Disclosed is a semiconductor device. In an aspect, a semiconductor device includes: a first-tier passive device including a substrate portion, a passive device portion, and a metallization portion disposed in a stacked configuration; and one or more second-tier passive devices disposed over the first-tier passive device. Each one of the one or more second-tier passive devices includes: a substrate portion, a passive device portion, and a metallization portion disposed in a stacked configuration; and a set of through substrate vias (TSVs) passing through a corresponding substrate portion and electrically coupled to a corresponding metallization portion. The semiconductor device comprises a passive component including the passive device portion of the first-tier passive device electrically coupled to one or more passive device portions of the one or more second-tier passive devices through the metallization portions of the first-tier passive device and the one or more second-tier passive devices.

A manufacturing method of a package includes at least the following steps. Contact vias are embedded in a semiconductor carrier. The contact vias are electrically grounded. A first die and a first encapsulant are provided over the semiconductor carrier. The first encapsulant encapsulates the first die. First through insulating vias (TIV) are formed aside the first die. The first TIVs are electrically grounded through the contact vias. The first die, the first encapsulant, and the first TIVs are grinded. A second die is stacked over the first die.

Multi-chip modules and methods of fabrication are described. The MCM may include a plurality of dies in which die-to-die routing can be partitioned within multiple metal routing layers for shorter die-to-die routings, while longer die-to-die routing can be routed primarily in a single metal routing layer. The plurality of dies may also be arranged in a spaced apart relationship to accommodate additional wiring area, while preserving direct routing areas for the longer die-to-die routing.

A package includes a first die, a second die, a first encapsulant, first through insulating vias (TIV), second encapsulant, and second TIVs. The second die is stacked on the first die. The first encapsulant laterally encapsulates the first die. The first TIVs are aside the first die. The first TIVs penetrate through the first encapsulant and are electrically floating. The second encapsulant laterally encapsulates the second die. The second TIVs are aside the second die. The second TIVs penetrate through the second encapsulant and are electrically floating. The second TIVs are substantially aligned with the first TIVs.

An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, a third bonding pad structure, a first internal bonding wire, and a second internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The third bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the third bonding pad structure via the first internal bonding wire. The third bonding pad structure is electrically coupled to the second bonding pad structure via the second internal bonding wire.

An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, and an internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the second bonding pad structure via the internal bonding wire. The integrated circuit device having a better electrical performance is provided by eliminating internal resistance drop in power supply trails or ground trails, and improving signal integrity of the integrated circuit device.

In a process, at least one circuit element is formed in a substrate. A conductive layer is formed over the substrate and in electrical contact with the at least one circuit element. Electrostatic charges are discharged from the substrate via the conductive layer.

In examples, a method for manufacturing a package comprises depositing a metal contact layer on a surface of a wafer, the wafer including first and second diodes; positioning the wafer on an expandable tape coupled to a carrier; dicing the wafer to produce first and second dies, the first die including the first diode and the second die including the second diode; wire bonding the first die to the second die using a bond wire; covering the first and second dies and the bond wire with a mold compound to produce a molded structure; decoupling the molded structure from the expandable tape; and sawing the molded structure to produce the package.

The present invention discloses a package structure and a method for forming the same. The package structure includes a substrate, a chip, a first plastic package layer and a support block, wherein the substrate includes a first surface and a second surface; the chip is disposed on the first surface; the first plastic package layer is disposed on the first surface and packages the chip; the support block is disposed on the second surface; and in a thickness direction of the substrate, an overlapping region exists between the chip and the support block, and a thermal expansion coefficient of the chip is equal to a thermal expansion coefficient of the support block. The support block can counteract part of stress to avoid problems such as warping or twisting. Due to the overlapping region, a counteraction function of the support block on the stress exerted on the chip can be improved.

Multi-chip modules and methods of fabrication are described. The MCM may include a plurality of dies in which die-to-die routing can be partitioned within multiple metal routing layers for shorter die-to-die routings, while longer die-to-die routing can be routed primarily in a single metal routing layer. The plurality of dies may also be arranged in a spaced apart relationship to accommodate additional wiring area, while preserving direct routing areas for the longer die-to-die routing.