According to one embodiment, an electronic device includes: a housing; a first electronic component inside the housing; a second electronic component arranged inside the housing and spaced apart from the first electronic component; a female connector electrically connected to the second electronic component, the female connector comprising multiple conductive pins; a male connector electrically connected to the first electronic component and configured to contact at least some of the multiple conductive pins of the female connector, the male connector comprising a base film, a conductive layer formed on one surface of the base film, and an adhesive layer formed on the back surface of the base film, thereby forming a lamination structure; and multiple reinforcement members provided on at least one of one surface of the base film and the back surface thereof so as to form a peripheral portion of the lamination structure.

The invention relates to an electric interface, in particular an interposer, having a first connection plane with at least one first contact surface pair, each of which has a first and second contact surface, and a second connection plane with at least one second contact surface pair, each of which has a third and a fourth contact surface. For each of a first and second contact surface pair, a first electric connection electrically connects the first contact surface of the first connection plane to the third contact surface of the second connection plane, and a second electric connection electrically connects the second contact surface of the first connection plane to the fourth contact surface of the second connection plane. The first electric connection between the first and third contact surface has a specified first geometric length, and the second electric connection between the second and fourth contact surface has a specified second geometric length, the first and second geometric length being different.

Various embodiments disclosed in this document relate to an electronic device and, more specifically, to an electronic device comprising a connector capable of electrically connecting at least two components. According to various embodiments disclosed herein, there may be provided an electronic device comprising: a housing; a first electronic component inside the housing; a second electronic component arranged inside the housing and spaced apart from the first electronic component; a female connector electrically connected to the second electronic component, the female connector comprising multiple conductive pins; a male connector electrically connected to the first electronic component and configured to contact at least some of the multiple conductive pins of the female connector, the male connector comprising a base film, a conductive layer formed on one surface of the base film, and an adhesive layer formed on the back surface of the base film, thereby forming a lamination structure; and multiple reinforcement members provided on at least one of one surface of the base film and the back surface thereof so as to form a peripheral portion of the lamination structure.

An electrical assembly having an electrical device electrically connected to a multilayer bus board, which has a multilayer stacked assembly that includes a plurality of electrically conductive layer structures and at least one dielectric layer structure disposed between an adjacent pair of the conductive layer structures. A frame formed of a dielectric material encapsulates at least a portion of the multilayer stacked assembly and mechanically maintains the conductive layer structures and the dielectric layer structure in secure aligned abutting relation.

An electronic interconnect may include a substrate. The substrate may include a passageway in the substrate. The passageway may extend from a first surface of the substrate toward a second surface of the substrate. The passageway may be closed at an end of the passageway. The electronic interconnect may include a plated through hole socket coupled to the passageway. The electronic interconnect may include a contact. The contact may include a pin. The pin may be configured to engage with the plated through hole socket. The electronic interconnect may include a solder ball. The solder ball may be coupled to the plated through hole socket.

A manufacturing method of connector structure including the following steps is provided. First, providing a dielectric layer having. Then, forming a first adhesive layer and a second adhesive layer on two opposite sides of the dielectric layer respectively. Then, providing at least one first conductive elastic cantilever and at least one second conductive elastic cantilever, wherein the first conductive elastic cantilever comprises a first fixing end portion and a first free end portion, and the second conductive elastic cantilever comprises a second fixing end portion and a second free end portion. Then, fixing the first fixing end portion and the second fixing end portion to the first adhesive layer and the second adhesive layer respectively, wherein the first fixing end portion is aligned with the second fixing end portion. Afterward, forming at least one conductive via for electrically connecting the first conductive elastic cantilever with the second conductive elastic cantilever.

An electrical assembly having an electrical device electrically connected to a multilayer bus board, which has a multilayer stacked assembly that includes a plurality of electrically conductive layer structures and at least one dielectric layer structure disposed between an adjacent pair of the conductive layer structures. A frame formed of a dielectric material encapsulates at least a portion of the multilayer stacked assembly and mechanically maintains the conductive layer structures and the dielectric layer structure in secure aligned abutting relation.

A manufacturing method of connector structure including the following steps is provided. First, providing a dielectric layer having. Then, forming a first adhesive layer and a second adhesive layer on two opposite sides of the dielectric layer respectively. Then, providing at least one first conductive elastic cantilever and at least one second conductive elastic cantilever, wherein the first conductive elastic cantilever comprises a first fixing end portion and a first free end portion, and the second conductive elastic cantilever comprises a second fixing end portion and a second free end portion. Then, fixing the first fixing end portion and the second fixing end portion to the first adhesive layer and the second adhesive layer respectively, wherein the first fixing end portion is aligned with the second fixing end portion. Afterward, forming at least one conductive via for electrically connecting the first conductive elastic cantilever with the second conductive elastic cantilever.

Embodiments herein relate to systems, apparatuses, or processes for a connector for a modular memory package that includes one or more memory dies on a substrate, where the connector directly electrically couples electrical contacts at an edge and on each side the substrate of the memory package to electrical contacts at an edge and on each side of another substrate that includes a compute die. The connector may include a first plurality of leads that are substantially parallel with each other, and a second plurality of leads that are substantially parallel with each other that are below the first plurality of leads and electrically couple the two substrates. Other embodiments may be described and/or claimed.

A multilayer bus board comprising a multilayer stacked assembly including a plurality of electrically conductive first layers, and at least one second dielectric layer disposed between adjacent first layers; and a frame formed of a dielectric material, the frame encapsulating at least a portion of the multilayer stacked assembly and mechanically maintaining the first and second layers in secure aligned abutting relation.