A circuit board includes a substrate having an end surface, and a principal surface on which an electronic component is mounted, a first region, provided on the principal surface, and coated with a moistureproof agent, a second region, provided on the principal surface, and prohibited from being coated with the moistureproof agent, and a groove having two ends, formed in the principal surface, between the first region and the second region. The two ends of the groove reach the end surface of the substrate. The groove includes a guiding part, configured to guide the moistureproof agent overflowing from the first region into the groove, provided at a portion of the groove farthest away from the end surface.

A flexible printed circuit includes: a chip component serving as an electronic component having a first electrode and the like; a base film; a conductive first pattern layer which is laminated on a portion of the base film and has a bonding region to which the electrode is, for example, soldered; and a coverlay laminated on the base film or the first pattern layer via an adhesive and having an opening for externally exposing a portion of the first pattern layer including the bonding region, and the chip component. The first pattern layer has a groove that opens in a range between the bonding region and an edge of the opening on a surface of the first pattern layer.

Disclosed herein is a microcontroller board for the learning and practice of coding. In the microcontroller board, a platform area (S1) including a platform circuit board (10) in which a microcontroller is provided and module areas (S2) each having a cut line and including a module circuit board (20) are divided and formed on a single board array (S), corresponding header socket holes H are formed in the platform area (S1) including the platform circuit board (10) and the module areas (S2) on both sides of each of the cut lines, a plurality of machine holes (30) is provided along each of the cut lines between the header socket holes (H), via holes (40) are formed by plating the inner circumferential surfaces of the machine holes (30) with metal layers (35) in order to conduct electricity, and V-cut grooves (50) are formed along each of the cut lines.

A flexible printed circuit board and a display touch apparatus are provided. The flexible printed circuit board includes a binding terminal region, a first circuit region and a second circuit region; the binding terminal region includes multiple terminals, the first circuit region includes a driver circuit, multiple first signal lines, multiple second signal lines, and multiple third signal lines, and the second circuit region includes an external connector; first ends of the multiple first signal lines, the multiple second signal lines and the multiple third signal lines are respectively connected to the terminals of the binding terminal region; second ends of the multiple first signal lines and the multiple second signal lines are respectively connected to the driver circuit; and second ends of the multiple third signal lines are connected to the connector.

A system may include a circuit board comprising a plurality of electrically-conductive layers separated and supported by layers of insulating material laminated together, wherein the plurality of electrically-conductive layers comprises a ground plane and the layers of insulating material comprise a surface layer having one or more openings through which the ground plane is exposed through the one or more openings. The system may also include a plurality of electrically-conductive pads formed on a surface of the surface layer and a cable comprising a first signal conductor mechanically contacted to a first pad of the plurality of electrically-conductive pads and a first drain conductor mechanically contacted to the ground plane through the one or more openings.

A display device includes a display panel, a first circuit board, a control unit disposed on the first circuit board, a second circuit board, and a coupling film which electrically couples the control unit and the second circuit board to each other. The coupling film includes a first coupling part including a first region attached to the first circuit board, and a second region overlapping the display panel when viewed in a thickness direction of the display panel, a second coupling part including a third region attached to the second circuit board, and a fourth region overlapping the display panel when viewed in the thickness direction of the display panel, and a third coupling part coupled to each of the second region and the fourth region to electrically couple the first coupling part and the second coupling part to each other.

A flexible circuit (FC) and a method of forming the FC each include providing a first dielectric layer, applying a plurality of conductive circuit traces that are substantially parallel to each other to the first dielectric layer, providing a second dielectric layer atop the first dielectric layer and the plurality of conductive circuit traces to form a third dielectric layer having the plurality of conductive traces disposed therein and being configured to support and insulate the plurality of conductive traces, and forming a plurality of channels extending at least partially through a thickness of the third dielectric layer, wherein the plurality of channels are arranged between the plurality of conductive circuit traces and substantially parallel thereto and are configured to provide increased flexibility of the FC.

A circuit board assembly and electronic device are provided that improve the reliability of the connection between circuit boards and electronic components. The circuit board assembly includes a first circuit board, including a first side surface and a first sidewall pad, where the first sidewall pad is disposed on the first side surface, a second circuit board, fastened to the first circuit board, where the first sidewall pad is located at a position close to the second circuit board, and sidewall solder, adhered to the first sidewall pad and the second circuit board.

The invention pertains to a method for the bonding of a component embedded into a printed circuit board exhibiting the following steps: Provision of a core exhibiting at least one insulating layer and at least one conductor layer applied to the insulating layer, Embedding of at least one component into a recess of the insulating layer, wherein the contacts of the component are essentially situated in the plane of an outer surface of the core exhibiting the at least one conductor layer, Application of a photoimageable resist onto the one outer surface of the core on which the component is arranged, while filling the spaces between the contacts of the component, Clearing of end faces of the contacts and of the areas of the conductor layer covered by the photoimageable resist by exposing and developing the photoimageable resist, by application of a semi-additive process, deposition of a layer of conductor material onto the cleared end faces of the contacts and the cleared areas of the conductor layer and formation of a conductor pattern on at least the one outer surface of the core on which the component is arranged, as well as the interconnecting paths between the contacts and the conductor pattern, and Removal of the areas of the conductor layer not belonging to the conductor pattern.

An adapter board is described having a substrate having a width, a length and a depth and at least one electrical component placed one of within the substrate and on a surface of the substrate. The adapter board may also have a first pad positioned on the substrate, the first pad connected to the at least one electrical component through a first via. The adapter board may also have a second pad positioned on the substrate, the second pad connected to the at least one electrical component through a second via, wherein at least a portion of the adapter board is configured through an additive manufacturing process and wherein the substrate is configured to be installed within a downhole tool.