An open concept computer cart has a frame, a lower computer storage shelf supported by the frame, an upper computer storage shelf supported by the frame, and a forward-facing brick storage area formed vertically intermediate the upper and lower computer storage shelves. The upper and lower computer storage shelves are rearwardly inclined to prevent computers stored thereon from sliding off of the shelves. A single wiring retention strip is formed along a front surface of the open concept computer cart, and a power outlet strip is formed along a rear of the brick storage area. The wiring retention strip has wire retention cutouts formed along its length to retain charging tethers for computers stored on both the upper and lower computer storage shelves.

A computer for an aircraft includes a dock part installed fixedly in the aircraft: configured so as to be connected to at least one avionics equipment by way of a bidirectional data bus, comprising a docking station, a server part installed removably on the docking station of the dock part, configured so as to exchange data and signals with the dock part through a connector, and configured so as to be connected to at least one non-avionics equipment through at least one communications link, the dock part being configured so as to implement a pairing mechanism with the server part in order to authorize or prevent the transmission of data between the server part and said at least one avionics equipment.

An external indicator assembly for a central processing unit (CPU) disposed within an equipment cabinet, including: an internal fitting adapted to be disposed adjacent to indicator lights associated with the CPU; an external fitting adapted to be coupled to or disposed through an external surface of the equipment cabinet; and one or more optical fibers adapted to be coupled between the internal fitting and the external fitting such that light from the indicator lights is transmitted from the CPU disposed within the equipment cabinet external to the equipment cabinet such that the light is visible to a person external to the equipment cabinet. This allows the person to visually assess the status or power-down cycling of the CPU during a shutdown or restart process without or before opening the equipment cabinet, thereby preventing corruption of the CPU and assuring personal safety by avoiding contact with powered components.

A docking board removably coupled to a processor board that does not function when not operatively coupled to the docking board. The docking board sends power to and receive a control signal from the processor board when operatively coupled to the processor board and does not send power and does not receive a control signal when not operatively coupled to the processor board. The docking board is removably coupled to an expansion board that performs a computer function that is not performed by the processor board and the docking board. The docking board sends power and a control signal to the expansion board when the docking board is operatively coupled to the processor board and the expansion board, and does not send power and does not send a control signal to the expansion board when the docking board is not operatively coupled to the processor board and the expansion board.

The present disclosure provides a display panel including: a panel main body including a display region, a bendable region and a binding region, wherein a plurality of signal transmission lines extending from the display region to the binding region are arranged in the bendable region; and an enhancement layer in the bendable region of the panel main body and including an electrode layer, wherein the electrode layer includes at least one auxiliary electrode, each auxiliary electrode corresponds to one of the plurality of signal transmission lines, different auxiliary electrodes correspond to different ones of the plurality of signal transmission lines, respectively, and each auxiliary electrode is electrically connected to a corresponding signal transmission line. The present disclosure further provides a flexible display device.

A first circuit board includes a positive output pin and a negative output pin of a power conversion circuit, each of which has a shape projecting from a second main surface. A second circuit board has a positive through via and a negative through via, each of which has a shape extending between a third main surface and a fourth main surface. The second main surface of the first circuit board and the third main surface of the second circuit board are physically in close contact with each other. The positive output pin is inserted through the positive through via to reach the fourth main surface. The negative output pin is inserted through the negative through via in such a manner as to reach the fourth main surface. The load receives a current supplied from the power conversion circuit through the positive output pin and the negative output pin.

An apparatus that includes an interposer, first power connectors that are disposed on a first surface and that receive respective power inputs from one or more power sources, second power connectors that are disposed on the second surface and that receive a respective third power connecter of an integrated circuit when the integrated circuit is mounted on the second surface of the interposer, a plurality of switches formed within the interposer, control circuitry formed within the interposer, and a sequencer circuit coupled to the control input of the control circuitry and that generates a different values for a control input signal that causes the control logic of the control circuitry to generate a corresponding set of switch signals, and the plurality of different values for the control input signal are generated according to a predefined sequence to provide power to the integrated circuit according to power up sequence.

The present disclosure relates to a display apparatus. The display apparatus may include a display panel, a peripheral region, an electronic component, and a gap-fill layer. The display panel defines a display region. The peripheral region is adjacent to the display region. The peripheral region includes lines and pads. The lines are disposed in the peripheral region, and the pads are connected to the lines. The electronic component includes connecting pads in contact with the pads. The gap-fill layer is between the display panel and the electronic component, between the connection pads, between the pads, and in the openings. Each of the pads may overlap at least two pads of the connection pads, and the openings may overlap between the connection pads, when viewed in a plan view.

The present disclosure provides a wiring structure, a display substrate and a display device, and belongs to the field of display technology. The wiring structure of the present disclosure comprises a body portion provided with hollow patterns; the body portion has a first side and a second side which are provided opposite to each other along an extending direction of the wiring structure, and both the first and second sides are wavy; the body portion comprises a plurality of conductive elements sequentially connected along the extending direction of the wiring structure; and in each conductive element, a length of a protruding portion on the first side in the extending direction of the wiring structure is different from that of a protruding portion on the second side in the extending direction of the wiring structure.

The disclosure provides a system of providing power to a chip on a mainboard, including: a first power supply, located on the mainboard, and configured to receive a first voltage and to provide a second voltage; and a second power supply and a third power supply, located on the mainboard, wherein the second power supply and the third power supply are electrically connected to the first power supply; so as to receive the second voltage, the second power supply is disposed at a first side of the chip, the third power supply is disposed at a second side of the chip, the second power supply provides a third voltage to the chip, and the third power supply provides a fourth voltage to the chip.