Water Temperature and Salinity Measurement Using Frequency Comb

Zhang, Haoyun; Xu, Xinyang; Zhao, Haihan; Dong, Fanpeng; Qian, Zhiwen; Xue, Bin

doi:10.3390/app9235043

Applied Sciences

2019

DOI: 10.3390/app9235043

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Water Temperature and Salinity Measurement Using Frequency Comb

Haoyun Zhang

Xinyang Xu

Haihan Zhao

et al.

Abstract: Water temperature and salinity are key parameters in many fields such as industry, forestry and agriculture. In this paper, we, theoretically and experimentally, demonstrate a method which is capable of water temperature and salinity measurement based on a laser frequency comb at 518 nm. We have developed a simple Michelson interferometer system. By scanning a mirror on a precision displacement platform, a pair of cross-correlation patterns can be obtained. The real-time optical distance information from these… Show more

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Cited by 3 publications

References 36 publications

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High-precision interferometric measurement of slow and fast temperature changes in static fluid and convective flow

Ge,

Zielińska,

Maldonado

2023

Exp Fluids

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We explore the strengths and limitations of using a standard Michelson interferometer to sample line-of-sight-averaged temperature in water via two experimental setups: slow-varying temperature in static fluid and fast temperature variations in convective flow. The high precision of our measurements (a few mK) is enabled by the fast response time and high sensitivity of the interferometer to minute changes in the refractive index of water caused by temperature variations. These features allow us to detect the signature of fine fluid dynamical patterns in convective flow in a fully non-intrusive manner. For example, we are able to observe an asymmetry in the rising thermal plume (i.e., an asynchronous arrival of two counter-rotating vortices at the measurement location), which is not possible to resolve with more traditional (and invasive) techniques, such as RTD (Resistance Temperature Detector) sensors. These findings, and the overall reliability of our method, are further corroborated by means of Particle Image Velocimetry and Large Eddy Simulations. While this method presents inherent limitations (mainly stemming from the line-of-sight-averaged nature of its results), its non-intrusiveness and robustness, along with the ability to readily yield real-time, highly accurate measurements, render this technique very attractive for a wide range of applications in experimental fluid dynamics.

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High-precision interferometric measurement of slow and fast temperature changes in static fluid and convective flow

Ge,

Zielińska,

Maldonado

2023

Exp Fluids

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A robust salinity sensor based on encapsulated long-period grating in microfiber

Jin

et al. 2020

Optoelectron. Lett.

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Water salinity measurement using a long-period grating and optical time-domain reflectometry

Jucá¹,

Pereira²,

Spelta³

et al. 2023

J. Opt. Soc. Am. B

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Salinity is a key variable in understanding several issues, from public health to food security. Measuring salinity in situ is traditionally done using conductivimetric methods, and can be challenging due to extreme temperatures, corrosive environment, and oxidation. Fiber-based methods and other alternatives proposed to date have brought a number of advantages, but present low sensor strength, complex or expensive setups, cross-influence of temperature, lack of portability, or prohibitively long response times. This work presents a simple, compact salinity sensing system that, associated with a modern interrogation technique, is capable of achieving good accuracy even in remote sensing and low salt concentrations. The sensor is a long-period grating fabricated using the point-by-point electric arc method. The interrogator is based on optical time-domain reflectometry aided by signal processing techniques inspired by audio processing. Experimental data show that the system is capable of estimating salinity in the range from 0 g/L to 80 g/L within 0.49 g/L on average, with the sensor 4 km away from the light source.

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Water Temperature and Salinity Measurement Using Frequency Comb

Cited by 3 publications

References 36 publications

High-precision interferometric measurement of slow and fast temperature changes in static fluid and convective flow

High-precision interferometric measurement of slow and fast temperature changes in static fluid and convective flow

A robust salinity sensor based on encapsulated long-period grating in microfiber

Water salinity measurement using a long-period grating and optical time-domain reflectometry

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