A package structure and the method thereof are provided. The package structure includes a conductive plate, a semiconductor die, a molding compound, and antenna elements. The conductive plate has a first surface, a second surface and a sidewall connecting the first surface and the second surface. The semiconductor die is located on the second surface of the conductive plate. The molding compound laterally encapsulates the semiconductor die and covers the sidewall and a portion of the second surface exposed by the semiconductor die, wherein the first surface of the conductive plate is coplanar with a surface of the molding compound. The antenna elements are located over the first surface of the conductive plate.

A semiconductor and a method of fabricating the semiconductor having multiple, interconnected die including: providing a semiconductor substrate having a plurality of disparate die formed within the semiconductor substrate, and a plurality of scribe lines formed between pairs of adjacent die of the plurality of disparate die; and fabricating, by a lithography system, a plurality of inter-die connections that extend between adjacent pair of die of the plurality of die.

A semiconductor memory device includes: a local write bit (LWB) line; a local write bit_bar (LWB_bar) line; a global write bit (GWB) line; a global write bit_bar (GWBL_bar) line; a column of segments, each segment including bit cells; each of the bit cells including a latch circuit and first and second pass gates connecting the corresponding LWB and LWB_bar lines to the latch circuit; and a distributed write driving arrangement. The distributed write driving arrangement includes: a global write driver including a first inverter connected between the GWB line and the LWB line, and a second inverter connected between the GWB_bar line and the LWB_bar line; and a local write driver included at an interior of each segment, each local write driver including a third inverter connected between the GWB line and the LWB line; and a fourth inverter connected between the GWB_bar line and the LWB_bar line.

The electronic device includes an electronic component, a plurality of leads electrically coupled to the electronic component, and a mold cover covering the electronic component, wherein the plurality of leads includes an inner part located inside the mold cover, and an outer part located outside the mold cover, and the inner part includes a first lead electrically coupled to the electronic component, a second lead separated from the first lead and integrated with the outer part, and a coupling member configured to electrically couple the first lead and the second lead to each other.

A semiconductor module includes a laminated substrate that includes a heat radiating plate, and an insulation layer having a conductive pattern thereof and being disposed on a top surface of the heat radiating plate, a semiconductor element disposed on a top surface of the conductive pattern, an integrated circuit that controls driving of the semiconductor element, a control-side lead frame having a primary surface on which the integrated circuit is disposed, and a mold resin that seals the laminated substrate, the semiconductor element, the integrated circuit, and the control-side lead frame. The control-side lead frame has a rod-shaped first pin having a first end, a first end side of the first pin extending toward the top surface of the heat radiating plate, and the heat radiating plate has at least one insertion hole into one of which the first end of the first pin is press-fitted.

Existing methods of cooling computer chips can be inefficient, when applied to high density computing systems, such as wafer-scale-integrated (WSI) systems and other high-density computing systems. In particular, current methods of cooling integrated circuits can be inefficient when applied to high-density computing systems, as the cooling medium can lose its ability to absorb heat due to heat absorption and aggregation when the cooling medium travels through multiple surfaces and regions of a high-density computing system. In some embodiments, systems and methods of achieving high-density computing, by using bridge dies and standard and/or WSI lithography techniques are disclosed. In other embodiments, systems and methods of cooling high-density computing systems are disclosed. Two-phase immersion cooling that avoids heat aggregation is used.

A method of generating a wire loop profile in connection with a semiconductor package is provided. The method includes the steps of: (a) providing package data related to the semiconductor package; and (b) creating a loop profile of a wire loop of the semiconductor package, the loop profile including a tolerance band along at least a portion of a length of the wire loop.

An electronic device structure having a shielding structure includes a substrate with an electronic component electrically connected to the substrate. The shielding structure includes conductive spaced-apart pillar structures that have proximate ends connected to the substrate and distal ends spaced apart from the substrate, and that are laterally spaced apart from the first electronic component. In one embodiment, the conductive pillar structures are conductive wires attached at one end to the substrate with an opposing end extending away from the substrate so that the conductive wires are provided generally perpendicular to the substrate. A package body encapsulates the electronic component and the conductive spaced-apart pillar structures. In one embodiment, the shielding structure further includes a shielding layer disposed adjacent the package body, which is electrically connected to the conductive spaced-apart pillar structures. In one embodiment, the electrical connection is made through the package. In another embodiment, the electrical connection is made through the substrate.

A package structure and the method thereof are provided. The package structure includes a conductive plate, a semiconductor die, a molding compound, and antenna elements. The conductive plate has a first surface, a second surface and a sidewall connecting the first surface and the second surface. The semiconductor die is located on the second surface of the conductive plate. The molding compound laterally encapsulates the semiconductor die and covers the sidewall and a portion of the second surface exposed by the semiconductor die, wherein the first surface of the conductive plate is coplanar with a surface of the molding compound. The antenna elements are located over the first surface of the conductive plate.

A method of generating a wire loop profile in connection with a semiconductor package is provided. The method includes the steps of: (a) providing package data related to the semiconductor package; and (b) creating a loop profile of a wire loop of the semiconductor package, the loop profile including a tolerance band along at least a portion of a length of the wire loop.