A method of forming a packaged semiconductor device includes attaching a backside surface of a semiconductor die to a major surface of a package substrate. A first conductive connector is formed over a portion of an active surface of the semiconductor die and a portion of the major surface of the package substrate. A first conductive connection between a first bond pad of the semiconductor die and a first substrate pad of the package substrate is formed by way of the first conductive connector. A bond wire connects a second bond pad of the semiconductor die to a second substrate pad of the package substrate. The first bond pad located between the second bond pad and an edge of the semiconductor die.

A semiconductor package includes a semiconductor die including a sensing component, an encapsulant laterally covering the semiconductor die, a through insulator via (TIV) and a dummy TIV penetrating through the encapsulant, a patterned dielectric layer disposed on the top surfaces of the encapsulant and the semiconductor die, a conductive pattern disposed on and inserted into the patterned dielectric layer to be in contact with the TIV and the semiconductor die, and a first dummy conductive pattern disposed on the patterned dielectric layer and connected to the dummy TIV. The top surface of the encapsulant is above and rougher than a top surface of the semiconductor die, and the sensing component is accessibly exposed by the patterned dielectric layer.

An example of a printable electronic component includes a component substrate having a connection post side and an opposing contact pad side. The component can include one or more non-planar, electrically conductive connection posts protruding from the connection post side of the component substrate. Each of the one or more connection posts can have a peak area smaller than a base area. The component can include one or more non-planar, electrically conductive exposed component contact pads disposed on (e.g., directly on, indirectly on, or in) the contact pad side of the component substrate. Multiple components can be stacked such that connection post(s) of one are in contact with non-planar contact(s) of one or more others.

An embedded module according to the present invention includes a base substrate having a multi-layer wiring, at least two semiconductor chip elements having different element thicknesses, each of the semiconductor chip element having a first surface fixed to the base substrate and having a connection part on a second surface, an insulating photosensitive resin layer enclosing the semiconductor chip elements on the base substrate and being formed by a first wiring photo via, a second wiring photo via, and a wiring, the first wiring photo via electrically connected to the connection part of the semiconductor chip elements, the second wiring photo via arranged at the outer periphery of each of the semiconductor chip elements and electrically connected to a connection part of the base substrate, the wiring arranged so as to be orthogonal to and electrically connected to the first wiring photo via and the second wiring photo via.

A semiconductor package includes a semiconductor die including a sensing component, an encapsulant extending along sidewalls of the semiconductor die, a through insulator via (TIV) and a dummy TIV penetrating through the encapsulant and disposed aside the semiconductor die, a patterned dielectric layer disposed on the encapsulant and exposing the sensing component of the semiconductor die, a conductive pattern disposed on the patterned dielectric layer and extending to be in contact with the TIV and the semiconductor die, and a first dummy conductive pattern disposed on the patterned dielectric layer and connected to the dummy TIV through an alignment opening of the first patterned dielectric layer. The semiconductor die is in a hollow region of the encapsulant, and a top width of the hollow region is greater than a width of the semiconductor die.

A stack of electrical components has a first electrical component having a first surface, a second surface that is opposite to the first surface and a side surface that is located between the first surface and the second surface; a second electrical component having a third surface on which the first electrical component is mounted, the third surface facing the second surface and forming a corner portion between the third surface and the side surface; an adhesive layer that bonds the first electrical component to the second electrical component, the adhesive layer has a first portion that is located between the second and third surface and a second portion that is made of a same material as the first portion and that fills the corner portion; and a conductive layer that extends on a side of the side surface, curves along the second portion and extends to the third surface.

The disclosure relates to systems, and methods for improving connectivity of embedded components. Specifically, the disclosure relates to systems and methods for using additive manufacturing to improve connectivity of embedded components with the host structure and/or other embedded components by selectably bridging the gap naturally formed due to manufacturing variation and built in tolerances, between the embedded components or devices and the host structure, and between one embedded component and a plurality of other embedded components.

A stack of electrical components has a first electrical component having a first surface, a second surface that is opposite to the first surface and a side surface that is located between the first surface and the second surface; a second electrical component having a third surface on which the first electrical component is mounted, the third surface facing the second surface and forming a corner portion between the third surface and the side surface; an adhesive layer that bonds the first electrical component to the second electrical component, wherein the adhesive layer has a first portion that is located between the second surface and the third surface and a curved second portion that fills the corner portion; and a conductive layer that extends on a side of the side surface, curves along the second portion and extends to the third surface.

A semiconductor package may include a substrate including a first coupling terminal and a second coupling terminal, a first chip disposed on the substrate, the first chip including a first pad and a second pad, and a connection structure connecting the first coupling terminal to the first pad. A portion of the connection structure may be in contact with a first side surface of the first chip. The connection structure may include a connection conductor electrically connecting the first pad to the first coupling terminal.

An integrated circuit chip includes a front face having an electrical connection pad. An overmolded encapsulation block encapsulates the integrated circuit chip and includes a front layer at least partially covering a front face of the integrated circuit chip. A through-hole the encapsulation block is located above the electrical connection pad of the integrated circuit chip. A wall of the through-hole is covered with an inner metal layer that is joined to the front pad of the integrated circuit chip. A front metal layer covers a local zone of the front face of the front layer, with the front metal layer being joined to the inner metal layer to form an electrical connection. The inner metal layer and the front metal layer are attached or anchored to activated additive particles that are included in the material of the encapsulation block.