A manufacturing method of an embedded component package structure includes the following steps: providing a carrier and forming a semi-cured first dielectric layer on the carrier, the semi-cured first dielectric layer having a first surface; providing a component on the semi-cured first dielectric layer, and respectively providing heat energies from a top and a bottom of the component to cure the semi-cured first dielectric layer; forming a second dielectric layer on the first dielectric layer to cover the component; and forming a patterned circuit layer on the second dielectric layer, the patterned circuit layer being electrically connected to the component.

The present disclosure provides a module including a circuit board, a first component and a second component. The circuit board includes a first side and a second side opposite to each other and includes a first plane and second plane disposed on the first side. A first height difference is formed between the first plane and the second plane. The first component and the second component are disposed on the first plane and the second plane, respectively. The first component and the second component include a first contact surface and a second contact surface, respectively. The first contact surface and the second contact surface are coplanar with a first surface of the module. It benefits to reduce the design complexity of a heat-transfer component, and enhance the heat dissipation capability and the overall power density of the module simultaneously.

A package structure including a circuit board and a heat generating element is provided. The circuit board includes a plurality of circuit layers and a composite material layer. A thermal conductivity of the composite material layer is between 450 W/mK and 700 W/mK. The heat generating element is disposed on the circuit board and electrically connected to the circuit layers. Heat generated by the heat generating element is transmitted to an external environment through the composite material layer.

Embodiments described herein may be related to apparatuses, processes, and techniques related to multilevel dies, in particular to photonics integrated circuit dies with a thick portion and a thin portion, where the thick portion is placed within a cavity in a substrate and the thin portion serves as an overhang to physically couple with the substrate, to reduce a distance between electrical contacts on the thin portion of the die and electrical contacts on the substrate. Other embodiments may be described and/or claimed.

Electronic packages and related methods are disclosed. An example electronic package apparatus includes a substrate and an electronic component. A protective material is positioned on a first surface, a second surface and all side surfaces of the electronic component to encase the electronic component. An enclosure is coupled to the substrate to cover the protective material and the electronic component.

An integrated circuit includes a lead frame, a first die, and a second die. The first die is bonded to and electrically connected to the lead frame. The second die is electrically connected to and spaced apart from the first die.

A semiconductor package includes a semiconductor chip including an electrode pad formed on the top surface thereof, a passive device embedded in the semiconductor package, the passive device having no functional electrode on the top surface thereof, a cover layer covering the semiconductor chip and the passive device, and at least one electrode pattern formed on the cover layer to transmit electrical signals. The cover layer includes at least one first opening formed to expose a region in which the functional electrode is to be formed. The electrode pattern includes a functional electrode portion formed in a region in which the functional electrode of the passive device is to be formed through the first opening. In the process of forming the electrode pattern, a functional electrode of the passive device is formed together therewith, thereby eliminating a separate step of manufacturing a functional electrode and thus reducing manufacturing costs.

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.

Implementations of semiconductor devices may include a die coupled over a lead frame, a redistribution layer (RDL) coupled over the die, a first plurality of vias coupled between the RDL and the die, and a second plurality of vias coupled over and directly to the lead frame. The second plurality of vias may be adjacent to an outer edge of the semiconductor device and may be electrically isolated from the die.

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.