Abstract: A display device includes an array of driver circuits distributed in a display area for driving corresponding LED zones and an array of sensor circuits distributed in the display area for sensing conditions associated with the driver circuits or LED zones. Various communication protocols and connectivity configurations may be employed to communicate driver control signals to the driver circuits and to obtain readback data from the sensors. A control circuit adjusts operation of the display device based on sensor data obtained from the sensor.

Abstract: Embodiments relate to a display device that includes a control circuit, an array of light emitting diode (LED) zones, and an array of zone integrated circuits that are distributed in the display area. The zone integrated circuits may comprise integrated LED and driver circuits with embedded sensors or the zone integrated circuits may comprise dedicated sensor devices. The zone integrated circuits are arranged in groups that are coupled to a shared single wire communication line. The control circuit provides control signals that control the driver circuits to drive the LED zones and may provide commands to request feedback data from the zone integrated circuits. Responsive to the commands, the zone integrated circuits output feedback data that is provided to the control circuit via the shared single wire communication line.

Abstract: A display device includes an array of driver circuits distributed in a display area for driving corresponding LED zones and an array of sensor circuits distributed in the display area for sensing conditions associated with the driver circuits or LED zones. Various communication protocols and connectivity configurations may be employed to communicate driver control signals to the driver circuits and to obtain readback data from the sensors. A control circuit adjusts operation of the display device based on sensor data obtained from the sensor.

Abstract: A power line communication driver circuit drives a power communication line with a power line communication signal that supplies both power and control data to a plurality of electronic devices. The power line communication driver circuit includes a ramp generator that receives an input signal encoding digital data and generates a ramp signal that switches between a low non-zero ramp voltage and a high ramp voltage to encode the digital data. The power line communication driver circuit furthermore includes a buffer circuit that receives and buffers the ramp signal to generate the power line communication signal. In one application, the power line communication driver circuit may drive a group of zone integrated circuits that include driver circuits for driving respective LED zones of a display device.

Abstract: A display device comprises a control circuit and a plurality of LED channels coupled to a shared supply voltage. The control circuit obtains respective brightness levels for each of the LED channels and determines, based on the brightness levels, a group current level sufficient to drive all of the LED channels. The control circuit also determines respective duty cycles for each of the LED channels that will achieve the respective brightness levels when each of the LED channels are driven with the group current level. The control circuit configures driver circuits to drive the LED channels in accordance with the group current level and the respective duty cycles. The control circuit may furthermore obtain sensed channel voltages associated with each of the LED channels, and configure the shared voltage supply based on the sensed channel voltages to a voltage level sufficient to drive all of the LED channels.

Abstract: Method and device for gauging an electronic apparatus are disclosed. The method comprising acts of processing measured data sets by a learned neural network to generate a gauging result, and updating neural coefficients of the learned neural network with a reference data for more accurate prediction. The learned neural network is trained with known algorithm or known data provided by the manufacture or collected from others. The device comprises sensors and controller. The sensors are configured to sense the electronic apparatus to generate the measured data sets. The controller has the learned neural network and a error feedback unit. The neural network generates the gauging result. The error feedback unit generates a reference data sensed from the electronic apparatus to the neural network for updating neural coefficients of the neural network for more accurate prediction.

Abstract: Embodiments relate to a display device that includes a control circuit, an array of light emitting diode (LED) zones, and an array of driver circuits that are distributed in the display area. An integrated LED and driver circuit includes one or more LEDs of a LED zone and one or more driver circuits integrated on a substrate in a single package with the LED and driver circuit vertically stacked over a substrate. An addressing scheme configures addresses of the driver circuits using address lines that connect between adjacent driver circuits. Control data is provided to the driver circuits via a power line communication signal that provides both a supply voltage and digital data modulated onto the supply voltage.

Abstract: Embodiments relate to a display device that includes a control circuit, an array of light emitting diode (LED) zones, and an array of driver circuits that are distributed in the display area. An integrated LED and driver circuit includes one or more LEDs of a LED zone and one or more driver circuits integrated on a substrate in a single package with the LED and driver circuit vertically stacked over a substrate. An addressing scheme configures addresses of the driver circuits using address lines that connect between adjacent driver circuits. Control data is provided to the driver circuits via a power line communication signal that provides both a supply voltage and digital data modulated onto the supply voltage.

Abstract: Embodiments relate to a display device that includes a control circuit, an array of light emitting diode (LED) zones, and an array of driver circuits that are distributed in the display area. An integrated LED and driver circuit includes one or more LEDs of a LED zone and one or more driver circuits integrated on a substrate in a single package with the LED and driver circuit vertically stacked over a substrate. An addressing scheme configures addresses of the driver circuits using address lines that connect between adjacent driver circuits. Control data is provided to the driver circuits via a power line communication signal that provides both a supply voltage and digital data modulated onto the supply voltage.

Abstract: Embodiments relate to a display device that includes a control circuit, an array of light emitting diode (LED) zones, and an array of driver circuits that are distributed in the display area. The driver circuits are arranged in groups that are coupled to each other and to the control circuit in a serial communication chain via serial communication lines. The group of driver circuits are also coupled in parallel to a shared multi-wire command line that provides a high-speed interface for providing the driver control signals from the control circuit. The control circuit may furthermore issue readback commands to the driver circuits via the shared multi-wire command line or the serial communication chain. In response to the commands, the driver circuits provide readback data via a readback line through the serial communication chain or via parallel connections from the driver circuits.

Abstract: A cell balancing battery module comprising: a cell string having N ports in series; a maximum and minimum finding circuit coupled with the N ports and the at least one switched capacitor comparison circuit for performing a voltage comparison procedure to find a highest voltage port number and a lowest voltage port number, the voltage comparison procedure including a plurality of voltage comparison operations using two phases of at least one switched capacitor comparison circuit; a charge and discharge connecting circuit coupled with the N ports and an inductor, and being configured to select a highest voltage port out of the N ports according to the highest voltage port number to deliver energy to the inductor, and select a lowest voltage port out of the N ports according to the lowest voltage port number to receive energy released from the inductor.

Abstract: Method and device for gauging an electronic apparatus are disclosed. The method comprising acts of processing measured data sets by a learned neural network to generate a gauging result, and updating neural coefficients of the learned neural network with a reference data for more accurate prediction. The learned neural network is trained with known algorithm or known data provided by the manufacture or collected from others. The device comprises sensors and controller. The sensors are configured to sense the electronic apparatus to generate the measured data sets. The controller has the learned neural network and a error feedback unit. The neural network generates the gauging result. The error feedback unit generates a reference data sensed from the electronic apparatus to the neural network for updating neural coefficients of the neural network for more accurate prediction.

Abstract: A fluid heating system assembly includes a first tube sheet, a second tube sheet opposite the first sheet, a plurality heat exchanger tubes, which connect the first tube sheet and the second tube sheet, and a plurality of baffles, comprising at least one plate baffle and at least one annular baffle disposed between the first tube sheet and the second tube sheet, wherein the heat exchanger tubes sealingly pass through the baffles, and wherein the tubes are arranged in a staggered ring configuration and the baffles have a baffle spacing, such that there is a substantially uniform temperature distribution and efficient exchange of thermal energy across the heat exchanger tube walls.

Abstract: A heat exchanger tube assembly comprising a first tube sheet, a second tube sheet opposite the first sheet, a plurality of heat exchanger tubes, each independently connects the first tube sheet and the second tube sheet, wherein the tubes are in a staggered ring configuration that comprises a concentric sequence of rings of decreasing diameter wherein adjacent tubes on the same ring are separated by a fixed radial separation angle and adjacent tubes on adjacent rings are staggered by rotating all the tubes within an inner ring by a fixed radial index angle, IA, relative to the next outermost tube ring.

Abstract: A device for protecting a low voltage LED direct driver comprises a rectifying stage, a major string, a minor string, a high voltage NFE, a pull-up resistor, and an avalanche unit (zener diode or equivalent component). The high voltage NFET has a gate, a drain and a source. The drain of the high voltage NFET is connected to a bottom end of the major string, the source of the high voltage NFET is connected to a top of the minor string. The pull-up resistor is connected between the gate of the high voltage NFET. The avalanche unit has a first end and a second end. The first end of the avalanche unit is connected to the gate of the high voltage NFET and the pull-up resistor. High voltage NFET is placed just above the low voltage LED direct driver and biased, which provides excellent voltage protection for the low voltage LED direct driver.

Abstract: An approach is provided for devices and methods for driving an LED light, which adjust the numbers of diodes of the LED string corresponding to the rectified AC voltage. The device comprises a power module, a LED string, a current source and a controller. The LED string has multiple LED diodes connected in series that forms a major segment and multiple minor segments. The controller is connected to the current source and the LED string, which selectively shorts the LED diodes of the minor segments. Since the number of LED diodes of the LED string is dynamically adjusted in response to the rectified voltage, the overall “on” voltage of the LED string is more closely matched to the rectified voltage, and thus the power efficiency is improved.

Abstract: The device for a LED direct driver comprises a major LED string, a minor LED string set, a pre-regulator, and a direct driver. The major LED string has multiple series-connected LED diodes which has a first end and a second end. The minor LED string set has a first end and a second end, and is formed with multiple series-connected minor strings. The first end of the minor LED string set is connected to the second of the major LED string. Each minor LED string has at least one LED diode. The direct driver is connected to the pre-regulator, the major LED string, and the minor LED string, which is configured to short out selected minor LED strings for ensuring the most efficient LED driving configuration. The pre-regulator provides a regulated voltage output. The regulated voltage output fed to the LED direct driver allows the LED direct driver to provide a constant power output with virtually no output power ripple.

Abstract: An anti-flicker circuit for an LED direct driver under low input voltage operation, the LED direct driver at least having a current source, and the anti-flicker circuit comprises a first path having a first resistor, a second path having a second resistor, a filter capacitor and a comparator having a reference voltage. The filter capacitor is connected to the first path, the second path and the current source of the LED direct driver, and discharges current via the first path. The comparator charges the filter capacitor to the current source via the second path when a voltage of the current source is below the reference voltage, wherein the RC time constant of the first path and the filter capacitor in combination with the second path and the filter capacitor is slower than a period of the flicker. As long as the RC time constant is long enough, then the changes in light output will occur slowly enough so that the deleterious effects for the flicker are eliminated.

Abstract: A controlling method for an electrical apparatus and a device thereof are provided in the present invention. The method includes the steps of: (a) providing an electrical apparatus and an AC power; (b) generating a control signal synchronized to the AC power; and (c) controlling the electrical apparatus by the control signal. The device includes a threshold detector, a phase-locked loop coupled to the threshold crossing detector and an output circuit coupled to the phase-locked loop.

Abstract: A device for protecting a low voltage LED direct driver comprises a rectifying stage, a major string, a minor string, a high voltage NFE , a pull-up resistor, and an avalanche unit (zener diode or equivalent component). The high voltage NFET has a gate, a drain and a source. The drain of the high voltage NFET is connected to a bottom end of the major string , the source of the high voltage NFET is connected to a top of the minor string. The pull-up resistor is connected between the gate of the high voltage NFET. The avalanche unit has a first end and a second end. The first end of the avalanche unit is connected to the gate of the high voltage NFET and the pull-up resistor. High voltage NFET is placed just above the low voltage LED direct driver and biased, which provides excellent voltage protection for the low voltage LED direct driver.