application by exploiting new aspects of OFCs, this will lead to new developments in optical metrology and instrumentation. Here, we report a fiber sensing application of OFCs based on a coherent link between the optical and radio frequencies, enabling high-precision refractive index measurement based on frequency measurement in radio-frequency (RF) region. Our technique encodes a refractive index change of a liquid sample into a repetition frequency of OFC by a combination of an intracavity multi-mode-interference fiber sensor and wavelength dispersion of a cavity fiber. Then, the change in refractive index is read out by measuring the repetition frequency in RF region based on a frequency standard. Use of an OFC as a photonic RF converter will lead to the development of new applications in high-precision fiber sensing with the help of functional fiber sensors and precise RF measurement.

Highlights

An optical frequency comb (OFC) [1,2,3] is regarded as a group of a vast number of phaselocked narrow-linewidth continuous-wave (CW) light sources with a constant frequency spacing frep over a broad spectral range
While the mode spacing of the OFC is transferred into the RF beat signal via such a coherent detection process, use of the RF beat signal simplifies the experimental methodology because measurement in the RF region benefits from high precision, high functionality, convenience, and low cost by making use of various kinds of RF measurement apparatuses
We focus on a multi-mode interference (MMI) fiber sensor for refractive index (RI) measurement [29,30,31]

Summary

Introduction

An optical frequency comb (OFC) [1,2,3] is regarded as a group of a vast number of phaselocked narrow-linewidth continuous-wave (CW) light sources with a constant frequency spacing frep (typically, 50–100 MHz) over a broad spectral range. When an OFC is detected with a photodiode, its quadratic-detection function converts a mode spacing of OFC into a beat signal in the RF region without changing frep. While the mode spacing of the OFC is transferred into the RF beat signal via such a coherent detection process, use of the RF beat signal simplifies the experimental methodology because measurement in the RF region benefits from high precision, high functionality, convenience, and low cost by making use of various kinds of RF measurement apparatuses. The RF beat signal and its harmonic components have been applied to optical distance metrology, such as long-distance measurement with extremely high precision [14,15,16]

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Conclusion