A printed circuit board (PCB) system includes a first printed circuit board (PCB), an integrated circuit (IC) package, and a memory module. The IC package includes i) a package substrate, ii) a main IC chip that is electrically coupled to a top surface of the package substrate, iii) first contact structures that are disposed on a bottom surface of the package substrate and that are electrically coupled to the first PCB, and iv) second contact structures that are disposed on a top surface of the package substrate. The memory module includes i) a second PCB, ii) one or more memory IC chips that are disposed on the second PCB, and iii) third contact structures that are disposed on a bottom surface of the second PCB. An interposer electrically couples the second contact structures of the IC package with the third contact structures of the memory module.

A stiffener device is suitable for use with an assembly that includes an electronic mother board, an electronic daughter board, a connector for connecting the daughter board parallel to the mother board, and an element for holding in position the daughter board in relation to the mother board. The stiffener device has a main clamp configured to hold tightly the upper surface and the lateral vertical surfaces of the connector.

A camera module according to an embodiment of the present technology includes a first component-mounting board, a second component-mounting board, and a spacer component. The first component-mounting board includes an imaging device. The second component-mounting board is electrically connected to the first component-mounting board. The spacer component is arranged between the first component-mounting board and the second component-mounting board. The spacer component includes a component body that is made of a first insulating material. The component body including a first primary-surface portion that includes a plurality of first reference surfaces including at least three first reference surfaces, a second primary-surface portion that includes a plurality of second reference surfaces including at least three second reference surfaces, and a component accommodation portion with or without a bottom, the first primary-surface portion being brought into contact with the first component-mounting board, the second primary-surface portion being brought into contact with the second component-mounting board, the component accommodation portion being provided to at least one of the first primary-surface portion or the second primary-surface portion.

An electrical connecting structure and a method for manufacturing the same are disclosed. The electrical connecting structure comprises: a first substrate; a second substrate; and an interconnect element disposed between the first substrate and the second substrate, wherein the interconnect element has a width, and no joint surface is present in the interconnect element in a range of 50% or more of the width.

An apparatus having stacked circuit boards has been disclosed. The apparatus includes a main circuit board and a sub circuit board disposed over the main circuit board. A plurality of sub components disposed on a bottom face of the sub circuit board penetrates through main circuit board and extends towards a bottom face of the main circuit board. In this say, a compact apparatus is produced.

An interposer for connecting a module to an M.2 socket includes a different form factor connector. The interposer includes an M.2 connector to couple the interposer to the M.2 socket. The M.2 connector is formed to mate with the M.2 socket. The interposer includes a different form factor socket to couple the interposer to the module including the different form factor connector. The different form factor socket is formed to mate with the different form factor connector.

An electrical connectors with electrodeposited terminals that are grown in place by electroplating cavities formed in a series of resist layers. The resist layers are subsequently stripped away. The resulting terminal shape is defined by the shape of the cavity created in the resist layers. Complex terminal shapes are possible. The present conductive terminals are particularly useful for electrical interconnects and semiconductor packaging substrates.

An electronic device comprises a supporting substrate, a flexible substrate disposed on the supporting substrate, a plurality of electronic units and a conductive pattern layer. The flexible substrate is bent from a front side to a back side of the supporting substrate, and a portion of the flexible substrate is disposed on the back side of the supporting substrate. The electronic units are disposed within a display region of the flexible substrate. The conductive pattern layer extends from the display region to the portion of the flexible substrate, and the conductive pattern layer electrically connects at least two of the electronic units.

An optoelectronic component includes an optical module and a host circuit board. The optical module includes a module circuit board and a gold finger that is located on a first surface of the module circuit board. The host circuit board includes a conductive elastomer corresponding to the gold finger and that is located on a first surface of the host circuit board. The module circuit board is located on the host circuit board, the first surface of the module circuit board and the first surface of the host circuit board face each other, and the gold finger is in contact with the conductive elastomer.

An integral toolless-installation Compression Attached Memory Module (CAMM) bolster plate has a generally flat, parallelepiped body portion configured to contact one surface of a CAMM Printed Circuit Board (PCB) and provide compression between the CAMM and a z-axis compression connector. The bolster plate body defines (a) ramped keyhole(s), each ramped keyhole converts lateral displacement of the toolless-installation CAMM bolster plate into vertical displacement, providing the compression between the CAMM and the z-axis compression connector, by the ramped keyhole(s) sliding along (a) bottom face(s) of (a) head(s) of (a) fixed standoff(s) extending from an information handling system (IHS) PCB, through the z-axis compression connector and the CAMM PCB. The integral toolless-installation CAMM bolster plate may lock in place, laterally displaced, to maintain the compression between the CAMM and the z-axis compression connector. The integral toolless-installation CAMM bolster plate may also have a flange portion extending generally perpendicular from the body portion.