Techniques for creating a low pass filter associated with a flux line are presented. A qubit device can comprise a first substrate and second substrate. A low pass filter, comprising at least one inductor and at least one capacitor can be formed, wherein respective components of or associated with the low pass filter can be formed on the first or second substrates, and wherein one or more bump bonds can extend between the substrates to connect respective components that are on respective substrates. The filter can receive an input signal via an input line and filter the signal to produce a filtered signal as output to a flux line that is in proximity to a coupler with SQUID loop and one or more flux-tunable qubits that are formed on one of the substrates. The filter can reduce electrical noise and Purcell decay associated with the flux line.

A phase shifter module arrangement comprises a phase shifter with a plurality of emitter connections and a central point connection. A matching network is provided. The matching network comprises a signal connection and a phase shifter connection. A separating device is provided which is electrically conductive and is arranged between the phase shifter and the matching network. The separating device has a first side on which the phase shifter is arranged and a second side on which the matching network is arranged. A connection opening connects the first side to the second side. The phase shifter connection of the matching network is connected electrically via the connection opening of the separating device to the central point connection of the phase shifter.

Provided is an example of a technology capable of accurately controlling impedance.

Provided is a substrate including a first through hole that penetrates a substrate from a first face to a second face of the substrate, and is electrically connected to a transmission line through which a signal is transmitted, a second through hole that is provided adjacent to the first through hole in plan view of the substrate, penetrates the substrate from the first face to the second face, and is electrically connected to a ground, and an adjustment unit that adjusts a distance between the first through hole and the second through hole in plan view of the substrate to adjust an impedance of a connection end of the first through hole with the transmission line.

An interface assembly includes a constraint layer formed from a material that provides a coefficient of thermal expansion match between first and second circuit board substrates. The constraint layer includes a waveguide cavity that extends between first and second opposing outer surface the constraint layer. The first and second circuit board substrates are respectively coupled to the first and second outer surfaces of the constraint layer via single ground connections. Portions of the first and second circuit board substrates are aligned with the waveguide cavity and positive connections are made between components of the first and second circuit boards through the waveguide cavity.

A system configured to increase a reliability of electrical connections in a device. The system including a lead configured to electrically connect a pad of at least one support structure to a pad of at least one electrical component. The lead includes an upper portion that includes a lower surface arranged on a lower surface thereof. The lower surface of the upper portion is arranged vertically above a first upper surface of a first pad connection portion; and the lower surface of the upper portion is arranged vertically above a second upper surface of the second pad connection portion. A process configured to increase a reliability of electrical connections in a device is also disclosed.

A method of improving electrical interconnections between two electrical is made available by providing a meta-material overlay in conjunction with the electrical interconnection. The meta-material overlay is designed to make the electrical signal propagating via the electrical interconnection to act as though the permittivity and permeability of the dielectric medium within which the electrical interconnection is formed are different than the real component permittivity and permeability of the dielectric medium surrounding the electrical interconnection. In some instances the permittivity and permeability resulting from the meta-material cause the signal to propagate as if the permittivity and permeability have negative values. Accordingly the method provides for electrical interconnections possessing enhanced control and stability of impedance, reduced noise, and reduced loss. Alternative embodiments of the meta-material overlay provide, the enhancements for conventional discrete wire bonds whilst also facilitating single integrated designs compatible with tape implementation.

A wiring substrate includes a substrate, a signal conductor, and a ground conductor. The substrate has a first surface and an opening provided in a first surface and being a mounting region for an electronic component. The signal conductor is on the first surface and extends in a first direction from the opening toward an outer edge of the substrate. The ground conductor is on the first surface and extends in the first direction, with the signal conductor being sandwiched between portions of the ground conductor. The signal conductor includes first, second and third sections in sequence in the first direction. The width of first section and the third section are wider than the second section. The ground conductor includes a protrusion extending toward the first section.

Embodiments of the present disclosure relate to a coupling component, a microwave device and an electronic device. The coupling component includes a first ground electrode, a first dielectric layer, a first transmission line, a second dielectric layer, a second ground electrode, a first substrate, a second transmission line, a second substrate and a third ground electrode which are sequentially stacked. Each of the first to third electrodes has a slot, and orthographic projections of the slots on the first dielectric layer overlap. An orthographic projection of a coupling end of the first transmission line on the first dielectric layer overlaps an orthographic projection of the slot of the second ground electrode on the first dielectric layer. An orthographic projection of a coupling end of the second transmission line on the first dielectric layer overlaps the orthographic projection of the slot of the second ground electrode.

A millimeter-wave active antenna unit and an interconnection structure between PCBs is provided. The interconnection structure between PCBs comprises a mainboard and an AIP antenna module. The mainboard is a first multilayer PCB on which a signal transmission line and a first pad electrically connected to the signal transmission line are provided. The AIP antenna module is a second multilayer PCB on which a second pad, an impedance matching transformation branch, an impedance line and a signal processing circuit are provided. The mainboard and the AIP antenna module are interconnected by directly welding multiple PCBs.

A circuit board is disclosed, including a circuit board body and at least one via apparatus provided on the circuit board body. The via apparatus includes a via (101) formed on the circuit board body, a via pad (201) surrounding the via and separately provided from the via, and an electrical conductor (301) electrically connecting the via pad (201) with the via (101).