An electronic device including a base structure, a first conductive layer, a first insulating layer, a first electronic element, a second insulating layer and a second electronic element is provided. The first conductive layer comprising a first conductive part and a second conductive part is disposed on the base structure. The first insulating layer is disposed on the first conductive layer, and comprises a first hole exposing at least portion of the first conductive part. The second insulating layer comprising a second hole is disposed between the first insulating layer and the first electronic element. The second electronic element is electrically connected to the second conductive part. The first electronic element is electrically connected to the first conductive part through the second hole and the first hole. A first width of the first hole is different from a second width of the second hole.

An electronic device including a base structure, a first conductive layer, a first insulating layer, a first electronic element, a second insulating layer and a second electronic element is provided. The first conductive layer comprising a first conductive part and a second conductive part is disposed on the base structure. The first insulating layer is disposed on the first conductive layer, and comprises a first hole exposing at least portion of the first conductive part. The second insulating layer comprising a second hole is disposed between the first insulating layer and the first electronic element. The second electronic element is electrically connected to the second conductive part. The first electronic element is electrically connected to the first conductive part through the second hole and the first hole. A first width of the first hole is different from a second width of the second hole.

A computing device includes a mounting arrangement having bistate spring clips. Each bistate spring clip has a main component, elongated spring member, and protrusion. The main component moves in a first direction under a first biasing spring force when the spring clip operates in a first state and in a second direction opposite the first direction under a second biasing spring force when the spring clip operates in a second state. The spring member couples at a proximal end to the main component, extends to a distal end, and imparts a biasing spring force to the main component depending on which way it is moved. The protrusion couples to the spring member and extends into a track at the mounting outer surface. The track forces the protrusion to move in different directions as it travels along the track, which causes the spring member to correspondingly move in its different directions.

A computing device includes a mounting arrangement having bistate spring clips. Each bistate spring clip has a main component, elongated spring member, and protrusion. The main component moves in a first direction under a first biasing spring force when the spring clip operates in a first state and in a second direction opposite the first direction under a second biasing spring force when the spring clip operates in a second state. The spring member couples at a proximal end to the main component, extends to a distal end, and imparts a biasing spring force to the main component depending on which way it is moved. The protrusion couples to the spring member and extends into a track at the mounting outer surface. The track forces the protrusion to move in different directions as it travels along the track, which causes the spring member to correspondingly move in its different directions.

The invention presents an LED display device featuring a highly efficient installation method. It consists of display screens arranged in a matrix, with adjacent screens connected via a rapid assembly. This assembly includes a motor screw structure affixed to one screen and a nut structure fixed to the adjacent screen. The motor screw structure incorporates a deceleration motor and a screw fixed on the screen, while the nut structure comprises a nut fixed on the screen via a mounting plate. During assembly, power is applied only after alignment, allowing the deceleration motor to rotate the screw. The nut then adjusts the distance between screens until installation requirements are met, enhancing installation efficiency.

The invention presents an LED display device featuring a highly efficient installation method. It consists of display screens arranged in a matrix, with adjacent screens connected via a rapid assembly. This assembly includes a motor screw structure affixed to one screen and a nut structure fixed to the adjacent screen. The motor screw structure incorporates a deceleration motor and a screw fixed on the screen, while the nut structure comprises a nut fixed on the screen via a mounting plate. During assembly, power is applied only after alignment, allowing the deceleration motor to rotate the screw. The nut then adjusts the distance between screens until installation requirements are met, enhancing installation efficiency.

A modular surgical system is disclosed. The modular surgical system can include a control module, a first surgical module, and a second surgical module that are arrangeable in a stack. The control module can include a pulse generator to generate a clock pulse signals. Each of the first and second surgical modules can include a timing circuit and a delay circuit. Each timing circuit can receive the clock pulse signal and start a timer. A first delay circuit of the first surgical module can also receive the clock pulse signal and transmit a first delayed sequence signal to the timing circuit of the first module. A second delay circuit of the second surgical can also receive the first delayed sequence signal from the first delay circuit and transmit a second delayed sequence signal to the clock timer of the second surgical module.

A modular surgical system is disclosed. The modular surgical system can include a control module, a first surgical module, and a second surgical module that are arrangeable in a stack. The control module can include a pulse generator to generate a clock pulse signals. Each of the first and second surgical modules can include a timing circuit and a delay circuit. Each timing circuit can receive the clock pulse signal and start a timer. A first delay circuit of the first surgical module can also receive the clock pulse signal and transmit a first delayed sequence signal to the timing circuit of the first module. A second delay circuit of the second surgical can also receive the first delayed sequence signal from the first delay circuit and transmit a second delayed sequence signal to the clock timer of the second surgical module.