Abstract: A method for an auxiliary device of an auxiliary resonant commutated pole inverter (ARCPI) to determine a boosting time of the ARCPI is provided. The auxiliary device includes an auxiliary switch path that uses a resonant inductor with at least one saturable inductor. The method includes: calculating, by a processor of the auxiliary device, a first boosting time in the auxiliary switch path based on a theoretical resonance inductance and a voltage that are applied to the resonant inductor; determining, by the processor, a second boosting time in the auxiliary switch path based on a look-up table; and determining, by the processor, the boosting time in the auxiliary switch path based on the first boosting time and the second boosting time. The method further includes controlling, by the processor, boosting current of the ARCPI based on the boosting time in the auxiliary switch path.

Abstract: The technology provides a computing device having a human presence sensor module. An image sensor of the human presence sensor module captures imagery, and the imagery is not disseminated outside of the human presence sensor module to another part of the computing device. One or more machine learning models, each trained to identify whether one or more persons are present in the imagery, are retrieved from memory within the human presence sensor module. The imagery received from the image sensor is processed using the one or more machine learning models to determine whether one or more persons are present in the imagery. Upon detection that one or more persons are present in the imagery, the human presence sensor module issues a signal to an operating system of the computing device so that the computing device can respond to that presence by performing one or more actions.

Abstract: An exemplary liquid crystal display device (200) includes: a first substrate, the first substrate including a parallel scan lines (201) and parallel data lines orthogonal to the scan lines (202); pixel electrodes (203); switches (211) each positioned near a crossing of a corresponding scan line and a corresponding data line, a first terminal of each switch being coupled to a scan line, a second terminal of the switch being coupled to a data line, and a third terminal of the switch being coupled to a corresponding pixel electrodes first data memory units (241), each of which outputs voltage signals to a corresponding pixel electrode during a time period in a frame; and second data memory units (242), each of which outputs voltage signals to the pixel electrode during another time period in the same frame.

Abstract: An exemplary display system (400) includes an image compensating source disposed in a video source (420), the image compensating source is configured to generate a compensative gray scale voltage signal according to two different images to be displayed by the display system in two sequential frame periods; and an LCD device (410) comprising an LCD panel (40), a gate driving circuit (41), a source driving circuit (42), and a control circuit (47). The LCD panel includes a plurality of pixel units and liquid crystal molecules in the pixel units. The compensating source provides the compensative gray scale voltage signal to the source driving circuit via the control circuit, and the source driving circuit provides corresponding compensative gray scale voltages to the pixel units in order to drive the liquid crystal molecules in the pixel units to twist when the gate driving circuit scans the liquid crystal display panel.

Abstract: An exemplary liquid crystal display device (1) includes a first substrate (3), a second substrate (2) facing the first substrate, and a liquid crystal layer (4) sandwiched between the first substrate and the second substrate. The first substrate includes a plurality of scan lines (11); a plurality of first and second parallel data lines (12, 22) orthogonal to the scan lines; a plurality of first and second thin film transistors (14, 24), positioned near a crossing of a corresponding scan line and a corresponding first data line, respectively; a plurality of first and second pixel electrodes (15, 25) electrically coupled to the first and second thin film transistors, respectively; a plurality of first and second static display units (19, 29) for providing voltage to the first and second pixel electrodes in a static display mode.

Abstract: An exemplary liquid crystal display (600) includes a liquid crystal panel, a scanning driving circuit (61), a compensation circuit (68), a control circuit (67), and a signal line driving circuit (62). The liquid crystal panel includes a first substrate, a second substrate opposite to the first substrate, and a liquid crystal layer sandwiched between the first and second substrates. The first substrate includes a plurality of scanning lines (63) that are parallel to each other and that each extend along a first direction, and a plurality of signal lines (64) that are parallel to each other and that each extend along a second direction orthogonal to the first direction. The scanning driving circuit is connected to the scanning lines, and continuously scans the same scanning lines twice in a frame time. The compensation circuit generates first signals. The control circuit generates gradation signals corresponding to the second frame image data.

Abstract: A method for driving an active matrix liquid crystal display (LCD) (200) includes: dividing a frame time into a first period and a second period; defining a gradation voltage that makes the light transmission of a pixel unit accumulated in the first period correspond to image data of an external circuit; defining a black-inserting voltage which corresponds with a black image; applying the gradation voltage to pixel electrodes (203) of pixel units of the LCD when the gate lines (201) are scanned by a gate driver (210) of the LCD in the first period; applying the black-inserting voltage to the pixel electrodes of the pixel units when the gate lines are scanned by the gate driver in the second period; and turning off a backlight of the LCD in the second period.

Abstract: A driving method for an active matrix liquid crystal display panel includes the following steps. First, a frame period is divided into a display period (t1) and a black insertion period (tr). A gray-scale voltage is generated according to a desired corresponding light transmittance of each pixel of the liquid crystal display panel; and during the display period, the gray-scale voltage is supplied to a corresponding pixel electrode of the liquid crystal display panel. Then during the black insertion period, a restoring voltage Vh is supplied to the pixel electrode, so that the pixel is returned to an initial black state. Accordingly, the quality of motion pictures of the liquid crystal display panel is good.