Abstract: An electronic device that includes processing circuitry configured to generate a frame of image data that has a frame duration is provided. The electronic device includes a display that has a plurality of pixels. Each of the plurality of pixels displays image data from the frame of image data for a pixel emission period that is less than the frame duration. A first pixel of a column of pixels of the plurality of pixels begins displaying the image data from the frame of image data at a first time for a first duration. A second pixel of the column of pixels that is adjacent to the first pixel begins displaying the image data from the frame of image data at a second time for a second duration. The first and second durations are equal to the pixel emission period. The second time begins after the first duration of time.

Abstract: Apparatus and methods are disclosed for control systems for improving stability of electrical grids by temporarily reducing voltage output of electrical generators responsive to transient events on an electrical grid. In one example of the disclosed technology, a controller is coupled is to an automatic voltage regulator, which in turn adjusts excitation current of an electrical generator responsive to changes in frequency detected for the electrical grid. Reducing the output voltage temporarily allows for smaller generators to provide power to the microgrid. Methods for selecting parameters determining how the controller generates a regulation signal used to adjust the excitation current are further disclosed.

Abstract: An electronic device is provided. The electronic device includes a display that is configured to show content that includes a plurality of frames. The plurality of frames includes a first frame that is associated with a pre-transition value. The plurality of frames also includes a second frame that is associated with a current frame value that corresponds to a first luminance. Additionally, the electronic device is configured to determine an overdriven current frame value corresponding to a second luminance that is greater than the first luminance. The electronic device is also configured to display the second frame using the overdriven current frame value.

Abstract: Systems and methods reduce likelihood of hysteresis that reduces perceived image quality of a subsequent image frame by toggling the display pixels to relax the display pixels by overwriting previous image frame data. During non-emission periods of the pixels, the pixels may be pre-toggled or exercised to improve response time and accuracy of the pixel. Data for pixels being programmed may also be used to pre-toggle other pixels reducing overhead but increasing cross-talk. Since the amount of cross-talk is related to content of the pixels being pre-toggled, a line buffer may be used to store image data for the pixels being pre-toggled. This stored image data may be used to determine how much pre-compensation is to be applied to data for the pixels being programmed. In other words, an amount of compensation applied is based at least in part on the content (e.g., greyscale levels) of the image data.

Abstract: An electronic device is provided. The electronic device includes a display that is configured to show content that includes a plurality of frames. The plurality of frames includes a first frame that is associated with a pre-transition value. The plurality of frames also includes a second frame that is associated with a current frame value that corresponds to a first luminance. Additionally, the electronic device is configured to determine an overdriven current frame value corresponding to a second luminance that is greater than the first luminance. The electronic device is also configured to display the second frame using the overdriven current frame value.

Abstract: A method employing an intuitive physical slider, or graphical computer display of a slider, to generate a single input value for use in generating operating set points (typically comprising dispatch and droop settings) for each of a multiplicity of energy resources in a microgrid to achieve a predetermined operational goal, such as maximizing resiliency or efficiency, or minimizing emissions. The single input value may be selected to maximize the resiliency of the microgrid, using a minimized droop when the microgrid encounters either a decrease in energy resources or an abrupt increase in end-user loads. Alternatively, the single input value may maximize the efficiency of the microgrid. Other operational goals may also be achieved with different settings of the single input value.

Abstract: Systems and methods reduce likelihood of hysteresis that reduces perceived image quality of a subsequent image frame by toggling the display pixels to relax the display pixels by overwriting previous image frame data. During non-emission periods of the pixels, the pixels may be pre-toggled or exercised to improve response time and accuracy of the pixel. Data for pixels being programmed may also be used to pre-toggle other pixels reducing overhead but increasing cross-talk. Since the amount of cross-talk is related to content of the pixels being pre-toggled, a line buffer may be used to store image data for the pixels being pre-toggled. This stored image data may be used to determine how much pre-compensation is to be applied to data for the pixels being programmed. In other words, an amount of compensation applied is based at least in part on the content (e.g., greyscale levels) of the image data.

Abstract: Embodiments of a touch-sensitive display device are disclosed herein. According to a first aspect, a touch-sensitive display device comprises an electrode matrix including transmit electrodes and receive electrodes; a conductive plane; and a controller configured to cause a transmit electrode driver to drive the transmit electrodes in a mutual capacitance mode. The controller is configured to cause the transmit electrodes, the receive electrodes, and the conductive plane to be connected to a common charging voltage during charge periods of a self-capacitance mode; to, during discharge periods of the self-capacitance mode that alternate with the charge periods, cause the transmit electrodes, the receive electrodes, and the conductive plane to be connected to a common reference voltage; and to, during the discharge periods, cause the transmit electrodes and the receive electrodes to be coupled to receive circuitry configured to measure self-capacitance of the transmit electrodes and the receive electrodes.

Abstract: Aspects of the subject technology relate to pulsed backlight operation for a display backlight. Backlight pulse patterns are provided that include steady state pulse patterns to be applied during operation of a liquid crystal display unit of the display at a corresponding frame rate. The backlight pulse patterns can be arranged to prevent visible artifacts such as flicker or strobing, particularly at or near a transition between LCD frame rates.

Abstract: An electronic device that includes processing circuitry configured to generate a frame of image data that has a frame duration is provided. The electronic device includes a display that has a plurality of pixels. Each of the plurality of pixels displays image data from the frame of image data for a pixel emission period that is less than the frame duration. A first pixel of a column of pixels of the plurality of pixels begins displaying the image data from the frame of image data at a first time for a first duration. A second pixel of the column of pixels that is adjacent to the first pixel begins displaying the image data from the frame of image data at a second time for a second duration. The first and second durations are equal to the pixel emission period. The second time begins after the first duration of time.

Abstract: Apparatus and methods are disclosed for control systems for improving stability of electrical grids by temporarily reducing voltage output of electrical generators responsive to transient events on an electrical grid. In one example of the disclosed technology, a controller is coupled is to an automatic voltage regulator, which in turn adjusts excitation current of an electrical generator responsive to changes in frequency detected for the electrical grid. Reducing the output voltage temporarily allows for smaller generators to provide power to the microgrid. Methods for selecting parameters determining how the controller generates a regulation signal used to adjust the excitation current are further disclosed.

Abstract: An electronic device is provided. The electronic device includes a display that is configured to show content that includes a plurality of frames. The plurality of frames includes a first frame that is associated with a pre-transition value. The plurality of frames also includes a second frame that is associated with a current frame value that corresponds to a first luminance. Additionally, the electronic device is configured to determine an overdriven current frame value corresponding to a second luminance that is greater than the first luminance. The electronic device is also configured to display the second frame using the overdriven current frame value.

Abstract: Examples are described for touch-sensitive displays in which ground references for associated electronics are isolated from one another. In one example, a touch-sensitive display includes a display panel, and a touch sensor, the touch sensor including a receive electrode, the touch sensor including a transmit electrode, the receive electrode and the transmit electrode overlaying the display panel, and wherein a ground reference of the receive and/or the transmit electrode is isolated from a ground reference of the display panel, thereby creating a transmission-inhibiting communication boundary between the display panel and the touch sensor, the touch sensor communicatively connected to the display panel so as to exchange data between ground domains separated by the boundary.

Abstract: An electronic device is provided. The electronic device includes a display that is configured to show content that includes a plurality of frames. The plurality of frames includes a first frame that is associated with a pre-transition value. The plurality of frames also includes a second frame that is associated with a current frame value that corresponds to a first luminance. Additionally, the electronic device is configured to determine an overdriven current frame value corresponding to a second luminance that is greater than the first luminance. The electronic device is also configured to display the second frame using the overdriven current frame value.

Abstract: Examples are disclosed herein that relate to hover sensing. One example provides a hover sensor comprising an electrode array including a first electrode subset and a second electrode subset, each electrode in the first electrode subset coupled to a corresponding electrode in the second electrode subset at a respective node and separated from the corresponding electrode by a gap, a charge circuit configured to charge the first electrode subset substantially oppositely about a reference voltage to the second electrode subset, an integration circuit configured to, for each respective node, store a net charge on a capacitor and provide an output voltage based on the net charge stored on the capacitor, and a controller. The controller is configured to indicate a presence of a hover object responsive to identifying at least a threshold voltage change based on a sample of the output voltage.

Abstract: Examples are described for touch-sensitive displays in which ground references for associated electronics are isolated from one another. In one example, a touch-sensitive display includes a display panel, and a touch sensor, the touch sensor including a receive electrode, the touch sensor including a transmit electrode, the receive electrode and the transmit electrode overlaying the display panel, and wherein a ground reference of the receive and/or the transmit electrode is isolated from a ground reference of the display panel, thereby creating a transmission-inhibiting communication boundary between the display panel and the touch sensor, the touch sensor communicatively connected to the display panel so as to exchange data between ground domains separated by the boundary.

Abstract: Examples are disclosed herein that relate to touch and force sensing. One example provides a touch-sensitive display device comprising a transmit electrode array; a receive electrode array; a conductive plane configured such that the transmit and receive electrode arrays and the conductive plane resiliently deflect relative to one another in response to applied force; and a controller. The controller may be configured to (1) switch the conductive plane between a first electrical state and a second electrical state while causing a transmit electrode driver to drive the transmit electrode array, (2) receive a first output and a second output from the receive electrode array corresponding respectively to the first and second electrical states, and (3) determine a location of a touch input and an applied force of the touch input based on the first and second outputs.

Abstract: Embodiments of a touch-sensitive display device are disclosed herein. According to a first aspect, a touch-sensitive display device comprises an electrode matrix including transmit electrodes and receive electrodes; a conductive plane; and a controller configured to cause a transmit electrode driver to drive the transmit electrodes in a mutual capacitance mode. The controller is configured to cause the transmit electrodes, the receive electrodes, and the conductive plane to be connected to a common charging voltage during charge periods of a self-capacitance mode; to, during discharge periods of the self-capacitance mode that alternate with the charge periods, cause the transmit electrodes, the receive electrodes, and the conductive plane to be connected to a common reference voltage; and to, during the discharge periods, cause the transmit electrodes and the receive electrodes to be coupled to receive circuitry configured to measure self-capacitance of the transmit electrodes and the receive electrodes.

Abstract: Examples are disclosed herein that relate to hover sensing. One example provides a hover sensor comprising an electrode array including a first electrode subset and a second electrode subset, each electrode in the first electrode subset coupled to a corresponding electrode in the second electrode subset at a respective node and separated from the corresponding electrode by a gap, a charge circuit configured to charge the first electrode subset substantially oppositely about a reference voltage to the second electrode subset, an integration circuit configured to, for each respective node, store a net charge on a capacitor and provide an output voltage based on the net charge stored on the capacitor, and a controller. The controller is configured to indicate a presence of a hover object responsive to identifying at least a threshold voltage change based on a sample of the output voltage.