Abstract: A mechanism is provided to remove heat from an integrated circuit (IC) device die by directing heat through a waveguide to a heat sink. The waveguide is mounted on top of a package containing the IC device die. The waveguide is thermally coupled to the IC device die. The waveguide transports the heat to a heat sink coupled to the waveguide and located adjacent to the package on top of a printed circuit board on which the package is mounted. Embodiments provide both thermal dissipation of the generated heat while at the same time maintaining good radio frequency performance of the waveguide.

Abstract: A method of manufacturing a semiconductor device packaging panel is provided. The method includes forming a panel by placing a plurality of semiconductor die on a major side of a carrier substrate and encapsulating with an encapsulant the plurality semiconductor die and the major side of the carrier substrate. A plurality of warpage control features are formed with the encapsulant while encapsulating. The method further includes placing the panel onto a warpage control fixture to substantially flatten the panel. The plurality of warpage control features interlock with mating features of the warpage control fixture.

Abstract: A package comprising, an integrated circuit, IC, die comprising circuitry configured to generate signalling for transmission to a waveguide and/or receive signalling from a waveguide via a launcher, the die coupled to an interconnect layer extending out from a footprint of the die; and the launcher is formed in a launcher-substrate, separate from the die, the launcher coupled to the die to pass said signalling therebetween by a connection in said interconnect layer, wherein said launcher comprises a launcher element mounted in a first plane within the launcher-substrate and a waveguide-cavity comprising a ground plane arranged opposed to and spaced from the first plane, the waveguide-cavity further defined by at least one side wall extending from the ground plane towards the first plane; and wherein said die and said launcher are at least partially surrounded by mould material of said package.

Abstract: A semiconductor device having an integrated antenna is provided. The semiconductor device includes a base die having an integrated circuit formed at an active surface and a cap die bonded to the backside surface of the base die. A metal trace is formed over a top surface of the cap die. A cavity is formed under the metal trace. A conductive via is formed through the base die and the cap die interconnecting the metal trace and a conductive trace of the integrated circuit.

Abstract: A semiconductor device package having a thermal dissipation feature is provided. The semiconductor device package includes a package substrate. A semiconductor die is mounted on a first surface of the package substrate. A first conductive connector is affixed to a first connector pad of the package substrate. A conformal thermal conductive layer is applied on the semiconductor die and a portion of the first surface of the package substrate. The conformal thermal conductive layer is configured and arranged as a thermal conduction path between the semiconductor die and the first conductive connector.

Abstract: A semiconductor device package that incorporates a waveguide usable for high frequency applications, such as radar and millimeter wave is provided. Embodiments employ a rigid-flex printed circuit board structure that can be folded to form the waveguide while, at the same time, mounting one or more semiconductor device die or packages. Embodiments reduce both the area of the mounted package and the distance signals need to travel between the semiconductor device die and antennas associated with the waveguide.

Abstract: A mechanism is provided to remove heat from an integrated circuit (IC) device die by directing heat through a waveguide to a heat sink. Embodiments provide the waveguide mounted on top of a package containing the IC device die. The waveguide is thermally coupled to the IC device die. The waveguide transports the heat to a heat sink coupled to the waveguide and located adjacent to the package on top of a printed circuit board on which the package is mounted. Embodiments provide both thermal dissipation of the generated heat while at the same time maintaining good radio frequency (RF) performance of the waveguide.

Abstract: A semiconductor device is provided. The device includes a semiconductor die and a launcher structure attached to a package substrate. The launcher structure includes a launcher substrate, a launcher portion formed from a conductive layer at a major surface of the launcher substrate, and a translation pad formed from the conductive layer at the major surface. The translation pad is separate from the launcher portion. A translation feature is formed on the translation pad. The translation feature is configured for alignment of a waveguide structure.

Abstract: A semiconductor device package having stress isolation is provided. The semiconductor device package includes a package substrate and a sensor attached to the package substrate. A first isolation material is formed around a perimeter of the sensor. An encapsulant encapsulates at least a portion of the first isolation material and the package substrate.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes forming an assembly including placing a semiconductor die and a launcher structure on a carrier substrate, encapsulating at least a portion of the semiconductor die and the launcher structure, and applying a redistribution layer on a surface of the semiconductor die and a surface of the launcher structure to connect a bond pad of the semiconductor die with an antenna launcher of the launcher structure. The assembly is attached to a substrate and a waveguide overlapping the assembly is attached to the substrate. The waveguide structure is physically decoupled from the assembly.

Abstract: A mechanism is provided to reduce a distance of a waveguide antenna from transmit and receive circuitry in an integrated circuit device die. This distance reduction is performed by providing vertical access to radio frequency connections on a top surface of the IC device die. A cavity in the encapsulant of the package can be formed to provide access to the connections and plated to perform a shielding function. A continuous connection from the RF pads is used as a vertical interconnect. The region around the vertical interconnect can be filled with encapsulant potting material and back grinded to form a surface of the semiconductor device package. A waveguide antenna feed can be plated or printed on the vertical interconnect on the surface of the package.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes forming an assembly including placing a semiconductor die and a launcher structure on a carrier substrate, encapsulating at least a portion of the semiconductor die and the launcher structure, and applying a redistribution layer on a surface of the semiconductor die and a surface of the launcher structure to connect a bond pad of the semiconductor die with an antenna launcher of the launcher structure. The assembly is attached to a substrate and a waveguide overlapping the assembly is attached to the substrate. The waveguide structure is physically decoupled from the assembly.

Abstract: A semiconductor device includes a substrate, an IC die mounted on the substrate, packaging encapsulant on the substrate, a cavity in the packaging encapsulant, a conductive lid attached to the packaging encapsulant over the IC die, an electrical ground path in the substrate, and a first conductive structure in the cavity. The first conductive structure includes a first end electrically coupled to the conductive lid and a second end electrically coupled to the electrical ground path.

Abstract: A semiconductor device package is provided that incorporates an antenna structure within the package through use of three-dimensional additive manufacturing processes. Embodiments can provide semiconductor device packages that are thinner than traditional device packages by depositing specific metal and dielectric layers within the package in desired positions with precision that cannot be provided by other manufacturing techniques. Further, embodiments can provide antenna geometries and orientations that cannot be provided by other manufacturing techniques.

Abstract: A no-gel sensor package is disclosed. In one embodiment, the package includes a microelectromechanical system (MEMS) die having a first substrate, which in turn includes a first surface on which is formed a MEMS device. The package also includes a polymer ring with an inner wall extending between first and second oppositely facing surfaces. The first surface of the polymer ring is bonded to the first surface of the first substrate to define a first cavity in which the MEMS device is contained. A molded compound body having a second cavity that is concentric with the first cavity, enables fluid communication between the MEMS device and an environment external to the package.

Abstract: A mechanism is provided to remove heat from an integrated circuit (IC) device die by directing heat through a waveguide to a heat sink. Embodiments provide the waveguide mounted on top of a package containing the IC device die. The waveguide is thermally coupled to the IC device die. The waveguide transports the heat to a heat sink coupled to the waveguide and located adjacent to the package on top of a printed circuit board on which the package is mounted. Embodiments provide both thermal dissipation of the generated heat while at the same time maintaining good radio frequency (RF) performance of the waveguide.

Abstract: A mechanism is provided to remove heat from an integrated circuit (IC) device die by directing heat through a waveguide to a heat sink. The waveguide is mounted on top of a package containing the IC device die. The waveguide is thermally coupled to the IC device die. The waveguide transports the heat to a heat sink coupled to the waveguide and located adjacent to the package on top of a printed circuit board on which the package is mounted. Embodiments provide both thermal dissipation of the generated heat while at the same time maintaining good radio frequency performance of the waveguide.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes forming an assembly including placing a semiconductor die and a launcher structure on a carrier substrate, encapsulating at least a portion of the semiconductor die and the launcher structure, and applying a redistribution layer on a surface of the semiconductor die and a surface of the launcher structure to connect a bond pad of the semiconductor die with an antenna launcher of the launcher structure. The assembly is attached to a substrate and a waveguide overlapping the assembly is attached to the substrate. The waveguide structure is physically decoupled from the assembly.

Abstract: A method of manufacturing a packaged semiconductor device is provided. The method includes attaching a semiconductor die to a package substrate. A bond pad of the semiconductor die is coupled to an antenna radiator formed on the package substrate. A waveguide is attached to the package substrate. An opening of the waveguide includes sidewalls substantially surrounding the antenna radiator. An epoxy material is deposited over at least a portion of the package substrate while leaving the opening void of epoxy material.

Abstract: A mechanism is provided to reduce a distance of a waveguide antenna from transmit and receive circuitry in an integrated circuit device die. This distance reduction is performed by providing vertical access to radio frequency connections on a top surface of the IC device die. A cavity in the encapsulant of the package can be formed to provide access to the connections and plated to perform a shielding function. A continuous connection from the RF pads is used as a vertical interconnect. The region around the vertical interconnect can be filled with encapsulant potting material and back grinded to form a surface of the semiconductor device package. A waveguide antenna feed can be plated or printed on the vertical interconnect on the surface of the package.