A power module includes a number of sub-modules connected via removable jumpers. The removable jumpers allow the connections between one or more power semiconductor die in the sub-modules to be reconfigured, such that when the removable jumpers are provided, the power module has a first function, and when the removable jumpers are removed, the power module has a second function. The removable jumpers may also allow for independent testing of the sub-modules. The power module may also include a multi-layer printed circuit board (PCB), which is used to connect one or more contacts of the power semiconductor die. The multi-layer PCB reduces stray inductance between the contacts and therefore improves the performance of the power module.

Some examples described herein relate to redundancy in a multi-chip stacked device. An example described herein is a multi-chip device. The multi-chip device includes a chip stack including vertically stacked chips. Neighboring pairs of the chips are directly connected together. Each of two or more of the chips includes a processing integrated circuit. The chip stack is configurable to operate a subset of functionality of the processing integrated circuits of the two or more of the chips when any portion of the processing integrated circuits is defective.

Some examples described herein relate to redundancy in a multi-chip stacked device. An example described herein is a multi-chip device. The multi-chip device includes a chip stack including vertically stacked chips. Neighboring pairs of the chips are directly connected together. Each of two or more of the chips includes a processing integrated circuit. The chip stack is configurable to operate a subset of functionality of the processing integrated circuits of the two or more of the chips when any portion of the processing integrated circuits is defective.

The present disclosure relates to a semiconductor device package. The semiconductor device package includes a substrate, a support structure, an electronic component and an adhesive. The support structure is disposed on the substrate. The electronic component is disposed on the support structure. The adhesive is disposed between the substrate and the electronic component and covers the support structure. A hardness of the support structure is less than a hardness of the electronic component.

An integrated circuit device that may include programmable logic fabric disposed on an integrated circuit die and a base die that may include clocking circuitry. Synchronization between logic resources in the programmable logic fabric may be performed using clock signals received from the clocking circuitry. The clocking circuitry in the base die may include phase-locked loops, delay-locked loops, clock trees, and other similar circuitry.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

A power module includes a number of sub-modules connected via removable jumpers. The removable jumpers allow the connections between one or more power semiconductor die in the sub-modules to be reconfigured, such that when the removable jumpers are provided, the power module has a first function, and when the removable jumpers are removed, the power module has a second function. The removable jumpers may also allow for independent testing of the sub-modules. The power module may also include a multi-layer printed circuit board (PCB), which is used to connect one or more contacts of the power semiconductor die. The multi-layer PCB reduces stray inductance between the contacts and therefore improves the performance of the power module.

Disclosed is a multi-chip module (MCM) with redundant chip-to-chip communication connection(s) to minimize the need to discard a chip-mounting layer due to defective signal traces. The MCM includes at least first and second chips mounted on the chip-mounting layer. The chip-mounting layer includes signal traces that are electrically connected between first and second links on the first and second chips, respectively, to form communication connections including at least one redundant communication connection. Instead of being directly connected to the chip-to-chip communication connections, first and second interfaces on the first and second chips are connected via first and second multiplexors, respectively, to selected ones of multiple chip-to-chip communication connections. By employing the multiplexors and the redundant chip-to-chip communication connection(s), chip-to-chip communication connection(s) with defective signal trace(s) can be bypassed. Specifically, during MCM assembly, the multiplexors are programmed to avoid using chip-to-chip communication connections with defective signal traces.

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.

Passive semiconductor components and switches may be formed directly in, on, about, or across each of two or more semiconductor dies included in a stacked-die semiconductor package. At least some of the passive semiconductor components and/or switches may be formed in redistribution layers operably coupled to corresponding semiconductor dies included in the stacked-die semiconductor package. The switches may have multiple operating states and may be operably coupled to the passive semiconductor components such that one or more passive semiconductor components may be selectively included in one or more circuits or excluded from one or more circuits. The switches may be manually controlled or autonomously controlled using one or more control circuits. The one or more control circuits may receive one or more input signals containing host system information and/or data that is used to adjust or set the operating state of at least some of the switches.