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.

An IC chip includes I/O bumps on a back side, a first die, a second die, a first circuit, and a second circuit. The first die has driver circuits for LED devices, the LED devices being located on a front-facing surface of the first die. The first circuit extends from the front side toward the back side and across a thickness of the first die. The first circuit provides electrical connections between the LED devices and at least some of the I/O bumps. The first die and the second die can be stacked vertically or arranged laterally adjacent. The second circuit extends between the first die and the second die to electrically connect the first die and the second die. A circuit board can be electrically connected to the IC chip through the I/O bumps to, among other things, provide power to the various components of the IC chip.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a package substrate including a first conductive pathway electrically coupled to a power source; a first microelectronic component embedded in an insulating material on the surface of the package substrate and including a TSV electrically coupled to the first conductive pathway; a redistribution layer (RDL) on the insulating material including a second conductive pathway electrically coupled to the TSV; and a second microelectronic component on the RDL and electrically coupled to the second conductive pathway, wherein the second conductive pathway electrically couples the TSV, the second microelectronic component, and the first microelectronic component.

Microelectronic assemblies, related devices and methods, are disclosed herein. In some embodiments, a microelectronic assembly may include a package substrate including a first conductive pathway electrically coupled to a power source; a mold material on the package substrate including a first microelectronic component embedded in the mold material, a second microelectronic component embedded in the mold material, and a TMV, between the first and second microelectronic components, the TMV electrically coupled to the first conductive pathway; a redistribution layer (RDL) on the mold material including a second conductive pathway electrically coupled to the TMV; and a third microelectronic component on the RDL and electrically coupled to the second conductive pathway, wherein the second conductive pathway electrically couples the TMV, the first microelectronic component, and the third microelectronic component.

A wireless transmission module, chips, a passive component, and a coil are integrated into an integral structure, so that an integration level of the wireless transmission module is improved. In addition, the integral structure can effectively implement independence of the module, and the independent module can be flexibly arranged inside structural design of an electronic device, and does not need to be disposed on a mainboard of the electronic device. Only an input terminal of the wireless transmission module needs to be retained on the mainboard of the electronic device. In addition, the integral structure can further effectively increase a capability of a product for working continuously and normally in an extremely harsh scenario, and improve product reliability. In addition, in the structure of the wireless transmission module, the chips and the coil are integrated, and signal transmission paths between the chips and the coil are relatively short.

In an embodiment, a device includes: a package component including integrated circuit dies, an encapsulant around the integrated circuit dies, a redistribution structure over the encapsulant and the integrated circuit dies, and sockets over the redistribution structure; a mechanical brace physically coupled to the sockets, the mechanical brace having openings, each one of the openings exposing a respective one of the sockets; a thermal module physically and thermally coupled to the encapsulant and the integrated circuit dies; and bolts extending through the thermal module, the mechanical brace, and the package component.

An integrated radar circuit comprising: a first substrate, of a first semiconductor material, said first substrate comprising an integrated transmit and receive radar circuit; a second substrate, of a second semiconductor material, said second substrate comprising at least on through-substrate cavity having cavity walls; at least one discrete transistor chip, of a third semiconductor material, said at least one discrete transistor chip having chip walls and being held in said at least one through-substrate cavity by a metal filling extending from at least one cavity wall to at least one chip wall; a conductor on said second substrate, electrically connecting a portion of said integrated transmit and receive radar circuit to a discrete transistor on said at least one discrete transistor chip.

Provided is a semiconductor device, including: a first electrode layer including a first wiring member and a second electrode layer including a second wiring member, the first electrode layer and the second electrode layer being disposed to face each other; a semiconductor element disposed in a gap between the first and second electrode layers, and electrically connected to the first and second electrode layers; and a via disposed in the gap between the first and second electrode layers, electrically connected to the first and second electrode layers, and configured to detect a state of the semiconductor element by being fractured at a predetermined temperature and losing electric connection.

A semiconductor package includes a semiconductor substrate forming a cavity and a redistribution layer on a first side of the semiconductor substrate, the redistribution layer forming die contacts within the cavity and a set of terminals for the semiconductor package opposite the semiconductor substrate. The redistribution layer electrically connects one or more of the die contacts to the set of terminals. The semiconductor package further includes a semiconductor die including die terminals within the cavity with the die terminals electrically coupled to the die contacts within the cavity.

An embodiment is a method including depositing a first dielectric layer over a molding compound and a chip and patterning a first opening in the first dielectric layer to expose a contact of the chip. A first metallization layer is deposited over the first dielectric layer and in the first opening, where a portion of the first metallization layer in the first opening has a flat top. A second dielectric layer is deposited over the first metallization layer and the first dielectric layer. A second metallization layer is deposited in a second opening in the second dielectric layer, where the second metallization layer does not have a flat top within the second opening.