Integrated circuit decoupling capacitance systems, arrangements, and assemblies are discussed herein. In one example, an assembly includes an integrated circuit device comprising a plurality of through silicon vias (TSVs) coupled to corresponding voltage domains of the integrated circuit device. The assembly includes one or more capacitive elements external to the integrated circuit device and conductively coupled to selected ones of the TSVs.

An embodiment is a method including forming a first passive device in a first wafer, forming a first dielectric layer over a first side of the first wafer, forming a first plurality of bond pads in the first dielectric layer, planarizing the first dielectric layer and the first plurality of bond pads to level top surfaces of the first dielectric layer and the first plurality of bond pads with each other, hybrid bonding a first device die to the first dielectric layer and at least some of the first plurality of bond pads, and encapsulating the first device die in a first encapsulant.

A semiconductor package includes an integrated passive device (IPD) including one or more passive devices over a first substrate; and metallization layers over and electrically coupled to the one or more passive devices, where a topmost metallization layer of the metallization layers includes a first plurality of conductive patterns; and a second plurality of conductive patterns interleaved with the first plurality of conductive patterns. The IPD also includes a first under bump metallization (UBM) structure over the topmost metallization layer, where the first UBM structure includes a first plurality of conductive strips, each of the first plurality of conductive strips electrically coupled to a respective one of the first plurality of conductive patterns; and a second plurality of conductive strips interleaved with the first plurality of conductive strips, each of the second plurality of conductive strips electrically coupled to a respective one of the second plurality of conductive patterns.

An exemplary assembly includes a top circuit substrate; a bottom circuit assembly that underlays the top circuit substrate and is attached to the top circuit substrate by an adhesive layer as a stiffener, the adhesive layer, and a plurality of conductive balls. The top circuit substrate includes a plurality of upper vias that extend through the top circuit substrate. The bottom circuit assembly includes a plurality of lower vias that extend through the bottom circuit assembly. The adhesive layer includes internal connections that electrically connect the upper vias to the lower vias. The conductive balls are housed in the lower vias. The bottom circuit assembly has an elastic modulus at least six times the elastic modulus of the top circuit substrate, and has a coefficient of thermal expansion at least two times the coefficient of thermal expansion of the top circuit substrate.

A semiconductor device includes a semiconductor substrate, a transistor, and a first harmonic termination circuit. The transistor is formed at the semiconductor substrate. The transistor amplifies an input signal supplied to an input end and outputs an amplified signal through an output end. The first harmonic termination circuit attenuates a harmonic component included in the amplified signal. The first harmonic termination circuit is formed at the semiconductor substrate such that one end of the first harmonic termination circuit is connected to the output end of the transistor and the other end of the first harmonic termination circuit is connected to a ground end of the transistor.

A semiconductor device includes a first electrode disposed on a substrate. A capacitor dielectric layer is on the first electrode. A second electrode is on the capacitor dielectric layer. A first insulating layer is on the first and second electrodes and the capacitor dielectric layer. A first interconnection structure is on the first insulating layer and connected to the first electrode. A second interconnection structure is on the first insulating layer and connected to the second electrode. A second insulating layer is on the first and second interconnection structures. A plurality of connection structures are configured to pass through the second insulating layer and be connected to the first and second interconnection structures. Each of the first and second interconnection structures has an aluminum layer.

Systems that include integrated circuit dies and voltage regulator units are disclosed. Such systems may include a voltage regulator module and an integrated circuit mounted in a common system package. The voltage regulator module may include a voltage regulator circuit and one or more passive devices mounted to a common substrate, and the integrated circuit may include a System-on-a-chip. The system package may include an interconnect region that includes wires fabricated on multiple conductive layers within the interconnect region. At least one power supply terminal of the integrated circuit may be coupled to an output of the voltage regulator module via a wire included in the interconnect region.

A package structure includes an insulating encapsulation, a semiconductor die, and a filter structure. The semiconductor die is encapsulated in the insulating encapsulation. The filter structure is electrically coupled to the semiconductor die, wherein the filter structure includes a patterned metallization layer with a pattern having a double-spiral having aligned centroids thereof.

A die can be applied to a front conductive layer. Openings can be formed in the conductive layer over contact points on the die. The openings can be filled with a conductive material to electrically couple the conductive layer to the contact points on the die. The front conductive layer can be etched to form a first conductive pattern. Conductive standoffs can be formed on portions of the front conductive layer. An additional front conductive layer can be laminated onto the front side. Openings can be formed in the additional front conductive layer over the standoffs. The openings can be filled with a conductive material to electrically couple the additional conductive layer to the underlying standoffs. The additional conductive layer can be etched to form a second conductive pattern.

Embodiments include semiconductor packages. A semiconductor package includes a plurality of dies on a package substrate, and a plurality of smart dies on the package substrate, where the plurality of smart dies include a plurality of interconnects and a plurality of capacitors. The semiconductor package also includes a plurality of routing lines coupled to the dies and the smart dies, where the routing lines are communicatively coupled to the interconnects of the smart dies, where each of the dies has at least two or more routing lines to communicatively couple the dies together, and where one of the routing lines is via the interconnects of the smart dies. The capacitors may be a plurality of metal-insulator-metal (MIM) capacitors. The dies may be a plurality of active dies. The routing lines may communicatively couple first and second active dies to first and second smart dies.