A strip-line includes a ground plane extending through a plurality of dielectric layers over a substrate; a signal line over the substrate and on a side of the ground plane; a first plurality of metal strips under the signal line and in a first metal layer, wherein the first plurality of metal strips is parallel to each other, and is spaced apart from each other by spaces; and a second plurality of metal strips under the signal line and in a second metal layer over the first metal layer. The second plurality of metal strips vertically overlaps the spaces. The first plurality of metal strips is electrically coupled to the second plurality of metal strips through the ground plane, and no via physically contacts the first plurality of metal strips and the second plurality of metal strips.

A device includes: a first chip including a qubit; and a second chip bonded to the first chip, the second chip including a substrate including first and second opposing surfaces, the first surface facing the first chip, wherein the second chip includes a single layer of superconductor material on the first surface of the substrate, the single layer of superconductor material including a first circuit element. The second chip further includes a second layer on the second surface of the substrate, the second layer including a second circuit element. The second chip further includes a through connector that extends from the first surface of the substrate to the second surface of the substrate and electrically connects a portion of the single layer of superconducting material to the second circuit element.

A method of forming a semiconductor device is provided. The method includes providing a connector structure configured for carrying a signal and providing a semiconductor die. At least a portion of the connector structure and the semiconductor die are encapsulated with an encapsulant. The semiconductor die is interconnected with the connector structure by way of a conductive trace.

The present disclosure relates to a system in package having a chiplet with a first substrate and a first die deposed over the first substrate, a second die, a second substrate that the chiplet and the second die are deposed over, and a heatsink spreader deposed over the chiplet and the second die. Herein, the first substrate includes layered-cake shaped heatsink stanchions that are coupled to the first die, and the second substrate includes layered-cake shaped heatsink stanchions that are coupled to the chiplet and the second die. As such, heat generated by the first die can be dissipated by the heatsink stanchions within the first and second substrates, and heat generated by the second die can be dissipated by the heatsink stanchions within the second substrate. Furthermore, the heat generated by the first die and the second die can be dissipated by the heatsink spreader above them.

According to the present invention, an integrated circuit includes a first amplifier stage, a second amplifier stage, a first signal line connecting an output of the first amplifier stage and an input of the second amplifier stage to each other, a first plane for ground connected to the first amplifier stage, a second plane for ground connected to the second amplifier stage and at least one at least one line for ground connecting the first plane and the second plane to each other, wherein the at least one line has a center line having a length of 10 μm to 1 mm, a width of the at least one line is ⅓ or less of a width of the first plane, and a pattern ratio is 1 or more.

A device includes a semiconductor chip including an electrical contact arranged on a main surface of the semiconductor chip. The device includes an external connection element configured to provide a first coax-like electrical connection between the device and a printed circuit board, wherein the first coax-like electrical connection includes a section extending in a direction vertical to the main surface of the semiconductor chip. The device further includes an electrical redistribution layer arranged over the main surface of the semiconductor chip and configured to provide a second coax-like electrical connection between the electrical contact of the semiconductor chip and the external connection element, wherein the second coax-like electrical connection includes a section extending in a direction parallel to the main surface of the semiconductor chip.

There are disclosed impedance matching networks and technique for impedance matching to microwave power transistors. Distributed capacitor inductor networks are used so as to provide a high degree of control and accuracy, especially in terms of inductance values, in comparison to existing lumped capacitor arrangements. The use of bond wires is reduced, with inductance being provided primarily by microstrip transmission lines on the capacitors.

A method includes measuring a first calibration kit in a wafer to obtain a first performance data. The wafer includes a substrate, and a plurality of dielectric layers over the substrate. The first calibration kit includes a first passive device over the plurality of dielectric layers, wherein substantially no metal feature is disposed in the plurality of dielectric layers and overlapped by the first passive device. The method further includes measuring a second calibration kit in the wafer to obtain a second performance data. The second calibration kit includes a second passive device identical to the first device and over the plurality of dielectric layers, and dummy patterns in the plurality of dielectric layers and overlapped by the second passive device. The first performance data and the second performance data are de-embedded to determine an effect of metal patterns in the plurality of dielectric layers to overlying passive devices.

Spatial power-combining devices with reduced dimensions are disclosed. Spatial power-combining devices are provided that employ a hybrid structure including both a planar splitter/combiner and an antipodal antenna array. Planar splitters may be arranged to divide an input signal while antipodal antenna arrays may be arranged to combine amplified signals. In other applications, the order may be reversed such that antipodal antenna arrays are arranged to divide an input signal while a planar combiner is arranged to combine amplified signals. Advantages of such spatial power-combining devices include reduced size and weight while maintaining suitable performance for operation in desired frequency bands.

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.