Abstract: A MEMS (Microelectromechanical System) INU (Inertial Navigation Unit) chip comprises a compact autonomous device undergoing motion tracks and analyzes its definite movement relative to local Earth coordinates with optimal accuracy and repeatability of lmm over distances of greater than two meters. The MEMS INU includes an Inertial Motion Tracking Device (IMTD) comprises a gyroscope, accelerometer, magnetometer, and digital processor programmed with a general purpose Inertial Measurement Engine (IME), an application specific Motion Analysis and Adaptation (MAA) program and a low power radio. The IMTD tracks its motion with optimum accuracy using compact practical sensors that may have noise and drift by periodically and autonomously checking its velocity changes at an optimum interval, computing a linear acceleration therefrom and determining a no-motion or motion condition relative to a threshold and correcting its velocity, position and acceleration errors when there is no motion.

Abstract: A compact autonomous device undergoing motion tracks and analyzes its definite movement relative to local Earth coordinates with optimal accuracy and repeatability of 1 mm over distances of greater than two meters. The Inertial Motion Tracking Device (IMTD) comprises a gyroscope, accelerometer, magnetometer, and digital processor programmed with a general purpose Inertial Measurement Engine (IME), an application specific Motion Analysis and Adaptation (MAA) program and a low power radio. The IMTD tracks its motion with optimum accuracy using compact practical sensors that may have noise and drift by periodically and autonomously checking its velocity changes at an optimum interval, computing a linear acceleration therefrom and determining a no-motion or motion condition relative to a threshold and correcting its velocity, position and acceleration errors when there is no motion.

Abstract: The disclosure relates generally to a display panel, which in at least some situations includes multiple separate stacked layers or components that are combined together, such as to have one emission layer component with numerous pixels that emit light, and to have at least one control logic layer component that includes integrated circuits or other logic to control the emission of light by the pixels in the emission layer. The different layers may be separate silicon chips or wafers that are connected in a stacked structure via a flip chip technique, with the emission layer using AMOLED or other OLED pixels. The display panels may be designed and/or configured for use in head mounted displays (e.g., with a fully immersive virtual reality system). The disclosure also relates generally to techniques for manufacturing, testing and/or otherwise using such a display panel in various manners.

Abstract: Open-Loop RF Transmitter Output Power Control for Increased Power Efficiency (NC #98068) method includes determining a desired RF output power and obtaining a battery voltage value; determining a supply control voltage, a bias control voltage and a highest power efficiency; and transmitting selected values of the supply control voltage and the bias control voltage to supply control circuitry and bias control circuitry.

Abstract: Open-Loop RF Transmitter Output Power Control for Increased Power Efficiency (NC#97507) system includes microprocessor, battery, bias control circuitry, supply control circuitry and power amplifier. Microprocessor receives desired RF output power and battery voltage value and transmits bias control voltage and supply control voltage. Bias control circuitry is operatively coupled to microprocessor and receives bias control voltage and transmits bias output voltage. Supply control circuitry is operatively coupled to battery and microprocessor, and receives battery voltage and supply control voltage, and transmits supply collector voltage. Power amplifier is operatively coupled to supply control circuitry and bias control circuitry via inductor, and receives supply collector voltage and bias output voltage, and transmits RF output signal in response to RF input signal, supply collector voltage and bias output voltage.