A multilayer ceramic substrate according to the present disclosure has ceramic layers and a patterned conductor, and a cavity is formed in the multilayer ceramic substrate. The cavity reaches to any one of principal surfaces of the multilayer ceramic substrate and forms an opening, and the opening is covered with a sealing member at the principal surface of the multilayer ceramic substrate.

The present invention provides flexible devices, such as integrated circuits, having a multilevel electronic device structure including two or more electronic components. The electronic components within the structure are electrically connected by an interconnect structure having multiple interconnect levels. In addition to the multilevel electronic device structure, the flexible devices include an elastomeric material disposed around the interconnect levels, including within the spaces between the interconnect levels.

An apparatus is provided which comprises: a cavity made in a substrate of a printed circuit board (PCB); a plurality of solder balls embedded in the cavity; and a horizontal trace within the substrate, wherein the horizontal trace is partially directly under the plurality of solder balls and is coupled to the plurality of solder balls and another trace or via in the substrate such that a substrate region under the plurality of solder balls is independent of a stop layer under the cavity.

The present inventive concept relates to a foldable layered connection comprising: a substrate having a first major surface and an opposing second major surface; a node of connector material arranged to contact the substrate via the first major surface; a released extension comprising a core of connector material arranged to be in communicative contact with the node of connector material, and flexible material arranged to at least partially enclose the core; wherein the released extension is configured to be hingedly connected to the node and to fold towards the second major surface, and wherein a portion of the core of connector material is exposed, forming a contact of connector material, wherein the contact is electrically isolated from the second major surface and arranged such that it is facing away from the second major surface when the released extension is folded towards the second major surface.

A method of manufacturing a component carrier. The method includes forming a stack having at least one electrically insulating layer structure and/or at least one electrically conductive layer structure, and embedding a filament in the stack.

A sensor device includes a printed circuit board (PCB) substrate having a top surface, a bottom surface, a slot between the top and bottom surfaces, and two holes through the top surface and reaching into the slot. The sensor device further includes a sensor chip mounted on the top surface of the PCB substrate and above one of the two holes. The sensor device further includes a molding compound covering the sensor chip and sidewall surfaces and the top surface of the PCB substrate.

A method of manufacturing circuit board structure includes forming a sacrificial layer having first openings on a substrate; forming a metal layer on the sacrificial layer; forming a patterned photoresist layer having second openings over the sacrificial layer, in which the second openings are connected to the first openings and expose a portion of the metal layer; forming a first circuit layer filling the second openings and the first openings; forming a first dielectric layer over the sacrificial layer and covering the metal layer, in which the first dielectric layer has third openings exposing the first circuit layer; forming a second circuit layer filling the third openings and covering a portion of the first dielectric layer; removing the substrate to expose the sacrificial layer, a portion of the metal layer and a portion of the first circuit layer; and removing the sacrificial layer and the metal layer.

A method for applying at least one electronic component to a surface is described. The method includes placing a component stencil on a support. At least one electronic component is arranged in a corresponding opening of the component stencil with a top surface of the electronic component on the support. A contact material stencil is positioned on the component stencil such that at least one opening in the contact material stencil is over a corresponding contact region on the bottom surface of the at least one electronic component. A contact material is applied on the at least one contact region of the at least one electronic component within the corresponding opening of the contact material stencil. The contact material stencil is removed from the component stencil. The component stencil is removed from the support. The at least one electronic component is applied to the surface.

A composite substrate that includes: an upper ceramic layer; a lower ceramic layer; a middle resin layer between the upper ceramic layer and the lower ceramic layer; and a side surface resin layer on all side surfaces of the composite substrate, wherein the middle resin layer and the side surface resin layer are integral resin layers.

Methods include receiving at least one electronic device including a sensor or an emitter, placing a cover over the sensor or emitter, placing the electronic device, including the cover, into a transfer mold system, encapsulating the electronic device with charge material, and removing a portion of the encapsulating charge material and the cover to expose the sensor or emitter to the environment.