A multiple-damascene structure is located below a semiconductor device footprint on a printed wiring board, where the structure includes multiple recesses that containing useful devices coupled to a semiconductive device.

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.

A component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A component is embedded in the stack. A first thermally conductive block is located above and thermally connected with the component, and a second thermally conductive block is located below and thermally coupled with the component. Heat generated by the component during operation is removed via at least one of the first thermally conductive block and the second thermally conductive block.

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.

A lens module includes a holder, at least one lens, a base, a sensor, an anisotropic conductive film, a flexible circuit board, and a filling member. The filling member is arranged at a side of the sensor and received in the holder. Along a direction of an optical axis of the lens module, a distance between the side of the sensor and the anisotropic conductive film is defined as a first value, a thickness of the filling member is defined as a second value, a ratio of the second value to the first value is in a range of 0.8 to 1. An electronic device having the lens module is also provided.

To provide a wiring substrate, an electronic device, and an electronic module the size of which can be easily reduced and the strength of which can be maintained. A wiring substrate includes an insulation substrate and an electrical wiring structure. The insulation substrate includes a recess section in one surface. A frame portion of the insulation substrate that forms a side surface which connects an opened surface and a bottom surface of the recess section to each other includes a first conductive portion having a plate shape in the frame portion.

A printed circuit board according to an embodiment includes a first insulating layer, a second insulating layer disposed on the first insulating layer and including a cavity; and a pad disposed on the first insulating layer and having an upper surface exposed through the cavity; wherein the cavity includes a first part including a first inner wall; and a second part including a second inner wall under the first part; and wherein an inclination angle of the first inner wall is different from an inclination angle of the second inner wall.

A method for manufacturing a circuit board including the following steps: providing a flexible double-sided metal-clad laminate including a first metal foil, a flexible dielectric layer, and a second metal foil. A carrier is attached to the second metal foil. A first wiring layer including a first wiring region and a second wiring region is formed by the first metal foil. The first wiring region includes a first connecting pad, and the second wiring region includes a connecting pad. A plurality of rigid dielectric blocks surrounded to form an interval and a first groove exposing the first connecting pad is pressed on the flexible dielectric layer to form a rigid dielectric layer. An electronic component is fixed the first groove. The carrier is removed. The intermediate structure is bent along the interval and pressed. A second wiring layer is formed by the second metal foil.

An electronic device is disclosed. In one example, the electronic device comprises a carrier board, a metal inlay having a cavity and being arranged in the carrier board. At least one electronic component is arranged at least partially in the cavity and embedded in the carrier board. Electric contacts are located at a castellated edge of the carrier board.

A sample holder includes a base comprising a support structure and a printed circuit board (PCB) in contact with the base. The PCB includes: a dielectric; a front-surface ground (GND) formed on a front surface of the dielectric; a back-surface GND formed on a back surface of the dielectric; a through hole penetrating from the front-surface GND to the back-surface GND, the through hole in which a chip is disposed, and a conductor that electrically connects the front-surface GND and the back-surface GND on an end face of the through hole. At least a part of the base below the through hole has a cavity. The support structure that supports a surface of the chip and is electrically connected to the base. The support structure is disposed in the cavity.