Patrick Riehl scite author profile

We have developed highly sensitive electrometers and electrostatic fieldmeters (EFMs) that make use of micromechanical variable capacitors. Modulation of the input capacitance, a technique used in macroscale instruments such as the vibrating-reed electrometer and the field-mill electrostatic voltmeter (ESV), moves the detection bandwidth away from the 1 -noise-limited regime, thus improving the signal-to-noise ratio (SNR). The variable capacitors are implemented by electrostatically driven resonators with differential actuation and sensing to reduce drive-signal feedthrough. The resonators in the electrometer utilize a balanced comb structure to implement harmonic sensing. Two fabrication methods were employed-a hybrid technology utilizing fluidically self-assembled JFETs and SOI microstructures, and an integrated process from Analog Devices combining 0.8-m CMOS and 6-m-thick polysilicon microstructures. All devices operate in ambient air at room temperature. Measured data from one electrometer with an input capacitance of 0.7 pF indicates a charge resolution of 4.5 aC rms (28 electrons) in a 0.3 Hz bandwidth. The resolution of this electrometer is unequaled by any known ambient-air-operated instrument over a wide range of source capacitances. The EFM has a resolution of 630 V/m, the best reported figure for a MEMS device.[985]Index Terms-Electrometer, electrostatic fieldmeter (EFM), electrostatic voltmeter, variable capacitor.

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Wireless Power Systems for Mobile Devices Supporting Inductive and Resonant Operating Modes

Riehl¹,

Satyamoorthy²,

Akram³

et al. 2015

IEEE Trans. Microwave Theory Techn.

135

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An AC-coupled hybrid envelope modulator for HSUPA transmitters with 80% modulator efficiency

Riehl¹,

Fowers

Hong

et al. 2013

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A 3D resonant wireless charger for a wearable device and a mobile phone

Kuo¹,

Riehl²,

Satyamoorthy³

et al. 2015

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A resonant wireless power transfer (WPT) system that allows for free positioning of a wearable device about a 360 o axis of rotation and simultaneous charging of a mobile phone is proposed. A 3D transmitter coil structure is introduced to provide a cylindrical charging surface with a uniform magnetic field. A prototype charging system including an amplifier and a rectifier operating at 6.78 MHz is demonstrated. The prototype delivers 1 W to a wearable device and 5 W to a mobile phone simultaneously with a power transfer efficiency of 48%.

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Embroidered Textile Coils for Wireless Charging of Smart Garments

Chang

Riehl

Lin

2021

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Patrick Riehl

Electrostatic charge and field sensors based on micromechanical resonators

Wireless Power Systems for Mobile Devices Supporting Inductive and Resonant Operating Modes

An AC-coupled hybrid envelope modulator for HSUPA transmitters with 80% modulator efficiency

A 3D resonant wireless charger for a wearable device and a mobile phone

Embroidered Textile Coils for Wireless Charging of Smart Garments

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