Composite substrate for a waveguide for RF signals having a signal frequency, wherein said composite substrate comprises at least a first layer of dielectric material and a second layer of dielectric material, and at least one conductor layer of an electrically conductive material arranged between said first layer and said second layer, wherein a layer thickness of said at least one conductor layer is smaller than about 120 percent of a skin depth of said RF signals within said electrically conductive material of said conductor layer.

The present invention reduces the risk of damaging a waveguide made of a brittle material. A transmission line (1) includes: a first waveguide (11) which is made of a brittle material; a second waveguide (21); and a bonding layer (31) by which the first waveguide (11) and the second waveguide (21) are bonded and which is electrically conductive. At least part of the bonding layer (31) is made of an electrically conductive adhesive, the at least part of the bonding layer (31) being in contact with the first waveguide (11).

To provide a multilayer substrate for transmitting/receiving a high frequency signal, the substrate having a simplified configuration and excellent high frequency characteristics. This disclosure pertains to a multilayer substrate provided with: a plurality of dielectric layers laminated together with ground layers interposed therebetween; and a signal line for inputting and outputting a signal, the signal line being formed on the surface of the dielectric layer. The plurality of ground layers include an input-side ground layer part formed in the region on the signal-input side of the signal line, an output-side ground layer part formed in the region on the signal-output side of the signal line, and an intermediate ground layer part formed in the region between the input-side ground layer part and the output-side ground layer part. The input-side ground layer part and the output-side ground layer part each have fewer layers than the intermediate ground layer part.

A technique relates to a structure. A first surface includes an inductive element of a resonator. A second surface includes a first portion of a capacitive element of the resonator and at least one qubit. A second portion of the capacitive element of the resonator is on the first surface.

A film transmission line includes a dielectric layer including at least one of a liquid crystal polymer (LCP) structure or a cyclo olefin polymer (COP) structure, and an electrode line on the dielectric layer. A signal loss level (S21) defined of the film transmission line is 1.5 dB or more at a frequency in a range from 20 GHz to 30 GHz. The film transmission line may be applied to a high frequency thin film antenna and an image display device.

A transmission line structure includes a first transmission line having a first and a second extending line segments and a first and a second line segments extending along a first direction and a third line segment extending along a second direction, and a second transmission line having a third and a fourth extending line segments, a fourth and a fifth line segments extending along the first direction and a sixth line segment extending along the second direction. The first and the second extending line segment are connected to ends of the first and the second line segment. The third line segment is connected to sides of the first and the second line segment. The third and the fourth extending line segment are connected to ends of the fourth the fifth line segment. The sixth line segment is connected to sides of the fourth and the fifth line segment.

A semiconductor device includes a first transmission line and a second transmission line. The semiconductor device further includes a high-k dielectric material between the first transmission line and the second transmission line. The semiconductor device further includes a dielectric material directly contacting at least one of the first transmission line or the second transmission line, wherein the dielectric material has a different dielectric constant from the high-k dielectric material.

A Printed Circuit Board (PCB) and methods for manufacturing the PCB board are provided. The PCB includes a Radio Frequency (RF) signal transition at a RF signal pad. Multiple conductive layers other than a conductive signal layer of the PCB and conductive portions of the conductive signal layer not in electrical contact with a RF signal transmission trace have common ground connections forming a ground cage structure within the PCB around the RF signal pad and RF the signal transmission trace.

A transmission line member includes a base body extending along a transmission direction of a high-frequency signal, and a first transmission line, a second transmission line, and a third transmission line. The base body includes a first portion including the first transmission line, a second portion including the second transmission line, and a third portion including the third transmission line. The second portion is connected between the first and third portions. A thickness of the second portion is smaller than a thickness of the first and third portions. The second transmission line includes only a conductor pattern extending more in the transmission direction than in a direction of the thickness.

A transmission line substrate includes a line portion and a connecting portion. The transmission line substrate includes a base material, a first ground conductor, a second ground conductor, a signal line, an external electrode, a second interlayer connection conductor. In the line portion, a transmission line having a strip line structure including the signal line, the first ground conductor, and the second ground conductor is provided. In the connecting portion, the signal line and the external electrode face each other in a stacking direction, without including therebetween an interlayer connection conductor. The second interlayer connection conductor surrounds a facing portion in which the signal line and the external electrode face each other in the Z-axis direction.