A component carrier includes a stack with at least one electrically conductive layer structure and at least one electrically insulating layer structure. At least one electrically insulating layer structure has at least partly tapering through holes filled substantially completely with an electrically conductive filling. The at least one electrically conductive layer structure and the electrically conductive filling are made of the same material. In addition, different ones of the through holes of one electrically insulating layer structure are tapering in opposite directions.

An extensible and contractible wiring board includes first and second extensible and contractible wiring substrates formed by respective wiring at extensible and contractible substrates. Each of the first and second extensible and contractible wiring substrates has a first end having functional units and an intermediate wiring portion, with the wiring and the functional units of the first and second extensible and contractible wiring substrates not electrically connected. Moreover, the first and second extensible and contractible wiring substrates are electrically independent extensible and contractible wiring substrates, and the wirings and the functional units do not overlap at the first ends of the first and second extensible and contractible wiring substrates in top view of the extensible and contractible wiring board, and the intermediate wiring portions of the first and second extensible and contractible wiring substrates overlap in top view of the extensible and contractible wiring board.

A display module is provided. The display module includes: a display panel, a light control panel, at least one first circuit board for the display panel, and at least one second circuit board for the light control panel. The display panel and the light control panel are stacked, the display panel is on a light-emitting side of the light control panel, a light-emitting surface of the display panel is on a first surface, and at least part of an orthographic projection of any one of the at least one first circuit board on the first surface does not overlap with an orthographic projection of the at least one second circuit board on the first surface in a direction perpendicular to the first surface.

A display device includes a display panel including first pads in a first row and second pads in a second row, a driving circuit board, a first connection circuit board including a first output portion on which first output pads bonded to the first pads of the display panel are disposed, a first input portion on which first input pads bonded to the driving circuit board are disposed, and a first protruding portion, and a second connection circuit board including a second output portion which overlap at least a portion of the first output portion and on which second output pads bonded to the second pads of the display panel are disposed, and a second input portion on which second input pads bonded to the driving circuit board are disposed. At least a portion of the first protruding portion is disposed on the second input portion.

The present disclosure provides a wireless sensing device. In an embodiment, the wireless sensing device includes (A) a button cell. The button cell has a positive electrode and a negative electrode. The device includes (B) a first printed circuit board (IPCB) located on a top surface of the button cell. The IPCB has a first contact and a second contact electrically connected to respective positive electrode and negative electrode of the button cell. The IPCB includes (i) a processor, and (ii) a wireless communication component (WCC). Each of the (i) processor, and (ii) WCC are electrically connected to the IPCB. The device includes (C) a sensor module. The sensor module includes a second PCB (2PCB) and one or more sensor chips electrically connected to the 2PCB. (D) The device has a length from 10 mm to 30 mm, a thickness from 3 mm to 10 mm and a width from 10 mm to 30 mm.

The present disclosure provides a circuit board and a method for manufacturing the circuit board. The circuit board may include: a base board, an embedded component, and an attached component. The base board may define a groove, the embedded component can be disposed in the groove. The attached component can be attached to at least one surface of the base board and connected to the embedded component.

Provided are a flexible printed circuit board and a display device. The flexible printed circuit board comprises a main flexible printed circuit board and a connection flexible printed circuit board having different outlines. Both printed circuit boards are single-layer boards or double-layer boards. The main flexible printed circuit board comprises a bonding region, a device mounting region, a first connection region and signal lines. The signal lines include a first signal line positioned between the device mounting region and the first connection region, and a second signal line positioned between the device mounting region and the bonding region. The connection flexible printed circuit board comprises a second connection region, a third connection region and a third signal line positioned between the second connection region and the third connection region. The two flexible printed circuit boards are connected by means of the first connection region and the second connection region. An orthographic projection of the third signal line on the main flexible printed circuit board overlaps with the second signal line. In an overlapping region, an electromagnetic shielding structure is at least provided at one side of the main flexible printed circuit board facing the connection flexible printed circuit board or at one side of the connection flexible printed circuit board facing the main flexible printed circuit board.

An electro-optical panel including a display region includes a first terminal group including a plurality of first terminals arranged along a first side of a liquid crystal panel; and a second terminal group disposed between the first terminal group and the display region and including a plurality of second terminals arranged along the first side, in which the number of the plurality of second terminals is smaller than the number of the plurality of first terminals.

A separable and reconnectable connector for semiconductor devices is provided that is scalable for devices having very small contact pitch. Connectors of the present disclosure include signal pins shielded by pins electrically-coupled to ground. One or more signal pins in a contact array are electrically-shielded by at least one ground pin coupled to a ground plane. Embodiments thereby provide signal pins, either single-ended or a differential pair, usable to transmit signals with reduced noise or cross-talk and thus improved signal integrity. Embodiments further provide inner ground planes coupled to connector ground pins to shield pairs of differential signal pins without increasing the size of the connector. Inner grounding layers can be formed within isolation substrates incorporated into connector embodiments between adjacent pairs of signal pins. These buried ground layers provide additional crosstalk isolation in close proximity to signal pins, resulting in improved signal integrity in a significantly reduced space.

A connection structure embedded substrate includes: a printed circuit board including a plurality of first insulating layers and a plurality of first wiring layers, respectively disposed on or between the plurality of first insulating layers; and a connection structure disposed in the printed circuit board and including a plurality of internal insulating layers and a plurality of internal wiring layers, respectively disposed on or between the plurality of internal insulating layers. Among the plurality of internal wiring layers, an internal wiring layer disposed in one surface of the connection structure is in contact with one surface of a first insulating layer, among the plurality of first insulating layers.