An integrated circuit device having separate dies for programmable logic fabric and circuitry to operate the programmable logic fabric are provided. A first integrated circuit die may include field programmable gate array fabric. A second integrated circuit die may be coupled to the first integrated circuit die. The second integrated circuit die may include fabric support circuitry that operates the field programmable gate array fabric of the first integrated circuit die.

A semiconductor package may include a semiconductor chip on a package substrate. The semiconductor package may include a plurality of conductive connections connecting the semiconductor chip to the package substrate may be disposed, a plurality of towers which are apart from one another and each include a plurality of memory chips may be disposed, wherein a lowermost memory chip of each of the plurality of towers overlaps the semiconductor chip from a top-down view. The semiconductor package further includes a plurality of adhesive layers be attached between the lowermost memory chip of each of the plurality of towers and the semiconductor chip.

A packaged IC includes a fanout layer, an Application Processor (AP) die having a first surface residing substantially adjacent a first surface of the fanout layer, a Redistribution Layer (RDL) having a first surface coupled to a second surface of the AP die Process, and high bandwidth memory coupled to a second surface of the RDL and configured to communicate wirelessly with the AP die. The packaged IC further includes an encapsulant surrounding a substantial portion of the high bandwidth memory, the RDL, and the AP die, the encapsulant contacting the fanout layer on a first side and having an exposed second side, a plurality of conductive posts extending from the fanout layer to the RDL through a portion of the encapsulant, and a plurality of Through Mold Vias (TMVs) extending between the fanout layer and the exposed second side of the encapsulant.

A semiconductor package may include a semiconductor chip on a package substrate. The semiconductor package may include a plurality of conductive connections connecting the semiconductor chip to the package substrate may be disposed, a plurality of towers which are apart from one another and each include a plurality of memory chips may be disposed, wherein a lowermost memory chip of each of the plurality of towers overlaps the semiconductor chip from a top-down view. The semiconductor package further includes a plurality of adhesive layers be attached between the lowermost memory chip of each of the plurality of towers and the semiconductor chip.

A semiconductor device includes a first terminal, a second terminal, and a plurality of third terminals on a substrate. Memory chips are stacked on the substrate in an offset manner. Each memory chip has first pads, second pads, and third pads thereon. A first bonding wire is electrically connected to the first terminal and physically connected to a first pad of each memory chip. A second bonding wire is electrically connected to the second terminal and physically connected to a second pad of each memory chip. A third bonding wire electrically connects one third terminal to a third pad on each memory chip. A fourth bonding wire is connected to the first bonding wire at a first pad on a first memory chip of the stack and another first pad on the first memory chip. The fourth bonding wire straddles over the second bonding wire and the third bonding wire.

An in-memory computing circuit is provided. The in-memory computing circuit includes a core die, a plurality of conductive pillars, and a plurality of memory dies. The plurality of memory dies are coupled to the core die through the plurality of conductive pillars and are configured to implement computing operation. The plurality of memory dies includes at least one of the memory dies disposed on a bottommost memory die of the plurality of memory dies. The plurality of memory dies receives an input data from the core die through a common input terminal of the core die.

A semiconductor package may include a semiconductor chip on a package substrate. The semiconductor package may include a plurality of conductive connections connecting the semiconductor chip to the package substrate may be disposed, a plurality of towers which are apart from one another and each include a plurality of memory chips may be disposed, wherein a lowermost memory chip of each of the plurality of towers overlaps the semiconductor chip from a top-down view. The semiconductor package further includes a plurality of adhesive layers be attached between the lowermost memory chip of each of the plurality of towers and the semiconductor chip.

A device may include a fabric die coupled to an active interposer. The fabric die may include programmable logic fabric and configuration memory that programs the programmable logic fabric. The programmable logic fabric of the fabric die may access at least a portion of the active interposer to perform an operation. As discussed herein, different power management techniques associated with the active interposer may be used to improve operation of the device.

The present invention provides a semiconductor module capable of improving a bandwidth between a logic chip and a RAM. According to the present invention, a semiconductor module 1 is provided with: a logic chip; a pair of RAM units 30 each composed of a lamination-type RAM module; a first interposer 10 electrically connected to the logic chip and to each of the pair of RAM units 30; and a connection unit 40 that communicatively connects the logic chip and each of the pair of RAM units 30, wherein one RAM unit 30a is placed on the first interposer 10, and has one end portion disposed so as to overlap, in the lamination direction C, one end portion of the logic chip with the connection unit 40 therebetween, and the other RAM unit 30b is disposed so as to overlap the one RAM unit 30a with the connection unit 40 therebetween, and is also disposed along the outer periphery of the logic chip.

A semiconductor module that can absorb thermal stress, and a manufacturing method therefor are provided. A semiconductor module includes a film interposer that includes a plurality of through electrodes which run in the thickness direction; a logic chip that is disposed on one surface side of the film interposer, and is connected electrically to the through electrodes; and a RAM unit that is a RAM module disposed on the other surface side of the film interposer, and connected electrically to the logic chip via the through electrodes.