Abstract: A low-power CMOS reference voltage generating with enhanced power supply rejection ratio (PSRR) and fast start-up time is disclosed. The reference voltage generating is generated by the stacked diode-connected MOS transistors (SDMT) architecture to reduce the dependence on process, voltage and temperature. The self-biased and capacitor coupled architecture can shorten the start-up time without increasing power consumption and improve the bandwidth of the power supply rejection ratio. This design is implemented using a CMOS process, which can achieve stabilization time of 0.2 ms. Under the same power consumption, this design is 274 times better than a design without a start-up time enhancement. The power supply rejection ratio measured at 100 Hz is ?73.5 dB. In the temperature range of ?40 to 130° C., the average temperature coefficient is 62 ppm/° C.

Abstract: A low-power CMOS reference voltage generating with enhanced power supply rejection ratio (PSRR) and fast start-up time is disclosed. The reference voltage generating is generated by the stacked diode-connected MOS transistors (SDMT) architecture to reduce the dependence on process, voltage and temperature. The self-biased and capacitor coupled architecture can shorten the start-up time without increasing power consumption and improve the bandwidth of the power supply rejection ratio. This design is implemented using a CMOS process, which can achieve stabilization time of 0.2 ms. Under the same power consumption, this design is 274 times better than a design without a start-up time enhancement. The power supply rejection ratio measured at 100 Hz is ?73.5 dB. In the temperature range of ?40 to 130° C., the average temperature coefficient is 62 ppm/° C.

Abstract: Disclosed herein is a portable ventilator and a method for providing an oscillatory flow to a subject in need thereof. The method comprises: (a) forming a gas mixture comprising pure oxygen and air; (b) converting the gas mixture into the oscillatory flow by applying thereto a predetermined oscillatory frequency and a predetermined ventilatory duration; (c) outputting the oscillatory flow of the step (b) at a first jet pressure, in which the outputted oscillatory flow has a first flow rate; and (d) modulating the outputted oscillatory flow of the step (c) by, (i) varying the respective amounts of the pure oxygen and the air in the gas mixture; or (ii) varying the predetermined ventilatory duration of the step (b), in which if the fist jet pressure is smaller than the predetermined jet pressure, then decreases the predetermined ventilatory duration; or if the first jet pressure is greater than the predetermined jet pressure, then increases the predetermined ventilatory duration.

Abstract: Various examples are provided for disposable medical sensors that can be used for detection of SARS-CoV-2 antigen, cardiac troponin I, or other biosensing applications. In one example, a medical sensing system includes single-use disposable test strip comprising a functionalized sensing area configured to detect SARS-CoV-2 antigen and a portable sensing and readout device including pulse generation circuitry that can generate synchronized gate and drain pulses for detection and quantification of SARS-CoV-2 antigen in biological samples. In another example, a method includes providing a saliva sample to a functionalized sensing area configured to detect SARS-CoV-2 antigen, generating synchronized gate and drain pulses for a transistor, the gate pulse provided via electrodes of the functionalized sensing area, and sensing an output of the transistor that is a function of a concentration of SARS-CoV-2 antigen in the sample.

Abstract: Various examples are provided for disposable medical sensors that can be used for the detection of cerebral spinal fluid. In one example, a medical sensing system includes a disposable sensing unit comprising a functionalized sensing area disposed between electrodes; and a portable sensing unit analyzer including pulse generation circuitry that can generate synchronized gate and drain pulses and a transistor with a gate electrically coupled to one electrode. A gate pulse output of the pulse generation circuitry is electrically coupled to a second electrode and a drain pulse output is electrically coupled to a drain of the transistor. In another example, a method includes providing a sample to a functionalized sensing area, generating synchronized gate and drain pulses for a transistor, the gate pulse provided via the electrodes and functionalized sensing area, and sensing an output of the transistor that is a function of a target concentration of the sample.

Abstract: A device for harvesting and managing wireless energy includes a wireless receiver, a first rectifier, a first capacitor, a voltage detection circuit, a first electrical switch, a second rectifier and a second capacitor connected to each other. The wireless receiver receives a wireless RF signal and converts it into an AC voltage with an input power. The first rectifier receives the AC voltage, converts it into a first DC voltage and transmits the first DC voltage to a load. The voltage detection circuit has a threshold voltage value and detects the first DC voltage. When the first DC voltage is larger than the threshold voltage value, the voltage detection circuit turns on the first electrical switch and the second rectifier receives the AC voltage through the first electrical switch to share the input power received by the first rectifier, thereby achieving the high energy conversion efficiency.

Abstract: A device for harvesting and managing wireless energy includes a wireless receiver, a first rectifier, a first capacitor, a voltage detection circuit, a first electrical switch, a second rectifier and a second capacitor connected to each other. The wireless receiver receives a wireless RF signal and converts it into an AC voltage with an input power. The first rectifier receives the AC voltage, converts it into a first DC voltage and transmits the first DC voltage to a load. The voltage detection circuit has a threshold voltage value and detects the first DC voltage. When the first DC voltage is larger than the threshold voltage value, the voltage detection circuit turns on the first electrical switch and the second rectifier receives the AC voltage through the first electrical switch to share the input power received by the first rectifier, thereby achieving the high energy conversion efficiency.

Abstract: Disclosed herein are example methods, systems, and devices involving electrically-conductive wires, such as standard IC bonding wires, that are configured so as to operate as inertial sensors. One embodiment of the disclosed methods, systems, and devices may take the form of a system that includes a first electrically-conductive wire and a second electrically-conductive wire, where the first wire and the second wire are electromagnetically coupled; and a sensor oscillator, where the sensor oscillator is coupled to the first wire and the second wire, and where the sensor oscillator is configured to output a sensor-oscillator signal that is frequency modulated based on a change in complex impedance between the first wire and the second wire, where the change in complex impedance is due to a displacement of the first wire relative to the second wire.

Abstract: The present invention provides a projecting device including a movement detecting unit, an image processing unit, and a projection module. The movement detecting unit is configured to detect displacement information of the projecting device. The image processing unit is configured to receive an image data frame, adjust a position of the image data frame related to a virtual image frame according to the displacement information, and generate a projection frame according to the intersection between the image data frame and the virtual image frame. The projection module is configured to project the projection frame on a projection plane.

Abstract: A contact lens having an integrated glucose sensor is provided. The contact lens includes an electrochemical sensor configured to measure the level of glucose in the tear fluid of the eye of the user wearing the contact lens. The electrochemical sensor is powered by radiation off-lens, through an RF antenna or a photovoltaic device mounted on the periphery of the contact lens. The power provided to the contact lens also enables transmission of data from the electrochemical sensor, for example by backscatter communications or optically by an LED mounted to the lens.

Abstract: A contact lens having an integrated glucose sensor is provided. The contact lens includes an electrochemical sensor configured to measure the level of glucose in the tear fluid of the eye of the user wearing the contact lens. The electrochemical sensor is powered by radiation off-lens, through an RF antenna or a photovoltaic device mounted on the periphery of the contact lens. The power provided to the contact lens also enables transmission of data from the electrochemical sensor, for example by backscatter communications or optically by an LED mounted to the lens.