A semiconductor structure includes a semiconductor wafer having at least one semiconductor device integrated in a first device layer, a thermally conductive but electrically isolating layer on a back side of the semiconductor wafer, a front side glass on a front side of the semiconductor wafer, where the thermally conductive but electrically isolating layer is configured to dissipate heat from the at least one semiconductor device integrated in the semiconductor wafer. The thermally conductive but electrically isolating layer is selected from the group consisting of aluminum nitride, beryllium oxide, and aluminum oxide. The at least one semiconductor device is selected from the group consisting of a complementary-metal-oxide-semiconductor (CMOS) switch and a bipolar complementary-metal-oxide-semiconductor (BiCMOS) switch. The semiconductor structure also includes at least one pad opening extending from the back side of the semiconductor wafer to a contact pad.

A high frequency semiconductor amplifier includes a package base part, and a monolithic microwave integrated circuit. The package base part includes a metal plate provided with an attachment hole, a frame body bonded to the metal plate and provided with an opening, a first lead part, and a second lead part. The monolithic microwave integrated circuit is provided with a first amplification element and a second amplification element. An output electrode of the second amplification element is connected to the second lead part via an output combiner. Each finger electrode of the second amplification element is generally orthogonal to the first line. Each finger electrode of the first amplification element is generally parallel to the first line. The attachment hole of the metal plate is provided in a region lying along a second line generally orthogonal to the first line and protruding outside the frame body.

A wafer-scale die packaging device is fabricated by providing a high-k glass carrier substrate having a ceramic region which includes a defined waveguide area and extends to a defined die attach area, and then forming, on a first glass carrier substrate surface, a differential waveguide launcher having a pair of signal lines connected to a radiating element that is positioned adjacent to an air cavity and surrounded by a patterned array of conductors disposed over the ceramic region in a waveguide conductor ring. After attaching a die to the glass carrier substrate to make electrical connection to the differential waveguide launcher, a molding compound is formed to cover the die, differential waveguide launcher, and air cavity, and an array of conductors is formed in the molding compound to define a first waveguide interface perimeter surrounding a first waveguide interface interior.

The present invention relates to the field of integrating electronic systems that operate at mm-wave and THz frequencies. A monolithic multichip package, a carrier structure for such a package as well as manufacturing methods for manufacturing such a package and such a carrier structure are proposed to obtain a package that fully shields different functions of the mm-wave/THz system. The package is poured into place by polymerizing photo sensitive monomers. It gradually grows around and above the MMICs (Monolithically Microwave Integrated Circuit) making connection to the MMICs but recessing the high frequency areas of the chip. The proposed approach leads to functional blocks that are electromagnetically completely shielded. These units can be combined and cascaded according to system needs.

The present disclosure relates to a semiconductor chip that includes a substrate, a metal layer, and a number of component portions. Herein, the substrate has a substrate base and a number of protrusions protruding from a bottom surface of the substrate base. The substrate base and the protrusions are formed of a same material. Each of the protrusions has a same height. At least one via hole extends vertically through one protrusion and the substrate base. The metal layer selectively covers exposed surfaces at a backside of the substrate and fully covers inner surfaces of the at least one via hole. The component portions reside over a top surface of the substrate base, such that a certain one of the component portions is electrically coupled to a portion of the metal layer at the top of the at least one via hole.

The disclosure is directed to an electronic device with a lid to manage radiation feedback. The electronic device includes a lid having at least one sidewall and a top wall, as well as a semiconductor positioned within a cavity of the lid. In certain embodiments, the lid includes at least one dielectric material and at least one internal conductive layer at least partially embedded within the at least one dielectric material. In certain embodiments, the lid includes dielectric material, as well as an internal wall extending from the top wall and positioned between an input port and an output port of the semiconductor. Such configurations may suppress any undesirable feedback through the lid between the input port and the output port of the semiconductor.

A transistor device includes a metal submount; a transistor die arranged on said metal submount; at least one integrated passive device (IPD) component that includes a substrate arranged on said metal submount; and one or more interconnects extending between the transistor die and the at least one integrated passive device (IPD) component. The substrate includes a silicon carbide (SiC) substrate.

A packaged electronic circuit includes a substrate having an upper surface, a first metal layer on the upper surface of the substrate, a first polymer layer on the first metal layer opposite the substrate, a second metal layer on the first polymer layer opposite the first metal layer, a dielectric layer on the first polymer layer and at least a portion of the second metal layer and a second polymer layer on the dielectric layer.

There is provided an integrated RF subsystem including a chip substrate, a circuit patterned on a first surface of the chip substrate, a probe electrically integrated with the circuit on a first side of the chip substrate, a frame at a second side of the chip substrate defining a first cavity underneath the circuit.

A technique for making high performance low noise amplifiers, low cost high performance RF, microwave circuits and other devices by using a minimum of costly high performance semiconductors is described. By combining a single discrete portion of an expensive semiconductor with a less expensive GaAs carrier, MMIC devices with improved performance over their discrete counterparts are achieved.