A printed wiring board includes a core substrate having cavity to accommodate an electronic component and including a front conductor layer formed on front side of the core substrate, and a back conductor layer formed on back side of the core substrate, through-hole conductors formed through the core substrate such that the through-hole conductors connect the front and back conductor layers of the core substrate, a front build-up layer formed on front surface of the core substrate and including interlayer insulating layers and conductor layers, and a back build-up layer formed on back surface of the core substrate and including interlayer insulating layers and conductor layers. The conductor layers in the front build-up layer include a conductor layer sandwiching one of the interlayer insulating layers with the front conductor layer such that the conductor layer and the front conductor layer have the same electric potential in region surrounding the cavity.

An electronic component-embedded substrate includes a core substrate, a cavity penetrating the core substrate, a wiring layer formed on one surface of the core substrate, a support pattern extending over the cavity and configured to divide the cavity into a plurality of component embedding areas, an insulation wall portion arranged on a part of the support pattern in the cavity and formed of the same material as the core substrate, a plurality of electronic components each of which is mounted in each of the plurality of component embedding areas, and an insulating material filling an inside of the cavity.

A manufacturing method of a package carrier is provided. A substrate having a through hole is provided, wherein a profile of the through hole from top view is a first rounded rectangular. A heat conducting slug is disposed inside the through hole, wherein the heat conducting slug and an inner wall of the through hole are separated with a gap, and a profile of the heat conducting slug from top view is a second rounded rectangular. An insulating material is filled in the through hole so as to fix the heat conducting slug in the through hole. A conductive through hole structure, a first and a second patterned circuit layers are formed. The first and the second patterned circuit layers are respectively formed on two opposite sides of the substrate. The conductive through hole structure penetrates the substrate and connects portions of the first and the second patterned circuit layers.

A component carrier includes a core having a recess, at least one electronic component arranged in the recess, wherein a vertical thickness of the at least one electronic component is larger than a vertical thickness of the core, and an electrically insulating sheet covering at least part of a top main surface of the core, covering at least part of the at least one electronic component and filling a gap between a lateral surface of the at least one electronic component and a lateral surface of the core in the recess.

The instant disclosure provides a polyimide composite film for a flexible display and a method for manufacturing the same. The composite film can be attached to a supporting carrier and includes a double-sided tape, a releasing layer and a transparent polyimide film. The double-sided tape includes a substrate, a surface of the substrate has an adhesive disposed thereon, and the other surface of the substrate has a releasing agent disposed thereon. A releasing layer is attached to the adhesive on the substrate and is removable from the substrate so that the substrate is attachable to the supporting carrier through the adhesive. The method includes providing a transparent polyimide film; providing the double-sided tape mentioned above; and removing the releasing layer on the releasing agent of the substrate for adhering the transparent polyimide film to the releasing agent.

A printed wiring board includes a core substrate, a first resin insulating layer formed on a first surface of the core substrate, a second resin insulating layer formed on a second surface of the core substrate on the opposite side of the first surface, an electronic component accommodated in opening portion formed in the core substrate, and a filling resin filling space formed between the electronic component and an inner wall of the opening portion and including resin material that is different from resin material forming the first and second resin insulating layers. The core substrate has a first conductor pattern forming a first outermost layer of the core substrate and a second conductor pattern forming a second outermost layer of the core substrate on the opposite side of the first conductor pattern, and the filling resin is filling spaces formed in the second conductor pattern of the core substrate.

A method for manufacturing a circuit board includes forming recess structures on a transferring layer; forming a dielectric layer on the transferring layer to form a stacking structure, in which the dielectric layer is at least embedded with the recess structures; bonding the stacking structure a base board by pressing, such that the dielectric layer is in contact with the base board; patterning the dielectric layer, including performing an exposure process on the stacking structure through the transferring layer; and after the exposure process is finished, removing the transferring layer.

A method for manufacturing an electronic component by a pressure-assisted low-temperature sintering process, by using a pressure sintering device having an upper die and a lower die is disclosed. The upper the die and/or the lower die is provided with a first pressure pad, wherein the method includes the following steps: placing a first sinterable component on a first sintering layer provided on a top layer of a first substrate; joining the sinterable component and the top layer of the first substrate to form a first electronic component by pressing the upper die and the lower die towards each other, wherein the sintering device is simultaneously heated.

A component carrier includes a stack with at least one electrically conductive layer structure and a plurality of electrically insulating layer structure, a first component, a second component, a central core in which both the first component and the second component are embedded. A first electrically insulating structure encapsulates the first component. A second electrically insulating structure encapsulates the second component. The first component and the second component are electrically connected to an external electrically conductive structure through at least one electrically conductive contact passing through the first electrically insulating structure and/or the second electrically insulating structure.

The purpose of the present invention is to provide a garment-type electronic device capable of reducing discomfort during the wearing in the garment-type electronic device comprising an electrical wiring using stretchable conductor composition. In a part in contact with a body surface of a garment-type electronic device, a level difference at the boundary between the electrode portion where the conductor is exposed and the wiring portion covered with the insulating cover layer is substantially eliminated, whereby a garment type electronic device with a natural wearing feeling in which discomfort during wearing has been reduced is obtained. Furthermore, by providing the projections and the depressions in the fabric texture on its surface, a more natural wearing feeling is obtained. Such a garment-type electronic device can be produced by a printing transfer method.