A three-dimensional programmable interconnection system based on a multi-chip package includes: a programmable metal bump or pad at a bottom of the multi-chip package; a first programmable interconnect provided by an interposer of the multi-chip package; a second programmable interconnect provided by the interposer; and a switch provided by a first semiconductor chip of the multi-chip package, wherein the switch is configured to control connection between the first and second programmable interconnects, wherein the programmable metal bump or pad couples to a second semiconductor chip of the multi-chip package through the switch and the first and second programmable interconnects, wherein the first and second semiconductor chips are over the interposer.

An electronic device includes one or more multinode pads having two or more conductive segments spaced from one another on a semiconductor die. A conductive stud bump is selectively formed on portions of the first and second conductive segments to program circuitry of the semiconductor die or to couple a supply circuit to a load circuit. The multinode pad can be coupled to a programming circuit in the semiconductor die to allow programming a programmable circuit of the semiconductor die during packaging. The multinode pad has respective conductive segments coupled to the supply circuit and the load circuit to allow current consumption or other measurements during wafer probe testing in which the first and second conductive segments are separately probed prior to stud bump formation.

A set of features for a product is identified. It is determined that preventing an electrical connection at a ball-grid-array location on a ball-grid-array assembly of the product would result in the set of features. The ball-grid-array location is established as a target BGA location based on that determination. Suction is applied to a via at the target BGA location during reflow of the ball-grid-array assembly. With that application of suction, a solder ball at the target BGA location is drawn into the via.

Programmable interposers for connecting integrated circuits, methods for programming programmable interposers, and integrated circuit packaging are provided. The programmable interposers are electrically reconfigurable to allow custom system-in-package (SiP) operation and configuration, field configurability, and functional obfuscation for secure integrated circuits fabricated in non-trusted environments. The programmable interposer includes, in one implementation, an interposer substrate and a programmable metallization cell (PMC) switch. The PMC switch is formed on the interposer substrate and is coupled between a signal input and a signal output. The PMC switch is electrically configurable between a high resistance state and a low resistance state.

A package structure including at least one semiconductor die and a redistribution structure is provided. The semiconductor die is laterally encapsulated by an encapsulant, and the redistribution structure is disposed on the semiconductor die and the encapsulant and electrically connected with the semiconductor die. The redistribution structure includes signal lines and a pair of repair lines. The signal lines include a pair of first signal lines located at a first level, and each first signal line of the pair of first signal lines has a break that split each first signal line into separate first and second fragments. The pair of repair lines is located above the pair of first signal lines and located right above the break. Opposite ending portions of each repair line are respectively connected with the first and second fragments with each repair line covering the break in each first signal line.

A multichip package includes: a chip package comprising a first IC chip, a polymer layer in a space beyond and extending from a sidewall of the first IC chip, a through package via in the polymer layer, an interconnection scheme under the first IC chip, polymer layer and through package via, and a metal bump under the interconnection scheme and at a bottom of the chip package, wherein the first IC chip comprises memory cells for storing data therein associated with resulting values for a look-up table (LUT) and a selection circuit comprising a first input data set for a logic operation and a second input data set associated with the data stored in the memory cells, wherein the selection circuit selects, in accordance with the first input data set, data from the second input data set as an output data for the logic operation; and a second IC chip over the chip package, wherein the second IC chip couples to the first IC chip through, in sequence, the through package via and interconnection scheme, wherein the second IC chip comprises a hard macro having an input data associated with the output data for the logic operation.

A semiconductor device includes a first chip package, a heat dissipation structure and an adapter. The first chip package includes a semiconductor die laterally encapsulated by an insulating encapsulant, the semiconductor die has an active surface and a back surface opposite to the active surface. The heat dissipation structure is connected to the chip package. The adapter is disposed over the first chip package and electrically connected to the semiconductor die.

Methods, systems, and apparatus for reducing power consumption or signal distortions in a semiconductor device package. The semiconductor device package includes a semiconductor device, a first electric path, a second electric path, and an isolation element in the first electric path. The second electric path is electrically connected to the first electric path and a functional unit of the device. The isolation element separates an isolated portion in the first electric path from the second electric path, where the isolation element is configured to reduce current in the isolated portion when a signal is passing through the second electric path.

A system comprises an interposer including multiple conductive interconnects; multiple chiplets arranged on the interposer and interconnected by the interposer; each chiplet including a die-to-die physical layer interface including one or more pads to engage the interconnect of the interposer; and wherein at least one chiplet includes multiple input-output channels organized into at least one column and arranged in an order at a periphery of the chiplet forming a die-to-die physical layer interface to engage the interconnects of the interposer, wherein the order of the channels of the column is programmable.

Systems and methods to translate or convert a desired circuit into a database that instructs a place and route or wire bonding machine where on a substrate to place components and also where to place bond wires on the pads of a connection matrix on a substrate. During the assembly process, the pads of the connection matrix are populated with bond wires using the database.