Frequency response of Quartz Crystal Microbalance under uniaxial force

Zafirah, Tyas N.; Triqadafi, A O; Kusuma, F J; Sakti, Setyawan P.

doi:10.1088/1742-6596/1951/1/012041

Cited by 1 publication

(1 citation statement)

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“…As a mass-sensitive sensor, the quartz crystal microbalance (QCM) works on the principle of frequency shift. Te sensor's resonance frequency changes according to the amount of the absorbing or desorbing molecule on the sensor surface [1] or by other infuences such as force [2,3], friction [4], and others. A frequency counter is used as a data acquisition system.…”

Section: Introductionmentioning

confidence: 99%

Four-Channels High-Resolution Frequency Counter for QCM Sensor Array Using Generic FPGA XC6SLX9 Board

Triqadafi

Zafirah

Dharmawan

et al. 2023

Journal of Electrical and Computer Engineering

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A frequency counter is essential for resonance-based sensors like quartz crystal microbalance. An electronic nose or tongue using a QCM sensor array requires a multichannel frequency counter to detect the frequency shift of the sensors simultaneously. The frequency counter’s resolution, precision, and sampling speed are important factors. Board size, energy consumption, and rapid deployment are also considered in the design. This work shows the development of an independent multichannel frequency counter using a commercial Xilinx Spartan 6 series XC6SLX9 board module and a microcontroller board. Both modules are general-purpose modules; therefore, there is no need for a printed circuit board design, resulting in a quick implementation: the use of FPGA results in a compact size and low energy consumption. The developed counter is designed based on a reciprocal counter utilizing the internal logic block of the FPGA. The FPGA module has a built-in 50 MHz TCXO clock and is the reference clock. The high-resolution timing of the counter is realized by multiplying the 50 MHz clock by 6 to reach 300 MHz. The multiplication utilizes the PLL modules in the FPGA. The high precision and accuracy of the counter are achieved by calibrating the timing clock to a 10 MHz rubidium oscillator. The data communication to the microcontroller is done via the SPI by implementing the SPI protocol in the FPGA. The resource is optimized by utilizing PLL and DSP blocks for the counter. Only 5% registers and 5% LUTs of the FPGA resource are used to build a four-channel frequency counter. The result shows that the counter can measure the frequency of incoming signals with a resolution of 0.033 Hz at 10 MHz with a sampling time of 1 second. The system has been tested to monitor the frequency changes of a QCM sensor array.

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