In accordance with one or more embodiments, a coupling system includes a plurality of dielectric couplers configured to generate, responsive to first electromagnetic waves received via a hollow waveguide, second electromagnetic waves along a surface of a transmission medium, wherein the plurality of dielectric couplers each have an end at differing azimuthal orientations relative to the transmission medium and wherein the second electromagnetic waves propagate along the surface of the transmission medium without requiring an electrical return path. A controller is configured to control a generation of the first electromagnetic waves in accordance with a first set of phases, wherein the second electromagnetic waves generated by the plurality of dielectric couplers combine on the surface of the transmission medium to propagate via a first selected wave mode.

An antenna feeding network for a multi radiator antenna is provided. The antenna feeding network comprises at least one coaxial line. Each coaxial line comprises a central inner conductor and an elongated outer conductor surrounding the central inner conductor, wherein at least one of the outer conductors of the coaxial lines is provided with an opening, wherein the antenna feeding network further comprises at least one nonconductive holding element configured to be placed in the opening. The holding element is configured to hold at least one of the inner conductors in position. The invention further relates to a multi radiator antenna comprising such an antenna feeding network, and to a method for providing an electrical connection in such an antenna feeding network.

A transmission line arrangement having a first end and a second end, the transmission line arrangement being configured to transmit a signal between the first end and the second end, the transmission line arrangement comprising a signal conductor extending between the first end and the second end of the transmission line arrangement, a first conducting sheet and a second conducting sheet positioned on two opposing sides of the signal conductor, an insulating material separating the first and second conducting sheets from the signal conductor and a plurality of pieces of conducting material extending between the first and second conducting sheets and arranged at different positions between the first and second ends of the transmission line arrangement, wherein the pieces of conducting material and the conducting sheets are arranged to substantially surround the signal conductor for at least part of its length between the first and second ends of the transmission line arrangement.

The technology described herein is directed towards microwave attenuators, and more particularly to a cryogenic microwave attenuator device for quantum technologies. In some embodiments, a device can comprise a cryogenic microwave attenuator device. The cryogenic microwave attenuator device can comprise: a housing component and a microwave attenuator chip, wherein the housing component can have thermal conductivity of about at least 0.1 Watts per meter-Kelvin at 1 degree Kelvin. The cryogenic microwave attenuator device can also comprise a microwave connector comprising a signal conductor that is direct wire coupled to the microwave attenuator chip.

An antenna feeding network for a multi-radiator base station antenna and an antenna arrangement comprising such a feeding network is provided. The feeding network comprises substantially air filled feeding lines and a coaxial connector for an antenna feeder cable, the connector being connected to at least one of the coaxial lines. The substantially air filled feeding lines each have a central inner conductor and an elongated outer conductor surrounding the central inner conductor. The coaxial connector comprises a body having an attachment portion, the attachment portion being attached to, and arranged in abutment with, a portion of at least one outer conductor such that the body connects electrically and mechanically with the outer conductors of the feeding lines.

The present invention relates to a connector (1), in particular for connecting an optical fiber (3) and an electrical conductor, comprising a printed circuit board (5); at least one electrical contact (7) which in each case has at least one internal conductor contact (11) and one external conductor contact (9); at least one electrical conductor (13) which has at least one internal conductor (15), one external conductor (17) and also one dielectric (19); wherein the electrical conductor (13) is connected, at a first end (21), to the electrical contact (7), and wherein the electrical conductor (13) is connected, at a second end (23), to an electrical component (25) which is arranged on the printed circuit board (5).

A radio frequency (RF) power monitoring device includes an RF sensor to monitor RF power transferred to a target load and an impedance of the target load and a transmission line to electrically connect the RF sensor to the target load and to transfer the RF power to the target load. A phase (z) of the impedance of the target load is adjusted to satisfy a range of 30+180*n<z<30+180*n (where n=2, 1, 0, 1, or 2).

Aspects of the subject disclosure may include, receiving, by a waveguide system, a communication signal that conveys data; transmitting, via a coupler of the waveguide system, electromagnetic waves, where the electromagnetic waves propagate along a transmission medium without requiring an electrical return path, and where the electromagnetic waves convey the data; and mitigating, by the waveguide system, interference to the electromagnetic waves associated with residual electromagnetic waves propagating along the transmission medium. Other embodiments are disclosed.

An apparatus includes an electrical connector. The electrical connector is configured to electrically couple a signal transmission line to another signal transmission line. The electrical connector includes a first electrical conductor and a second electrical conductor. The first electrical conductor is disposed around a center axis. The first electrical conductor is disposed azimuthally symmetric around the center axis. The second electrical conductor is disposed around the center axis and around the first electrical conductor. The second electrical conductor is disposed azimuthally symmetric around the center axis. Faces on opposing ends of the electrical connector along the center axis are configured to mate the signal transmission line and the second electrical conductor in a first plane and the other signal transmission line and the second electrical conductor in a second plane.

An antenna feeding network for a multi-radiator antenna. The feeding network comprises at least one substantially air filled coaxial line, each comprising a central inner conductor, an elongated outer conductor surrounding the central inner conductor and an elongated rail element slidably movably arranged inside the outer conductor. The rail element is longitudinally movable in relation to at least the outer conductor.