A semiconductor package includes a module substrate having opposite top and bottom surfaces, a semiconductor chip provided with bumps and mounted on the top surface of the module substrate via the bumps, and a metal member having a top portion disposed at a level higher than the semiconductor chip with reference to the top surface of the module substrate and including the semiconductor chip in plan view and a side portion extending from the top portion toward the module substrate. The module substrate includes a first metal film disposed on or in at least one of the bottom surface and an internal layer of the module substrate. The first metal film is electrically connected to the bumps and reaches a side surface of the module substrate. The side portion is thermally coupled to the first metal film at the side surface of the module substrate.

A semiconductor device package includes a first electronic component, a plurality of first conductive traces, a second electronic component, a plurality of second conductive traces and a plurality of first conductive structures. The first electronic component has a first active surface. The first conductive traces are disposed on and electrically connected to the first active surface. The second electronic component is stacked on the first electronic component. The second electronic component has an inactive surface facing the first active surface, a second active surface opposite the inactive surface, and at least one lateral surface connecting the second active surface and the inactive surface. The second conductive traces are electrically connected to the second active surface, and extending from the second active surface to the lateral surface. The first conductive structures are electrically connecting the second conductive traces to the first conductive traces, respectively.

An IC package, an electronic assembly, and methods of preventing warpage of components of an electronic assembly during fabrication of the electronic assembly are shown. An IC package including an adhesive disposed at or near at least one of four corners of a die of the IC package is shown. An electronic assembly including an IC package that includes an adhesive disposed at or near at least one of four corners of a second surface of a first substrate is shown. Methods of preventing warpage of components of an electronic assembly during fabrication of the electronic assembly that include applying an adhesive to at least one of four corners of a first surface of a first component are shown.

A semiconductor device includes a wiring substrate, a first semiconductor element, a second semiconductor element, a bump, a bonding portion, and a resin portion. The second semiconductor element is between the wiring substrate and the first semiconductor element. The bump is between the first and second semiconductor elements and electrically connects the first and second semiconductor elements. The bonding portion is between the first and second semiconductor elements, bonds the first semiconductor element to the second semiconductor element, and has a first elastic modulus. The resin portion has a second elastic modulus higher than the first elastic modulus. The resin portion is between the first and second semiconductor elements. The first semiconductor element is between a second portion of the resin portion and the wiring substrate. A third portion of the resin portion is overlapped with the first and second semiconductor elements.

A package structure applied to power converters can include: a first die having a first power transistor and a first control and drive circuit; a second die having a second power transistor; a connection device configured to couple the first and second power transistors in series between a high-level pin and a low-level pin of a lead frame of the package structure; and where a common node of the first and second power transistors can be coupled to an output pin of the lead frame through a metal connection structure with a low interconnection resistance.

Embodiments that allow both high density and low density interconnection between microelectronic die and motherboard via. Direct Chip Attach (DCA) are described. In some embodiments, microelectronic die have a high density interconnect with a small bump pitch located along one edge and a lower density connection region with a larger bump pitch located in other regions of the die. The high density interconnect regions between die are interconnected using an interconnecting bridge made out of a material that can support high density interconnect manufactured into it, such as silicon. The lower density connection regions are used to attach interconnected die directly to a board using DCA. The high density interconnect can utilize current Controlled Collapsed Chip Connection (C4) spacing when interconnecting die with an interconnecting bridge, while allowing much larger spacing on circuit boards.

A chip on film package including a chip and a flexible film. The chip includes bumps disposed on the chip and is mounted on the flexible film. The flexible film includes first vias, second vias, upper leads and lower leads. The first vias and the second vias penetrate the flexible film and are arranged on two opposite sides of a reference line respectively. A distance between one of the first vias and one of the second vias, which are closer to a first side of the chip, is longer than that between another one of the first vias and another one of the second, which are further from the first side. The upper leads are disposed on the upper surface connected between the vias and the bumps. The lower leads are disposed on the lower surface and connected to the vias.

Embodiments that allow both high density and low density interconnection between microelectronic die and motherboard via. Direct Chip Attach (DCA) are described. In some embodiments, microelectronic die have a high density interconnect with a small bump pitch located along one edge and a lower density connection region with a larger bump pitch located in other regions of the die. The high density interconnect regions between die are interconnected using an interconnecting bridge made out of a material that can support high density interconnect manufactured into it, such as silicon. The lower density connection regions are used to attach interconnected die directly to a board using DCA. The high density interconnect can utilize current Controlled Collapsed Chip Connection (C4) spacing when interconnecting die with an interconnecting bridge, while allowing much larger spacing on circuit boards.

A system may include a host processor, an interposer having memory elements, a coprocessor mounted on the interposer for accelerating tasks received from the host processor, and an auxiliary chip. The coprocessor, interposer, and auxiliary chip may be part of an integrated circuit package. The memory elements on the interposer may convey configuration bit streams to one or more logic sectors in programmable circuitry of the coprocessor. The interposer may be connected to a package substrate of the integrated circuit package using through-silicon vias, such that an active surface of the interposer faces an active surface of the coprocessor. Each logic sector may include one or more data registers that are loaded with configuration data from the memory elements. In some instances, the auxiliary chip may include a secondary memory for storing additional configuration bit streams for configuring the logic sectors of the coprocessor.

An integrated circuit (IC) package including ICs with multi-row columnar die interconnects has increased die-to-die (D2D) interconnect density in a conductive layer. Positioning the die interconnects in die interconnect column clusters, that each include a plurality of die interconnect rows and two columns, reduces the linear dimension occupied by the die interconnects and leaves room for more D2D interconnects. A die interconnect column cluster pitch is a distance between columns of adjacent die interconnect column clusters and this distance is greater than a die interconnect pitch between columns within the column clusters. Die interconnects may be disposed in the space between the multi-row column clusters and additional die interconnects can be disposed at the D2D interconnect pitch between the die interconnect column clusters. IC packages with ICs including the multi-row columnar die interconnects have a greater number of D2D interconnects for better IC integration.