An antenna feeding network for a multi-radiator antenna, the antenna feeding network comprising at least two coaxial lines, wherein each coaxial line comprises an elongated central inner conductor and an elongated outer conductor surrounding the central inner conductor. At least one connector device is configured to interconnect at least a first inner conductor and a second inner conductor of the central inner conductors. The connector device comprises at least one engaging portion, each being configured to engage with at least one corresponding surface portion formed on the envelope surface of the first or second inner conductor. The envelope surface is furthermore provided with at least one recess provided adjacent at least one surface portion.

An angled coaxial cable adapter may include a housing portion structurally configured to include a first RF signal wave receiving portion and a second RF signal wave receiving portion and a conductive portion structurally configured to pass an RF signal through the first RF signal wave receiving portion and the second RF signal wave receiving portion. The first RF signal wave receiving portion may be configured to be disposed at an angle relative to the second RF signal wave receiving portion, and the conductive portion may be structurally configured to include a bend. The RF signal wave blocking portion may be structurally configured to block the first RF signal wave and the second RF signal wave from interfering with one another so as to reduce potential noise when a signal changes direction at the bend of the conductive element such that the adapter can provide an enhanced RF signal.

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 coaxial 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 coaxial 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 coaxial lines.

A connector device according to the present disclosure includes a first connector section and a second connector section. The first connector section includes a waveguide for transmitting a high-frequency signal. The second connector section includes a waveguide for transmitting a high-frequency signal, a yoke disposed to cover the waveguide, and a magnet forming a magnetic circuit with the yoke, and is couplable to the first connector section by the attractive force of the magnet. A communication system according to the present disclosure includes two communication devices and a connector device. The connector device has the above-described configuration and transmits a high-frequency signal between the two communication devices.

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.

A solution to the technical problem of improving device-to-device connection speeds includes the use of single-wire communication (SWC). Unlike the two differential wires required in transmission lines, SWC includes a transmission method using a single wire for data without requiring a return wire. The use of SWC has the potential to enable low loss channels of increasingly high bandwidth. The SWC improvements in bandwidth and frequency enable a significant reduction of power required for communication. SWC provides significant improvement in speed for each channel, so fewer wires may be used for each device-to-device connection. SWC also provides the ability to convey increased bandwidth and increased power over each wire, which further reduces the number of wires needed to provide power and communication.

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).

Aspects of the subject disclosure may include, for example, a system for determining a usage pattern, and sending instructions to a plurality of waveguide systems to transmit or receive electromagnetic waves along a surface of each of a plurality of wires according to the usage pattern. Other embodiments are disclosed.

A directional coupler operable at microwave and RF frequencies. Embodiments of directional coupler includes a main transmission line supporting transverse electromagnetic (TEM) or quasi-TEM wave mode propagation. A coupled transmission line supports TEM or quasi-TEM wave mode propagation. The coupled transmission line is adjacent to and oriented at an angle with respect to the main transmission line. A coupling hole is formed through conductive shielding between the main and coupled lines, the coupling hole formed at an intersection region between the main and coupled lines. The angle is nominally 60 degrees for optimal directivity and isolation.

An apparatus includes a filter. The filter includes a metal structure forming a cavity and includes a ceramic block, which is suspended in the cavity. The ceramic block has two removed portions, the removed portions removed from two opposing sides of the ceramic block. The ceramic block further has one or more slots that that span a region of ceramic between the two removed portions and connects chambers formed by the two regions with chambers formed by the one or more slots, wherein a combined structure of the ceramic block, cavity, and metal structure supports multiple fundamental TM modes and one fundamental TE mode. The filter comprises multiple coupling structures to couple radio frequency signals into and out of the filter. The apparatus may include multi-cavity filters including one and typically multiple ones of the filters.