A MEMS Ultra-Wideband (UWB) Power Sensor with a Fe-Co-B Core Planar Inductor and a Vibrating Diaphragm Capacitor

Vejella, Sujitha; Chowdhury, Sazzadur

doi:10.3390/s21113858

Cited by 7 publications

(2 citation statements)

References 31 publications

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“…Table 3 summarizes the main performance of the proposed PCA compared to the prior art [22,23] and commer-cial devices (Axopatch 200B) [20,24]. The proposed design shows a wider bandwidth and higher capacitance compensation and is the only design that integrates a glass microelectrode series resistance/capacitance compensation circuit and feedback resistor parasitic capacitance compensation.…”

Section: Resultsmentioning

confidence: 99%

A 146-dB-Ohm Gain 14-pARMS Noise Patch-Clamp Amplifier for Whole-Cell Ion Current Detection

Pan

2022

Journal of Sensors

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The membrane clamp technique is an important tool to reflect the electrophysiological characteristics of cells by recording the ionic currents of cellular channels. Embedded systems work in systems designed for specific user groups and are used to implement specific functions. The membrane clamp amplifier built with embedded technology has the advantages of miniaturization, specialization, low power consumption, high integration, high resource utilization, and a long life cycle, which can avoid the inconvenience to developers and experimenters due to the update of general-purpose computer software and hardware. In this paper, a patch-clamp amplifier (PCA) based on a transimpedance amplifier (TIA) is proposed, which includes a glass microelectrode series resistance/capacitance compensation circuit and feedback resistor parasitic capacitance compensation. The prototype is designed using 180 nm CMOS technology and occupies an area of 720 μ m × 630 μ m . The prototype achieves a transimpedance gain of 145.6 dB-Ohm, a -3 dB bandwidth greater than 15 kHz, and an input reference noise current of 13.98 pARMS. Experimental results show that the proposed PCA is capable of compensating up to 30 pF of electrode capacitance and up to 10 MΩ for 86% of the series resistance, respectively. In addition, when the feedback resistor parasitic capacitance compensation circuit is enabled, the overshoot phenomenon disappears, overcoming the shortcomings of the conventional diaphragm clamp amplifier current clamp and maintaining the original key performance.

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Section: Resultsmentioning

confidence: 99%

A 146-dB-Ohm Gain 14-pARMS Noise Patch-Clamp Amplifier for Whole-Cell Ion Current Detection

Pan

2022

Journal of Sensors

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“…A variable inductivity, L com , is used to fine-tune both frequencies f 1 and f 2 for reactances −1/jωC l p and −1/jωC lr at a certain frequency f r , and to set the sensitivity of the sensor [28,[44][45][46][47]. A pulse-wide modulated signal corresponding to the frequency difference between the frequency f 1 and reference frequency f r (from reference oscilator) or the difference between the frequency f 2 and reference frequency enters the BPF (Band Pass Filter) [48][49][50]. If the frequencies f 1 and f 2 (in our case) equal approximately 4 MHz and are a few kHz different from the frequency f r , then these two frequencies are converted (depending on the signal S con ) to the range between 4 and 100 kHz at the output of BPF.…”

Section: Methodsmentioning

confidence: 99%

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

Matko

2022

Sensors

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We present a new highly sensitive, low-value capacitance sensor method that uses multiple quartz crystals connected in parallel inside the oscillator. In the experimental setup, the measured (sensible) reactance (capacitance) is connected in parallel to the total shunt capacitance of the quartz crystals, oscillating in the oscillator. Because AT-cut crystals have a certain nonlinear frequency–temperature dependence, we use the switching mode method, by which we achieve a temperature compensation of the AT-cut crystals’ frequency–temperature characteristics in the temperature range between 0–50 °C. The oscillator switching method also compensates for any other influences on the frequency of the oscillator, such as ageing of the crystals and oscillator elements, supply voltage fluctuations, and other parasitic impedances in the oscillating circuit. Subsequently using two 50-ms-delayed switches between the measuring and reference capacitors, the experimental error in measuring the capacitance is lowered for measurements under a dynamic temperature variation in the range of 0–50 °C. The experimental results show that the switching method, which includes a multiple quartz connection and high-temperature compensation improvement of the quartz crystals’ characteristics, enables a sub-aF resolution. It converts capacitance changes in the range 10 zF–200fF to frequencies in the range 4 kHz–100 kHz.

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Development of fiber Bragg grating vibration sensor for bidirectional monitoring of thin rod cantilever beam

Zhu,

Liu,

Qin

et al. 2024

Measurement

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A MEMS Ultra-Wideband (UWB) Power Sensor with a Fe-Co-B Core Planar Inductor and a Vibrating Diaphragm Capacitor

Cited by 7 publications

References 31 publications

A 146-dB-Ohm Gain 14-pARMS Noise Patch-Clamp Amplifier for Whole-Cell Ion Current Detection

A 146-dB-Ohm Gain 14-pARMS Noise Patch-Clamp Amplifier for Whole-Cell Ion Current Detection

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

Development of fiber Bragg grating vibration sensor for bidirectional monitoring of thin rod cantilever beam

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