A device includes a first semiconductor chip including a first face, wherein a first contact pad is arranged over the first face. The device further includes a second semiconductor chip including a first face, wherein a first contact pad is arranged over the first face, wherein the first semiconductor chip and the second semiconductor chip are arranged such that the first face of the first semiconductor chip faces in a first direction and the first face of the second semiconductor chip faces in a second direction opposite to the first direction. The first semiconductor chip is located laterally outside of an outline of the second semiconductor chip.

The embodiment of the disclosure provides a composite layer circuit element and a manufacturing method thereof. The manufacturing method of the composite layer circuit element includes the following. A carrier is provided. A first dielectric layer is formed on the carrier, and the first dielectric layer is patterned. The carrier on which the first dielectric layer is formed is disposed on a first curved-surface mold, and the first dielectric layer is cured. A second dielectric layer is formed on the first dielectric layer. The second dielectric layer is patterned. The carrier on which the first dielectric layer and the second dielectric layer are formed is disposed on a second curved-surface mold, and the second dielectric layer is cured. A thickness of a projection of the first curved-surface mold is smaller than a thickness of a projection of the second curved-surface mold.

A component is disclosed. A component includes an elongated body, with a first end and a second end; and one or more tabs at the first end and the second end, the tabs configured to have a lower tensile strength than other regions of the component.

A method for manufacturing an electronic device is disclosed. The electronic device has a first region and a transparent region. The method includes the steps of providing a substrate, forming an electric circuit layer on the substrate at an elevated temperature, forming an opening in the transparent region and penetrating through a portion of the electric circuit layer, forming a light emitting unit on the electric circuit layer in the first region, and forming an insulating layer on the substrate. At least a part of the insulating layer is formed in the opening.

Some features pertain to a substrate that includes a first portion of the substrate including a first plurality of metal layers, a second portion of the substrate including a second plurality of metal layers, and a plurality of insulating layers configured to separate the first plurality of metal layers and the second plurality of metal layers. A first plurality of posts and a plurality of interconnects are coupled together such that the first plurality of posts and the plurality of interconnects couple the first portion of the substrate to the second portion of the substrate.

A resin multilayer substrate includes a multilayer body including resin base-material layers laminated in a thickness direction and a circuit conductor therein, an end-surface ground conductor provided directly on each end surface of the multilayer body in the thickness direction, an adhesion layer on a side surface of the multilayer body, and a side-surface ground conductor on the adhesion layer. The end-surface and side-surface ground conductors are made of a ground conductor material with a coefficient of thermal expansion whose difference from a coefficient of thermal expansion of the resin base-material layers in a plane direction is smaller than a difference from a coefficient of thermal expansion of the resin base-material layers in the thickness direction. The adhesion layer is made of a material with higher adhesiveness to the side surface of the multilayer body than adhesiveness of the ground conductor material.

The present disclosure provides a package stack structure and a method for manufacturing the same. The method is characterized by stacking coreless circuit portions on the board of an electronic component to reduce the overall thickness of the package stack structure.

A method for manufacturing a flexible circuit board is provided. The method for manufacturing a flexible circuit board includes the following steps: providing a carrier substrate, forming a flexible substrate on the carrier substrate, and forming a plurality of circuit strings on the flexible substrate. A flexible circuit board manufactured by the above method is also provided.

A printed circuit board according to an embodiment includes an insulating layer; and a via portion disposed on the insulating layer; wherein the via portion includes: a first pad disposed under the insulating layer; a second pad disposed on the insulating layer; and a via part disposed between the first and second pads in the insulating layer; and wherein a width of the first pad is less than or equal to a width of a lower surface of the via part.

A circuit board utilizing the better and faster performance of optical signals includes interconnected first, second, and third areas. The first area includes a first circuit substrate, and a first coupling element and a chip connected thereon. The second area includes an optical fiber within an insulating layer. The third area includes a second circuit substrate, and a second coupling element and an electronic element connected thereon. The first coupling element and the second coupling element are optically aligned with the optical fiber for signal reception and transmission. A method for manufacturing such composite circuit board is also disclosed.