Abstract: Aspects disclosed in the detailed description include a touch capacitance transduced energy harvesting system. The energy harvesting system includes a touch sensing electrode array and energy harvesting circuitry coupled to the touch sensing electrode array. When a movable conductive object (e.g., a human finger) moves toward or away from the touch sensing electrode array, capacitance of the touch sensing electrode array increases and decreases accordingly, thus transducing a direct current (DC) current in the touch sensing electrode array. As such, the energy harvesting circuitry can be configured to harvest electric energy from the DC current to generate and store a DC voltage. By harvesting the electric energy transduced from the kinetic energy of the movable conductive object, it is possible to power a low-power electronic device (e.g., a biosensor) with motions already used for interfacing with the low-power electronic device.

Abstract: Methods and apparatus for real-time, quantifiable monitoring of high-risk areas of biological tissue are described. The methods and apparatus use impedance spectroscopy to detect subtle changes in tissue health.

Abstract: Aspects disclosed in the detailed description include a touch capacitance transduced energy harvesting system. The energy harvesting system includes a touch sensing electrode array and energy harvesting circuitry coupled to the touch sensing electrode array. When a movable conductive object (e.g., a human finger) moves toward or away from the touch sensing electrode array, capacitance of the touch sensing electrode array increases and decreases accordingly, thus transducing a direct current (DC) current in the touch sensing electrode array. As such, the energy harvesting circuitry can be configured to harvest electric energy from the DC current to generate and store a DC voltage. By harvesting the electric energy transduced from the kinetic energy of the movable conductive object, it is possible to power a low-power electronic device (e.g., a biosensor) with motions already used for interfacing with the low-power electronic device.

Abstract: Methods and apparatus for real-time, quantifiable monitoring of high-risk areas of biological tissue are described. The methods and apparatus use impedance spectroscopy to detect subtle changes in tissue health.

Abstract: A minimally invasive, wireless ECoG microsystem is provided for chronic and stable neural recording. Wireless powering and readout are combined with a dual rectification power management circuitry to simultaneously power to and transmit a continuous stream of data from an implant with a micro ECoG array and an external reader. Area and power reduction techniques in the baseband and wireless subsystem result in over 10×IC area reduction with a simultaneous 3× improvement in power efficiency, enabling a minimally invasive platform for 64-channel recording. The low power consumption of the IC, together with the antenna integration strategy, enables remote powering at 3× below established safety limits, while the small size and flexibility of the implant minimizes the foreign body response.