A pad arranging method and a pad arrangement structure for a wire bonding of a chip is provided. The method includes following steps. A soldered component and a circuit board are provided. A plurality of pads is arranged on the circuit board. a number of the pads is corresponding to a number of a plurality pins of the soldered component. The pads are disposed in a plurality of rows toward or away from the soldered component according to a predetermined arranging position, and the number of the pads on one of the rows at outer side is equal to that on one of the rows at inner side, or greater than that on one of the rows at inner side by one or more than one

This disclosure generally relates to high-speed fiber optic networks that use light signals to transmit data over a network. The disclosed subject matter includes devices and methods relating to header subassemblies and/or optoelectronic subassemblies. In some aspects, the disclosed devices and methods may relate to a header subassembly that can include: a multi-layer substrate with a bottom layer, a top layer having top thin film signal lines, and one or more intermediate layers having thick film traces between the top layer and the bottom layer, the thick film traces electrically coupled to the top thin film signal lines; and optoelectronic components positioned over the multi-layer substrate and electrically coupled with the signal lines.

An electrical contact pad for electrically contacting a connector includes a first region having a first length in a longitudinal direction, and a second region having a second length in the longitudinal direction that is greater than the first length. The first region is arranged to contact a first arm of the connector and the second region is arranged to contact a second arm of the connector. The first length being smaller than the second length results in an increase in the impedance of the electrical contact pad as compared to typical contact pads which tend to correspond to low impedance regions.

A connection body comprises a body having upper and lower surfaces, a first path and a second path. The first path has a first wired portion configured to be connected to a first core wire of a cable structure and a first terminal portion coupled to the first wired portion by a first coupling portion. The first wired portion, the first terminal portion and the first coupling portion are formed on the upper surface of the body. The second path has a second wired portion configured to be connected to a second core wire of the cable structure and a second terminal portion coupled to the second wired portion by a second coupling portion. The second wired portion is formed on the upper surface of the body. The second terminal portion is formed on the lower surface of the body.

A wiring board for a fingerprint sensor includes an insulating board including insulating layers; outer strip electrodes disposed on the insulating layer in an uppermost layer, and side by side in a first direction; inner strip electrodes disposed on the insulating layer in a next layer contacting the insulating layer in the uppermost layer, and side by side in a second direction orthogonal to the first direction; a pad electrode disposed on the insulating layer in the uppermost layer, and on the inner strip electrodes and between the outer strip electrodes; and a via conductor extending through the insulating layer in an outermost layer between the pad electrode and the inner strip electrodes and electrically connecting the pad electrode and the inner strip electrodes to each other. The via conductor has an elliptical shape that is long in the first direction in top view.

A driving chip and a display panel are provided. The display panel includes the driving chip, and a plurality of first bonding pads and a plurality of second bonding pads disposed at two opposite sides out of the driving chip. The driving chip includes a group of first input leads and a group of second input leads. There is an interval between the group of first input leads and the group of second input leads. The group of first input leads is disposed near the first bonding pads, and the group of second input leads is disposed near the second bonding pads.

The present disclosure provides a display substrate, a chip-on-film, a display apparatus and methods for manufacturing them. The display apparatus includes: a base substrate; a bonding structure disposed on the base substrate; and a chip-on-film COF, wherein the COF and a side of the bonding structure that is away from the base substrate are clamped with each other, and the COF is bonded to the side of the bonding structure that is away from the base substrate; wherein when the COF and the bonding structure are bonded, the COF contacts both a first surface and a second surface of the bonding structure at the side of the bonding structure that is away from the base substrate, wherein the first surface is parallel to the base substrate, and the second surface is at an angle with the first surface.

An electronic device includes a substrate and a flexible printed circuit board. The substrate includes a plurality of first pins disposed on the substrate. The flexible printed circuit board includes a plurality of second pins disposed on the flexible printed circuit board. The first pins and the second pins are bonded to each other to form a plurality of bonding points. The bonding points include at least one central bonding point and at least one first bonding point. The at least one central bonding point is located in a central area of the electronic device. The at least one first bonding point is located in a first area of the electronic device. The first area is located outside the central area. A line width of the at least one first bonding point is greater than a line width of the at least one central bonding point.

A switch component includes a spring plate and a cover of rubber. The cover of rubber covers at least one part of an upper surface of the spring plate. The cover of rubber includes at least one pair of supporting portions that support the spring plate.

The disclosure is related to a flexible printed circuit board. The flexible printed circuit board comprises a connecting area and a plurality of gold fingers disposed inside the connecting area, wherein the widths of the gold fingers are different. By the above manner, the disclosure is able to increase the number of the gold fingers without changing the size of the flexible printed circuit board so as to solve the impedance matching problem of the gold fingers of the flexible printed circuit board.