Multiple Quartz Crystals Connected in Parallel for High-Resolution Sensing of Capacitance Changes

Matko, Vojko

doi:10.3390/s22135030

Cited by 5 publications

(4 citation statements)

References 53 publications

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“…The use of the quartz crystal microbalance (QCM) sensor in liquid media [29][30][31] has brought great benefits in expanding the range of applications [32][33][34], especially in biological media [35]. A significant experimental effort was required to monitor the QCM sensor's series resonance frequency and damping parameters using an active method (oscillator) [36][37][38] or passive interrogation, such as as ring-down methods [39][40][41] in high-viscosity liquid media.…”

Section: Introductionmentioning

confidence: 99%

Assessing Impedance Analyzer Data Quality by Fractional Order Calculus: A QCM Sensor Case Study

Burda

2023

Electronics

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The paper presents the theoretical, simulation, and experimental results on the QCM sensor based on the Butterworth van Dyke (BVD) model with lumped reactive motional circuit elements of fractional order. The equation of the fractional order BVD model of the QCM sensor has been derived based on Caputo definitions and its behavior around the resonant frequencies has been simulated. The simulations confirm the ability of fractional order calculus to cover a wide range of behaviors beyond those found in experimental practice. The fractional order BVD model of the QCM sensor is considered from the perspective of impedance spectroscopy to give an idea of the advantages that fractional order calculus brings to its modeling. For the true values of the electrical parameters of the QCM sensor based on the standard BVD model, the experimental investigations confirm the equivalence of the measurements after the standard compensation of the virtual impedance analyzer (VIA) and the measurements without compensation by fitting with the fractional order BVD model. From an experimental point of view, using fractional order calculus brings a new dimension to impedance analyzer compensation procedures, as well as a new method for validating the compensation.

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Section: Introductionmentioning

confidence: 99%

Assessing Impedance Analyzer Data Quality by Fractional Order Calculus: A QCM Sensor Case Study

Burda

2023

Electronics

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“…However, when we measure the frequency difference (the crystals in the oscillator act as sensors), the measurement error depends on the chosen method [ 30 ]. If changes of the equivalent circuit of the quartz crystals are in the aF or zF region (in the case of the capacitive effect) or in the pH region (in the case of an inductive effect), changes in the resonant frequency, which are typical in measurements of a mechanical displacement, nanopositioning, eccentric motion, strain sensing, dielectric properties of liquids and density of liquids, low pressure, etc., are very low [ 4 , 16 , 17 , 18 , 19 , 20 , 21 , 22 , 31 , 32 , 33 , 34 , 35 , 36 , 37 , 38 , 39 , 40 ]. It is of crucial importance that these small changes of the resonant frequency are measured as accurately as possible, before they are transformed into the measured quantity.…”

Section: Introductionmentioning

confidence: 99%

Measurements of Small Frequency Differences by Dual Mode 4 MHz Quartz Sensors

Matko

2023

Sensors

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We proposed a method for measuring frequency differences of the order of a few Hz with an experimental error lower than 0.0001% by using two 4 MHz quartz oscillators, the frequencies of which are very close (a few 10 Hz difference) due to the dual mode operation (differential mode with two temperature-compensated signal frequencies or a mode with one signal and one reference frequency). We compared the existing methods for measuring frequency differences with the new method which is based on counting the number of transitions through zero within one beat period of the signal. The measuring procedure requires equal experimental conditions (temperature, pressure, humidity, parasitic impedances etc.) for both quartz oscillators. To ensure equal resonant conditions for oscillation two quartz crystals are needed, which form a temperature pair. The frequencies and resonant conditions of both oscillators must be almost equal, which is achieved by an external inductance or capacitance. In such a way, we minimized all the external effects and ensured highly stable oscillations and high sensitivity of the differential sensors. The counter detects one beat period by an external gate signal former. By using the method of counting transitions through zero within one beat period, we reduced the measuring error by three orders of magnitude, compared to the existing methods.

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“…This scenario, described by Sauerbrey’s equation [ 25 , 26 ], is not affected by coating one or both electrodes of the QCM sensor with a thin sensing layer if it is firmly bound, and its mass does not change the linear dependence of the serial resonant frequency with the deposited mass. In this situation, an experimental setup that consists of an oscillator with a QCM sensor in the loop [ 29 ] and a frequency meter is commonly used. This experimental configuration might be more efficient if the parallel capacitance

was compensated to eliminate the discrepancy between the serial resonant frequency of the QCM sensor and the frequency of the oscillator output.…”

Section: Introductionmentioning

confidence: 99%

Effect of Load on Quartz Crystal Microbalance Sensor Response Addressed Using Fractional Order Calculus

Burda

2023

Sensors

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To accurately model the effect of the load caused by a liquid medium as a function of its viscosity, the fractional order Butterworth–Van Dyke (BVD) model of the QCM sensor is proposed in this study. A comprehensive understanding of the fractional order BVD model followed by a simulation of situations commonly encountered in experimental investigations underpins the new QCM sensor approach. The Levenberg–Marquardt (LM) algorithm is used in two fitting steps to extract all parameters of the fractional order BVD model. The integer-order electrical parameters were determined in the first step and the fractional order parameters were extracted in the second step. A parametric investigation was performed in air, water, and glycerol–water solutions in ten-percent steps for the fractional order BVD model. This indicated a change in the behavior of the QCM sensor when it swapped from air to water, modeled by the fractional order BVD model, followed by a specific dependence with increasing viscosity of the glycerol–water solution. The effect of the liquid medium on the reactive motional circuit elements of the BVD model in terms of fractional order calculus (FOC) was experimentally demonstrated. The experimental results demonstrated the value of the fractional order BVD model for a better understanding of the interactions occurring at the QCM sensor surface.

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Multiple Quartz Crystals Connected in Parallel for High-Resolution Sensing of Capacitance Changes

Cited by 5 publications

References 53 publications

Assessing Impedance Analyzer Data Quality by Fractional Order Calculus: A QCM Sensor Case Study

Assessing Impedance Analyzer Data Quality by Fractional Order Calculus: A QCM Sensor Case Study

Measurements of Small Frequency Differences by Dual Mode 4 MHz Quartz Sensors

Effect of Load on Quartz Crystal Microbalance Sensor Response Addressed Using Fractional Order Calculus

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