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Carrier Storage Frequency Divider Using Silicon PIN Diodes (Case No. 2025-023)

Summary: Researchers in UCLA’s Department of Electrical and Computer Engineering have designed and fabricated an innovative device capable of frequency division at the Terahertz range, featuring low power consumption, quadrature outputs, and high sensitivity. Background: Traditional electronic and optical devices struggle to operate at the...

Published: 1/23/2025 | Inventor(s): Sidharth Thomas, Aydin Babakhani, Fallahi Motlagh

Keywords(s): Analogue Electronics, Antennas/Wireless, artificial electromagnetic materials, Bandwidth (Signal Processing), Bioelectromagnetics, bioelectronics, bistable electroactive polymer, Cardiac Electrophysiology, Consumer Electronics, Continuous-Wave Radar, Digital Electronics, Digital Signal Processing, Electrical Engineering, Electroactive Polymers, Electrocatalyst, electrochemical sensors, Electrode, Electrode 3D Printing, electrodeposition, electrodes, Electroencephalography, Electroencephalography (EEG), Electroencephalography Microsecond Neurofeedback, Electrolyte, electromagnetic, Electromagnetism, Electron, electron emittance, Electron Gun, Electronics & Semiconductors, energy-efficient wireless communication, Extremely High Frequency, high-frequency signals, image signal processing, Imaging, Integrated Circuit, low-power device, Optical networks, PIN Diode, power conversion efficiency, Radar, Radar / Antennae, Remote Sensing, Semiconductor, Semiconductor Device, Semiconductors, signal decoding, Signal Processing, Silicon, Synthetic aperture radar (SAR), Wireless, wireless communication, wireless connectivity, Wireless Sensor Network, wireless spectrum

Category(s): Electrical > Electronics & Semiconductors, Electrical > Electronics & Semiconductors > Circuits, Electrical, Electrical > Wireless, Electrical > Signal Processing

Soft, Stretchable, and Strain-Insensitive Bioelectronics 2022-201

Summary: UCLA Researchers in the Department of Electrical and Computer Engineering have developed a library of soft, stretchable biomaterials that decouple bioelectronic interfaces resulting in improved sensing and neural stimulation devices that can withstand significant strain. Background: The interface between electronic devices and biological...

Published: 9/18/2024 | Inventor(s): Sam Emaminejad, Qibing Pei, Brian Bo Wang, Yichao Zhao

Keywords(s): Bioelectromagnetics, bioelectronics, Biomaterial, Biosensor, electrodes, Functional Materials, Materials, Medical Devices and Materials, Nanomaterials, Nanosensor, nanostructured materials, neural stimulation, strain insensitive, tissue-electronic interface

Category(s): Materials, Materials > Functional Materials, Electrical, Electrical > Electronics & Semiconductors, Materials > Nanotechnology, Medical Devices, Medical Devices > Neural Stimulation