A directional coupler includes: a hollow coaxial line including a central conductor forming a main line and an outer conductor surrounding the central conductor and having an opening formed therein; a dielectric substrate covering the opening and provided with film-shaped ground conductors, wherein a film-shaped ground conductor covers a rear surface of the dielectric substrate facing the central conductor via the opening and a film-shaped ground conductor covers a front surface of the dielectric substrate, respectively, and are grounded; and a coupling line provided on the rear surface of the dielectric substrate in a region surrounded by the ground conductor formed on the rear surface and serving as an auxiliary line, wherein the ground conductor formed on the front surface is provided with a conductor-removed portion in which a portion of a conductor film in a region facing the coupling line via the dielectric substrate is removed.

A coupler, in particular a resistive coupler, wherein all ports are at least partially or completely arranged in or at a connector. The coupler comprises resistors which are adapted to sum and/or divide the incoming and/or outgoing signal. The resistors are arranged at or in the connector. A sum port and/or at least two dividing ports are arranged on a substrate.

A radar system includes a transmit section to emit a transmit signal. A chip-based front-end portion of the transmit section increases a frequency of an input signal to produce an intermediate signal and amplifies signal strength of the intermediate signal to produce the transmit signal. The frequency of the input signal is in a range of 76 gigahertz (GHz) to 80 GHz. The radar system also includes a receive section to receive a reflected signal resulting from reflection of the transmit signal by an object.

A power coupler includes an input port, first and second output ports and an antenna element that is electrically coupled between the first output port and the second output port or that is electrically coupled to an isolation port of the power coupler. The power coupler is configured to split a radio frequency signal incident at the input port and/or to combine radio signals incident at the respective first and second output ports.

Power combiner/divider includes a transmission line (TL) resonator having an inner conductor, an outer conductor that surrounds the inner conductor, and a cavity between the inner conductor and the outer conductor. The inner conductor and the outer conductor are electrically connected at a proximal end of the TL resonator. The power combiner/divider also includes coupling elements extending through respective openings of the outer conductor and into the cavity. The power combiner/divider also includes a capacitive element connected to at least one of the inner conductor or the outer conductor. The capacitive element capacitively couples the inner conductor and the outer conductor at a distal end of the TL resonator.

Wideband coaxial low loss signal couplers use an electro-magnetic loop placed perpendicularly in a mantle hole of the external wall of the coaxial airline. The signal coupling factor increases with frequency thus favoring detection of harmonic components generated by the nonlinearly operated RF transistors. In order to adapt also to various power levels and associated harmonic receiver sensitivity the coupling factor can be adjusted either by controlling the penetration of the loop inside the airline cavity or by rotating the loop around its vertical axis.

There is provided a multilayer directional coupler formed in a wireless communications device formed by stacking a plurality of substrates, comprising a first conductive pattern formed on a first substrate among the plurality of substrates; and a second conductive pattern formed on a second substrate stacked on one surface of the first substrate and having one or more conductive lines overlapping the first conductive pattern when viewed in a plane direction.

A combiner/divider includes a transition waveguide interposed between a plurality of input/output waveguides and an output/input waveguide. The input/output waveguides are preferably distributed in a radial sector extending in the E-plane of the input/output waveguides. The input/output waveguides extend from inner nodes disposed proximate to and spaced from a sector center to outer nodes disposed along an arc of the sector. At least some of the input/output waveguides taper in size from the inner nodes to the outer nodes. Walls between adjacent input/output waveguides also may taper in width between the inner nodes and the outer nodes. The output/input waveguide has an inner port facing and spaced from the inner nodes of the input/output waveguides. A transition waveguide extends between the input/output waveguides and the output/input waveguide and has side walls extending along the radii of the sector for communicatively coupling the output/input waveguide with input/output waveguides.

The invention relates to a high frequency amplifier unit comprising several amplifier modules to amplify high frequency input signals into high frequency output signals and a coaxial combiner having an outer conductor and an inner conductor arranged coaxially to this to combine the high frequency output signals of the amplifier modules, wherein the amplifier modules are arranged on the outside of the outer conductor of the coaxial combiner and the amplifier modules are connected to the coaxial inner conductor of the coaxial combiner to transmit the high frequency output signals to the coaxial combiner. The invention additionally relates to an amplifier system.

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.