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Enhanced Frequency Resolution Two-Channel Two-Phase Microcontroller Lock-In Amplifier

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Abstract:

This article presents a method to obtain a enhanced frequency resolution two-phase lock-in amplifier (LIA) with two channels in a microcontroller using minimum external c...Show More

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Abstract:

This article presents a method to obtain a enhanced frequency resolution two-phase lock-in amplifier (LIA) with two channels in a microcontroller using minimum external circuitry. The timer peripheral of the microcontroller was used to generate the square wave signals for both the excitation and the quadrant demodulation, simplifying the waveform synthesis when compared to the use of digital-to-analog converters (DACs). To improve the frequency resolution of the generated signals, the timer signal was dithered to achieve fractional frequency values, while demodulation was executed in real time with signal acquisition. The real and imaginary parts of the signal are then transmitted to the computer by the universal serial bus (USB) interface while the computer sends commands to change the frequency, phase, or control other features. As proof of work, quartz tuning fork (QTF) sensors were measured due to its high

$Q$ -factor. The bandwidth of the lock-in was limited by the acquisition and demodulation sample rate of 300 Ks/s, while we showed 1000 times frequency resolution enhancement when compared to the not dithered signal generation. This approach can be applied in embedded design to measure frequency-dependent sensors with high

$Q$ , in scientific instrumentation such as scanning probe microscopes (SPMs), or even for educational purposes to teach the working principle of the LIAs.

Published in: IEEE Transactions on Instrumentation and Measurement ( Volume: 70)

Article Sequence Number: 2003608

Date of Publication: 26 February 2021

ISSN Information:

DOI: 10.1109/TIM.2021.3062409

References is not available for this document.

Contents

I. Introduction

Two-phase lock-in amplifiers (LIAs) are instruments that measure the amplitude and phase of amplitude-modulated signals. It is used in a multitude of experiments in science and technology in diverse scenarios. The most common application is in the improvement of the signal-to-noise ratio of an experiment. The lock-in exploits the limited bandwidth of noise and modulates the excitation source of the experiment in a different frequency to finally demodulate a cleaner response signal. In this case, dynamic range and/or dynamic reserve should be enhanced to better recover the signal from the noise. At a different scenario, the LIA can be used to measure the frequency-dependent response of devices and experiments. Different from the application cited before, this application requires an instrument with enhanced frequency resolution and bandwidth of operation allied to the signal recovery capabilities.

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K. Kishore and S. A. Akbar, "Evolution of lock-in amplifier as portable sensor interface platform: A review", IEEE Sensors J., vol. 20, no. 18, pp. 10345-10354, Sep. 2020.

View Article

Google Scholar

L. E. Bengtsson, "A microcontroller-based lock-in amplifier for sub-milliohm resistance measurements", Rev. Sci. Instrum., vol. 83, no. 7, Jul. 2012.

CrossRef Google Scholar

J. Wang, Z. Wang, X. Ji, J. Liu and G. Liu, "A simplified digital lock-in amplifier for the scanning grating spectrometer", Rev. Sci. Instrum., vol. 88, no. 2, Feb. 2017.

CrossRef Google Scholar

A. A. Dorrington and R. Kunnemeyer, "A simple microcontroller based digital lock-in amplifier for the detection of low level optical signals", Proc. 1st IEEE Int. Workshop Electron. Design Test Appl., pp. 486-488, Jan. 2002.

View Article

Google Scholar

H. Rahmannuri, M. Rivai and T. A. Sardjono, "Design of digital lock-in amplifier for low concentration gas detection", Proc. Int. Seminar Intell. Technol. Appl. (ISITIA), pp. 319-322, Aug. 2017.

View Article

Google Scholar

M. A. K. Nooruddin and S. Roy, "A simple digital phase-sensitive detector using AVR microcontroller", Amer. J. Phys., vol. 88, no. 2, pp. 153-158, Feb. 2020.

CrossRef Google Scholar

A. Kar, M. Chandra, P. Goel and V. K. Gupta, "A low-cost portable alternative for a digital lock-in amplifier using TMS320C5535 DSP", Proc. IEEE Region 10th Annu. Int. Conf. (TENCON), pp. 1-5, Dec. 2015.

Google Scholar

M. O. Sonnaillon and F. J. Bonetto, "A low-cost high-performance digital signal processor-based lock-in amplifier capable of measuring multiple frequency sweeps simultaneously", Rev. Sci. Instrum., vol. 76, no. 2, Feb. 2005.

CrossRef Google Scholar

G. Li, S. Zhang, M. Zhou, Y. Li and L. Lin, "A method to remove odd harmonic interferences in square wave reference digital lock-in amplifier", Rev. Sci. Instrum., vol. 84, no. 2, Feb. 2013.

CrossRef Google Scholar

10.

S. Zhang, G. Li, L. Lin and J. Zhao, "Optimization of a digital lock-in algorithm with a square-wave reference for frequency-divided multi-channel sensor signal detection", Rev. Sci. Instrum., vol. 87, no. 8, Aug. 2016.

CrossRef Google Scholar

11.

PWM Resolution Enhancement Through a Dithering Technique for STM32 Advanced-Configuration General-Purpose and Lite Timers, Geneva, Switzerland, 2017.

Google Scholar

12.

C. Barth and R. C. N. Pilawa-Podgurski, "Implementation of dithering digital ripple correlation control for PV maximum power point tracking", Proc. IEEE 14th Workshop Control Modeling Power Electron. (COMPEL), pp. 1-7, Jun. 2013.

View Article

Google Scholar

13.

M. M. Peretz and S. Ben-Yaakov, "Digital control of resonant converters: Enhancing frequency resolution by dithering", Proc. 24th Annu. IEEE Appl. Power Electron. Conf. Expo., pp. 1202-1207, Feb. 2009.

View Article

Google Scholar

14.

J.-M. Friedt and and É. Carry, "Introduction to the quartz tuning fork", Amer. J. Phys., vol. 75, no. 5, pp. 415-422, May 2007.

CrossRef Google Scholar

15.

R. Rousseau, N. Maurin, W. Trzpil, M. Bahriz and A. Vicet, "Quartz tuning fork resonance tracking and application in quartz enhanced photoacoustics spectroscopy", Sensors, vol. 19, no. 24, pp. 5565, Dec. 2019.

CrossRef Google Scholar

16.

T. Voglhuber-Brunnmaier, A. O. Niedermayer, F. Feichtinger and B. Jakoby, "Fluid sensing using quartz tuning forks—Measurement technology and applications", Sensors, vol. 19, no. 10, pp. 2336, May 2019.

CrossRef Google Scholar

17.

A. Castellanos-Gomez, N. Agraït and G. Rubio-Bollinger, "Dynamics of quartz tuning fork force sensors used in scanning probe microscopy", Nanotechnology, vol. 20, no. 21, May 2009.

CrossRef Google Scholar

18.

J. Ko, Y. Yoon and J. Lee, "Quartz tuning forks with hydrogel patterned by dynamic mask lithography for humidity sensing", Sens. Actuators B Chem., vol. 273, pp. 821-825, Nov. 2018.

CrossRef Google Scholar

19.

Fundamentals of Direct Digital Synthesis (DDS)-MT-085 Tutorial, Nov. 2009, [online] Available: https://www.analog.com/media/en/training-seminars/tutorials/MT-085.pdf.

Google Scholar

20.

D. A. Howe and W. Riley, Handbook of Frequency Stability Analysis, Washington, DC, USA:U.S. Government Printing Office, 2008.

Google Scholar

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Enhanced Frequency Resolution Two-Channel Two-Phase Microcontroller Lock-In Amplifier

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Enhanced Frequency Resolution Two-Channel Two-Phase Microcontroller Lock-In Amplifier

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