An opto-electronic package is described. The opto-electronic package is manufactured using a fan out wafer level packaging to produce dies/frames which include connection features. Additional structures such as heat exchanged structures are joined to a connection component and affixed to packages, using the connection features, to provide structural support and heat exchange to heat generating components in the package, among other functions.

A frame lid for use with a semiconductor package is disclosed. First, a mask is applied to a top surface of the lid and over a central area of the top surface to define a peripheral area. Next, a seal ring is formed by metallizing the peripheral area and the sidewall of the plate. The mask can then be removed obtain the frame lid. Next, a solder preform can be attached to the seal ring. This reduces pullback and shrinkage of the metallized layer, while lowering the manufacturing cost and process times.

A method for manufacturing a cover for an electronic package includes placing an insert having opposite faces between opposite faces of a cavity of a mold. A coating material is injected in the mold cavity around the insert. The coating material is then set to form a substrate that is overmolded around the insert and produce the cover.

A stacked semiconductor microcooler includes a first microcooler and a second microcooler. The microcoolers may be positioned such that the fins of each microcooler are vertically aligned. The microcoolers may include an inlet passage to accept coolant and an outlet passage to expel the coolant. One or more microcoolers may be thermally connected to an electronic device heat generating device, such as an integrated circuit (IC) chip, or the like. Heat from the electronic device heat generating device may transfer to the one or more microcoolers. A flow of cooled liquid may be introduced through the passages and heat from the one or more microcoolers may transfer to the liquid coolant.

According to the present invention, a semiconductor device includes an insulating substrate having an organic insulating layer and a circuit pattern provided on the organic insulating layer; and a semiconductor chip provided on an upper surface of the circuit pattern, wherein a thickness of the circuit pattern is not less than 1 mm and not more than 3 mm. According to the present invention, a method for manufacturing a semiconductor device includes forming a metal layer with a thickness not less than 1 mm and not more than 3 mm on an organic insulating layer; patterning the metal layer by machining processing to form a circuit pattern; and providing a semiconductor chip on an upper surface of the circuit pattern.

A casing for semiconductor packages that includes a plurality of press-fit pins is disclosed. Specific implementations include a shaft including a first end and a second end. The first end may include a head. The press-fit pin may include a bonding portion included at the second end. The bonding portion may include a first section extending substantially perpendicular from a longest length of the shaft. The bonding portion may also include an angled section coupled to a bonding foot. The bonding foot may be configured to be ultrasonically welded to a substrate.

A device may include a first package and a second package where the first package has a warped shape. First connectors attached to a redistribution structure of the first package include a spacer embedded therein. Second connectors attached to the redistribution structure are fee from the spacer, the spacer of the first connectors keeping a minimum distance between the first package and the second package during attaching the first package to the second package.

An electrical connector is essentially composed of a pair of half housings opposite to each other in a longitudinal direction to commonly form a receiving cavity for receiving a CPU. Each half housing is equipped with a plurality of contacts with corresponding contacting sections upwardly extending into the receiving cavity for mating with the CPU. A single pick-up cap includes a plate with a plurality of claws adapted to be engaged within locking recesses in exterior sides of the half housings, a plurality of positioning blocks adapted to extend into the receiving cavity so as to cooperate with the claws to sandwich the periphery wall of the housing therebetween in the longitudinal direction for securing the half housings to the pick-up cap. Therefore, both the pair of half housings may be grasped by the single pick-up cap for mounting and soldering to PCB at the same time.

In one example, a semiconductor device comprises a substrate comprising a conductive structure, an electronic component over a top side of the substrate and electrically coupled with the conductive structure, a lid structure over the substrate and over the electronic component, and a vertical interconnect in the lid structure extending to a top surface of the lid structure and electrically coupled with the conductive structure. Other examples and related methods are also disclosed herein.

An electronic device and associated methods are disclosed. In one example, the electronic device includes a substrate, a semiconductor die thereon, electrically coupled to the substrate, and an interposer adapted to connect the substrate to a circuit board. The interposer can include a major surface, a recess in the major surface, a first plurality of interconnects passing through the interposer within the recess to electrically couple the substrate to a circuit board, and a second plurality of interconnects on the major surface of the interposer to electrically couple the substrate to the circuit board, wherein each of the second plurality of interconnects comprises a smaller cross-section than some of the first plurality of interconnects.