A method of manufacturing component carriers is disclosed. The method includes providing a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, forming a first hole in a core of the stack and subsequently embedding a first component in the first hole, thereafter forming a second hole in the same core of the stack and subsequently embedding a second component in the second hole. A component carrier has a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A first hole is formed in a core of the stack. A first component is embedded in the first hole. A second hole is formed in the same core of the stack and subsequently a second component is embedded in the second hole.

The invention relates to a multi-layer 3D foil package and to a method for manufacturing such a multi-layer 3D foil package. The 3D foil package has a foil substrate stack having at least two foil planes, wherein a first electrically insulating foil substrate is arranged in a first foil plane, and wherein a second electrically insulating foil substrate is arranged in a second foil plane, wherein the first foil substrate has a first main surface region on which at least one functional electronic component is arranged, wherein the second foil substrate has a cavity having at least one opening in the second main surface region, wherein the foil substrates within the foil substrate stack are arranged one above the other such that the functional electronic component arranged on the first foil substrate is arranged within the cavity provided in the second foil substrate.

A method may include obtaining a printed circuit board (PCB) that includes a set of vias that include a set of stub regions. The PCB may include a set of layers perpendicular to the set of vias. The set of layers may include a signal layer and a ground layer. The ground layer may be located between the set of stub regions and the signal layer. The method may include drilling to remove at least a portion of a stub region of a via of the set of vias. The method may include performing an electrical test to determine whether a sliver of conductive material is included within the via after drilling to remove the at least a portion of the stub region of the via.

A display device includes a display panel, a back cover disposed on a rear surface of the display panel and including a plurality of layers, and a finishing portion disposed to surround at least a part of an outer side surface of the display panel and an outer side surface of the back cover. The back cover includes a first layer positioned on the rear surface of the display panel and disposed in an area including an area overlapping with the display panel, a second layer disposed apart from the first layer to oppose the first layer, and a core disposed between the first layer and the second layer.

A display panel includes a plastic substrate and a first inner lead bonding (ILB) electrode on the plastic substrate. The first ILB electrode includes a first bonding segment, a second bonding segment, and a first connection segment. The first bonding segment is extended in a first direction oblique to a vertical direction of the display panel. The first connection segment is configured to provide an electrical connection between the first bonding segment and the second bonding segment. The first ILB electrode is configured to be bonded to an integrated circuit chip using one of the first bonding segment or the second bonding segment.

A smart key for a vehicle includes: a base part; a first terminal part coupled to the base part and which makes contact with a first electrode of a battery so as to be electrically connected to the battery; a second terminal part disposed facing the first terminal part to form an insertion part where the battery is inserted and which makes contact with a second electrode of the battery to be electrically connected to the battery; a separation prevention part which extends from the second terminal to the base part and which abuts the side surface of the battery to prevent the battery from separating from the insertion part; and a pressure applying part which is connected to the second terminal part so as to enable contact with the battery and which maintains contact between the battery and the separation prevention part by an elastic restoring force.

A printed circuit board (PCB) and a method of manufacturing the same is described. The PCB includes a substrate defining a major plane and an integrated electromagnetic interference and compatibility (EMC/EMI) shielding enclosure configured to enclose the substrate. The shielding enclosure includes a metallic top layer deposited on top of the major plane of the substrate so as to envelop an uppermost layer of the substrate, a metallic bottom layer deposited on bottom of the major plane of the substrate so as to envelop a bottommost layer of the substrate, and a metallic side layer formed along a length of one or more edges of the substrate to electrically connect the metallic top layer and the metallic bottom layer.

A process for conformally coating passive surface mount components soldered to a printed circuit substrate of a lidless flip-chip ball grid array package includes affixing a stiffener ring to the substrate before forming a conformal coating on the passive surface mount components. The stiffener ring is affixed to the substrate so that the plurality of passive surface mount components and the integrated circuit die are contained within an opening formed by the stiffener ring. After affixing the stiffener ring to the substrate, the conformal coating is formed on the passive surface mount components. The conformal coating extends over each of the passive surface mount components, around a periphery of each of the passive surface mount components, and under each of the passive surface mount components. A product made according to the process is also disclosed.

A mounted structure of a supporting-terminal-equipped capacitor chip includes first and second supporting terminals. The first supporting terminal includes a first helical electrically conductive portion extending in a first axial direction along a main surface. The second supporting terminal includes a second helical electrically conductive portion extending in a second axial direction along the main surface. The first helical electrically conductive portion is electrically connected to a first outer electrode at an outer peripheral side surface of the first helical electrically conductive portion. The second helical electrically conductive portion is electrically connected to a second outer electrode at an outer peripheral side surface of the second helical electrically conductive portion.

A system that may include a rigid bus bar body portion having one or more first conductive pathways, and a flexible bus bar body portion extending from the rigid bus bar body portion and having a lower modulus of elasticity than the rigid bus bar body portion, the flexible bus bar body portion including one or more second conductive pathways. The one or more first conductive pathways and the one or more second conductive pathways may be configured to be conductively coupled with a first electronic device to form a conductive connection between the first electronic device and at least a second electronic device.