A method includes forming a plurality of dielectric layers, forming a plurality of redistribution lines in the plurality of dielectric layers, etching the plurality of dielectric layers to form an opening, filling the opening to form a through-dielectric via penetrating through the plurality of dielectric layers, forming a dielectric layer over the through-dielectric via and the plurality of dielectric layers, forming a plurality of bond pads in the dielectric layer, bonding a device die to the dielectric layer and a first portion of the plurality of bond pads through hybrid bonding, and bonding a die stack to through-silicon vias in the device die.

A connector for surface mounting with a solder reflow process with closely-spaced solder masses on mounting ends of reference contacts. The solder masses on the reference contacts may fuse for enhanced shielding. The mounting ends of signal and reference contacts may be positioned in rows, configured such that the solder masses of the reference contacts may shield solder masses attached to signal contacts in adjacent rows. The mounting ends of the signal contacts may be disposed in pockets in a surface of the connector housing. In some embodiments, solder balls may be fused to an edge of the signal contact, with the length of the edge extending beyond locations at which the solder ball is fused to. The edge may extend through a wall of the pocket, so as to set a desired impedance in the mounting region of the connector.

Systems (300) and methods (1200) for inserting an electronic module in a structure. The methods comprise: sliding at least one glide mechanism on a rail of the structure or a surface of the electronic module as the electronic module is being inserted into the structure; actuating a coupler to secure the electronic module to the rail and compress a thermal interface material between the electronic module and the rail; thus causing the glide mechanism to be retracted into the electronic module or rail while the coupler is being actuated. The thermal interface material first comes in contact with the rail while the coupler is being actuated. The glide mechanism is integrated with the electronic module or the rail and is resiliently biased in a direction away from the electronic module or rail so as to partially extend out from the electronic module in a direction towards the electronic module or rail.

A connector for surface mounting with a solder reflow process with closely-spaced solder masses on mounting ends of reference contacts. The solder masses on the reference contacts may fuse for enhanced shielding. The mounting ends of signal and reference contacts may be positioned in rows, configured such that the solder masses of the reference contacts may shield solder masses attached to signal contacts in adjacent rows. The mounting ends of the signal contacts may be disposed in pockets in a surface of the connector housing. In some embodiments, solder balls may be fused to an edge of the signal contact, with the length of the edge extending beyond locations at which the solder ball is fused to. The edge may extend through a wall of the pocket, so as to set a desired impedance in the mounting region of the connector.

The electrical connector includes an insulative housing for receiving the CPU therein with a plurality of contacts retained thereto, a fastener located beside the housing, and a load plate pivotally mounted upon the fastener and covering the housing for holding the CPU in position. The load plate includes opposite first and second sides and opposite first and fourth sides to commonly form a center opening. The first and second sides form first protrusions with corresponding first pressing sections, and the third and fourth sides forms second protrusions with corresponding second pressing sections. During operation, both the first pressing sections and the second pressing sections act upon the CPU.

An electronic component device includes a mount substrate including an outer electrode on one principal surface and a mount electrode on another principal surface, at least one substrate component including a terminal electrode on one principal surface, and that is mounted on the mount substrate by joining the terminal electrode to the mount electrode, and a sealing resin layer that is provided on the mount substrate on which the at least one substrate component is mounted. The sealing resin layer includes a region with a large thickness, and a top surface including an inclination.

An electrical connector includes an insulative base, an insulative cover attached upon the base and moveable along a front-to-back direction, and an operation lever sandwiched between the base and the cover for moving the cover relative to the base in the front-to-back direction. The lever includes an actuating bar sandwiched between the upper head and the lower head, and an operation bar exposed outside of the base and the cover. The operation bar is rotatable between a horizontal position and a vertical position. The lower head includes a stopper around a front end of the operation bar with a locking section engaged with the operation bar wherein said locking section extends toward the operation bar either inwardly along the transverse direction or in the front-to-back direction.

A heat sink according to one embodiment of the present invention includes: a base portion having a first surface and a second surface which oppose each other; at least one heat dissipating fin extending vertically from the first surface, each of the at least one heat dissipating fin having an insertion groove extending from an end portion thereof toward the base portion, and a first fin portion and a second fin portion which are separated by the insertion move; and a connector included in the base portion, the connector being above the insertion groove in plan view, and the connector being configured to electrically connect a first heat generating component to be inserted into the insertion groove from a side of the first surface and a second heat generating component to be disposed on a side of the second surface.

A connector for surface mounting with a solder reflow process with closely-spaced solder masses on mounting ends of reference contacts. The solder masses on the reference contacts may fuse for enhanced shielding. The mounting ends of signal and reference contacts may be positioned in rows, configured such that the solder masses of the reference contacts may shield solder masses attached to signal contacts in adjacent rows. The mounting ends of the signal contacts may be disposed in pockets in a surface of the connector housing. In some embodiments, solder balls may be fused to an edge of the signal contact, with the length of the edge extending beyond locations at which the solder ball is fused to. The edge may extend through a wall of the pocket, so as to set a desired impedance in the mounting region of the connector.

A method includes forming a plurality of dielectric layers, forming a plurality of redistribution lines in the plurality of dielectric layers, etching the plurality of dielectric layers to form an opening, filling the opening to form a through-dielectric via penetrating through the plurality of dielectric layers, forming a dielectric layer over the through-dielectric via and the plurality of dielectric layers, forming a plurality of bond pads in the dielectric layer, bonding a device die to the dielectric layer and a first portion of the plurality of bond pads through hybrid bonding, and bonding a die stack to through-silicon vias in the device die.