A embedded passive structure, a microelectronic system, and an integrated circuit device assembly, and a method of forming the embedded passive structure. The embedded passive structure includes a base layer; a passive device attached to the base layer; a first power plane comprising metal and adjacent an upper surface of the base layer, the first power plane having a portion electrically coupled to a terminal of the passive device, wherein an upper surface of a combination of the first power plane and the passive device defines a recess; a second power plane comprising metal, the second power plane at least partially within the recess and having a lower surface that conforms with the upper surface of the combination; and a liner including a dielectric layer between the first power plane and the second power plane.

An aspect of the disclosed embodiments is a method for printed circuit board (PCB) component placement comprising: graphically displaying, on a display device, PCB design features of a PCB design; and providing a user interface control for designating one or more of the PCB design features as electrical contacts for a first selected electrical component. Other aspects are disclosed.

There is provided a method of forming a thin film-based microfluidic electronic device. The method includes: providing a first elastomeric thin film layer on a substrate; depositing a first elastomer on the first elastomeric thin film by direct ink writing to form an elastomeric structure configured to define a microfluidic channel on the first elastomeric thin film layer; providing a second elastomeric thin film layer over the elastomeric structure to cover the microfluidic channel; providing a sacrificial layer on the second elastomeric thin film; depositing liquid metal into the microfluidic channel to form a conductor in the microfluidic channel; and electrically connecting the conductor to an electronic component. The thin film-based microfluidic electronic device is a tissue or skin adhesive sensor including a skin adhesive acoustic device.

There is provided a method of forming a thin film-based microfluidic electronic device. The method includes: providing a first elastomeric thin film layer on a substrate; depositing a first elastomer on the first elastomeric thin film by direct ink writing to form an elastomeric structure configured to define a microfluidic channel on the first elastomeric thin film layer; providing a second elastomeric thin film layer over the elastomeric structure to cover the microfluidic channel; providing a sacrificial layer on the second elastomeric thin film; depositing liquid metal into the microfluidic channel to form a conductor in the microfluidic channel; and electrically connecting the conductor to an electronic component. The thin film-based microfluidic electronic device is a tissue or skin adhesive sensor including a skin adhesive acoustic device.

According to one embodiment, a metal base circuit board includes a metal base substrate, a first circuit pattern, and a first insulating layer between the metal base substrate and the first circuit pattern. The first insulating layer covers a lower surface of the first circuit pattern and at least part of a side surface of the first circuit pattern, the lower surface facing the metal base substrate, the at least part of the side surface being adjacent to the lower surface.

The present invention relates to an embedded printed circuit board including: an insulation substrate including a cavity; a sensor device disposed on the cavity; an insulating layer disposed on the insulation substrate, having an opening part exposing the sensor device; and a pad part disposed on the lower surface of the opening part exposing the sensor device.

A PCB, a method of manufacturing the PCB, and a mobile terminal are provided. The PCB includes a PCB body and a PCB element. A first surface of the PCB body is provided with a groove. The PCB element includes a connection terminal, and a part of the PCB element is arranged within the groove. The connection terminal includes a first portion arranged within the groove and a second groove arranged outside the groove, and the first portion is electrically connected to conductive layers in the PCB body.

A PCB, a method of manufacturing the PCB, and a mobile terminal are provided. The PCB includes a PCB body and a PCB element. A first surface of the PCB body is provided with a groove. The PCB element includes a connection terminal, and a part of the PCB element is arranged within the groove. The connection terminal includes a first portion arranged within the groove and a second groove arranged outside the groove, and the first portion is electrically connected to conductive layers in the PCB body.

A device component assembly including an upper support plate (USP) of glass and a lower support plate (LSP) of metal affixed to the USP, and a manufacturing method are provided. The USP and the LSP include openings of different shapes and sizes. The LSP includes gaps cut in different directions for reducing thermal expansion and tension generated during a temperature shift. Device components including optical, mechanical, electric, electronic, and optoelectronic components are mutually optically aligned and mounted on the USP and/or the LSP based on component requirements. The device components are mounted on the LSP through the openings of the USP. The optical components are affixed to the support plate(s) using a fastening material. One or more heat transfer members are affixed to the LSP for mounting the device component(s) thereon, after mutual optical alignment therebetween. The device component assembly is integrated in an optical or optoelectronic module or system.

A method for manufacturing a circuit board embeds a portion of an outer circuit layer in an outer dielectric layer which increases contact area between the outer circuit layer and the outer dielectric layer, improving adhesion between the outer circuit layer and the outer dielectric layer, and reducing a thickness of the outer circuit substrate, thereby reducing the overall thickness of the finished circuit board.