Integrated circuit assemblies, electronic systems, and methods for fabricating the same are disclosed. An integrated circuit assembly is formed by thermally contacting at least two integrated circuit packages to opposite sides of a shared heat dissipation device. In one embodiment, the at least two integrated circuit packages are electrically attached to an electronic card to form an intermediate integrated circuit assembly. In a further embodiment, the integrated circuit assembly includes at least one intermediate integrated circuit assembly electrically attached to an electronic board.

A surface mount technology (SMT) terminal header is described for providing an electrical connection to a first printed circuit board (PCB). The SMT terminal header includes multiple first electrically conductive connector elements each having a base configured for surface mount attachment to the first PCB, and an insulative housing having multiple cells and a fixation member configured to attach the housing to the first PCB. Each of the multiple cells is configured to at least partially house one of the multiple first electrically conductive connector elements. Each of the first electrically conductive connector elements includes a position assurance member configured to attach the first electrically conductive connector element to at least one of the multiple cells of the insulative housing.

A capacitor module has a module case including a lower case and an upper case. A housing case is fixed to an inner face of the upper case, and a capacitor is housed in the housing case. A circuit board is fixed to an upper face of the lower case. The circuit board has wiring that is electrically connectable to the capacitor, and electronic components and constituting a circuit that controls electric current to the capacitor are mounted on the circuit board.

An illuminated modular decorative article includes a base control panel and a side panel. The base control panel includes a base, a first electrical/mechanical connection interface, and a power source. The side panel includes a base, a second electrical/mechanical connection interface, and illumination sources. The first electrical/mechanical connection interface connects to the second electrical/mechanical connection interface to electrically connect the base control panel to the side panel and to mechanically connect the base control panel substantially orthogonally to the side panel.

An electronic device includes a top plate having a first surface and a second surface that is positioned at an elevation that is lower than an elevation of the first surface, the second surface extending from a first end part of the top plate to a second end part of the top plate, a bottom plate provided under the top plate, and a circuit board placed between the top plate and the bottom plate and mounted with an electronic component. The top plate has opposing first and second edges and opposing third and fourth edges that are perpendicular to the first and the second edges, the first end part being formed at the first edge and the second end part being formed at the second edge.

A standalone top cover retention mechanism can attach to the top of an array of tall (e.g., 2U) DIMMs to provide structural support. In one example, the DIMM cover is attached to two or more DIMMs without attaching to the chassis. The DIMM cover can mitigate shock and vibration related failures at the DIMM level without significant interference with platform thermal mechanical solutions.

An electronic assembly includes a printed wiring board (PWB), and a stiffener secured to the PWB. The stiffener includes one or more tray sections. One or more electronic modules is secured respectively to the one or more tray sections of the stiffener.

A printed circuit board with a lateral metallization groove and a processing method thereof, relates to the field of printed circuit boards with lateral metallization grooves, processing technologies thereof and batch processing methods. The processing method includes the following steps: step S01, drilling and milling grooves; step S02, performing metallization treatment; step S03, laying an outer layer circuit; step S04, performing pattern plating; step S05, performing first milling grooves; step S06, etching an outer layer; step S07, performing surface treatment after performing solder resist printing and character printing; step S08, forming to mill off connections of a processing side; step S09, performing second milling grooves to form a through groove. The present disclosure can implement: a long side of the printed circuit board can be directly connected with the ground wire rather than independently installing the ground wire; a small space is occupied and conveniently replacement.

The present invention relates to a base fastener which is disposed corresponding to a pair of arc holes on a base. The base fastener comprises a body. The body has a first side, a second side, and a throughhole. The throughhole penetrates through the first side and the second side. A first post and a second post protrude from the second side beside the throughhole. The first post, the second post, and the pair of arc holes are disposed correspondingly and rotatably connected to each other to be assembled with the base firmly.

A MEMS board assembly, a LiDAR system including the same, and a method for making the same are disclosed. The exemplary MEMS board assembly includes a MEMS board having a plurality of through holes and a mount having a plurality of threaded holes. The MEMS board assembly further includes a plurality of spring-loaded posts each formed by fitting a spring into a respective post. The plurality of spring-loaded posts are fitted into the plurality of threaded holes of the mount. The MEMS board assembly also includes a plurality of screws fitting the MEMS board to the mount by reaching into the plurality of threaded holes of the mount through the plurality of through holes in the MEMS board and the plurality of spring-loaded posts. The MEMS board touches the plurality of spring-loaded posts at the plurality of through holes in the MEMS board corresponding to the plurality of threaded holes of the mount respectively.