Comparative Analysis of Sinusoidal Oscillators with Surface Acoustic Wave Sensor in the Feedback Loop

Q4 Engineering

Journal of Integrated Circuits and Systems Pub Date : 2023-09-27 DOI:10.29292/jics.v18i2.690

Henrique Silva, Raimundo Carlos Silvério Freire, Jalberth Fernandes de Araújo, Sávio Correia Bezerra, Maria Nathália Freitas Nunes, Maxence Rube, Ollivier Tamarin

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Abstract

Surface acoustic wave sensors can be implemented within the feedback loop of sinusoidal oscillators for detecting pollutants. This detection process involves analyzing the variation of oscillator output voltage parameters, such as amplitude and oscillation frequency. However, each oscillator topology has a distinct operating range concerning frequency and component values. Therefore, a comparative analysis is necessary to determine the oscillator with optimal performance to use with the sensor. To obtain results, a surface acoustic wave sensor model was chosen based on a piezoelectric crystal with a resonant frequency of 117.6 MHz, and three sinusoidal oscillator topologies were used: Pierce, Colpitts, and Clapp. The oscillators were simulated with the sensor model in the feedback loop using the Montecarlo method. The simulation occurred in two steps: individually varying each component by +/- 20% with 250 iterations, and simultaneously varying all components by +/- 20% with 1000 iterations. The variables analyzed in the simulations were amplitude, oscillation frequency, and a new parameter indicating the percentage of time there is an oscillation, termed "robustness." As a result, it was determined that all three oscillators generated oscillations in the output voltage, making them viable for use with the sensor. Furthermore, it was discovered that the Clapp oscillator had a robustness of 84.5%, while the Colpitts and Pierce oscillators had a robustness of 56.3% and 49.9%, respectively. Therefore, based on the results presented in this study, the Clapp oscillator is the optimal choice for use with the surface acoustic wave sensor.

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反馈回路中正弦波振荡器与表面声波传感器的对比分析

表面声波传感器可以在正弦波振荡器的反馈回路中实现，用于检测污染物。该检测过程包括分析振荡器输出电压参数的变化，如振幅和振荡频率。然而，每个振荡器拓扑都有一个关于频率和分量值的不同工作范围。因此，有必要进行比较分析，以确定与传感器一起使用的性能最佳的振荡器。为了得到结果，选择了一种基于压电晶体的表面声波传感器模型，谐振频率为117.6 MHz，使用了三种正弦振荡器拓扑:Pierce、Colpitts和Clapp。利用蒙特卡罗方法对反馈回路中的传感器模型进行了振子仿真。模拟分两个步骤进行:在250次迭代中单独改变每个组件+/- 20%，同时在1000次迭代中改变所有组件+/- 20%。在模拟中分析的变量是振幅、振荡频率和一个新的参数，表示振荡的时间百分比，称为“鲁棒性”。结果，确定了所有三个振荡器在输出电压中产生振荡，使它们能够与传感器一起使用。此外，我们发现Clapp振子的鲁棒性为84.5%，而Colpitts和Pierce振子的鲁棒性分别为56.3%和49.9%。因此，根据本研究的结果，克拉普振荡器是与表面声波传感器一起使用的最佳选择。

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来源期刊

Journal of Integrated Circuits and Systems Engineering-Electrical and Electronic Engineering

CiteScore

0.90

自引率

0.00%

发文量

期刊介绍： This journal will present state-of-art papers on Integrated Circuits and Systems. It is an effort of both Brazilian Microelectronics Society - SBMicro and Brazilian Computer Society - SBC to create a new scientific journal covering Process and Materials, Device and Characterization, Design, Test and CAD of Integrated Circuits and Systems. The Journal of Integrated Circuits and Systems is published through Special Issues on subjects to be defined by the Editorial Board. Special issues will publish selected papers from both Brazilian Societies annual conferences, SBCCI - Symposium on Integrated Circuits and Systems and SBMicro - Symposium on Microelectronics Technology and Devices.