A magic tee microwave junction comprising: an E-plane tee junction includes a difference arm along a first axis (Ox) in a reference plane (xOz) and two collinear arms that are symmetric about the reference plane, an H-plane tee junction comprising a sum arm along an axis (O′z′) orthogonal to the first axis in the reference plane and two collinear arms that are symmetric about the reference plane, two first waveguides that are symmetric about the reference plane, connected to the ends of the collinear arms of the junctions, two waveguides that are symmetric about the reference plane and connected to the first waveguides. A power divider, to a beamforming network and to an additive manufacturing production method is also provided.

An RF applicator has an open-ended waveguide having an aperture and a dielectric cone extending through the aperture and is electrically connected to an RF source that is configured to generate RF energy pulses. A top fin is mounted to an inner top surface of the waveguide and comprises a conductive material, is electrically connected to the RF source, and has dimensions configured to optimize a bandwidth that the RF applicator applies to tissue. A bottom fin is mounted to an inner bottom surface of the waveguide and comprises a conductive material electrically isolated from the RF source, with dimensions configured to optimize a bandwidth that the RF applicator applies to tissue. A dielectric cone is inserted into the waveguide. A filler material between inner surfaces of the waveguide and the solid dielectric cone can fill gaps and has a dielectric constant similar to the dielectric cone.

A hybrid-harmonic waveguide filter includes transformer sections at end terminals of the harmonic waveguide filter, a number of corrugations along the length of the waveguide filter, and multiple ridge interconnects that couple the corrugations. By shaping the identical-cross-section ridge interconnects via single-pass wire electrical-discharge machining (EDM), low manufacturing cost is achieved along with continuous broadband rejection of TEn0 modes and an extremely high-power handling capability is observed.

An arrangement for communication satellites including a payload bay. The arrangement includes an assembly of waveguides, waveguide fixation interfaces for fixing the waveguides to electronic equipment and/or components and a mechanical structure including a plurality of links interconnecting at least some of the waveguides to ensure the stability of the waveguide assembly. The arrangement further includes at least one heat pipe that is arranged to heat or cool one or more of the waveguides. The arrangement is formed in a single piece by 3D printing.

The present invention includes a method of creating high Q empty substrate integrated waveguide devices and/or system with low loss, mechanically and thermally stabilized in photodefinable glass ceramic substrate. The photodefinable glass ceramic process enables high performance, high quality, and/or low-cost structures. Compact low loss RF empty substrate integrated waveguide devices are a cornerstone technological requirement for RF systems, in particular, for portable systems.

A method of manufacturing a device is provided. The method includes forming a first cavity in a first substrate with the first cavity having a first depth. A second cavity is formed in a second substrate with the second cavity having a second depth. The first cavity and the second cavity are aligned with each other. The first substrate is affixed to the second substrate to form a waveguide substrate having a hollow waveguide with a first dimension substantially equal to the first depth plus the second depth. A conductive layer is formed on the sidewalls of the hollow waveguide. The waveguide substrate is placed over a packaged semiconductor device, the hollow waveguide aligned with a launcher of the packaged semiconductor device.

A vehicle having a communication system is disclosed. The system includes two electrical couplings, coupled by way of a rotary joint having a bearing waveguide. Each electrical coupling includes an interface waveguide configured to couple to external signals. Each electrical coupling also includes a waveguide section configured to propagate electromagnetic signals between the interface waveguide and the bearing waveguide of the rotary joint. Additionally, the rotary joint is configured to allow one electrical coupling to rotate with respect to the other electrical coupling. An axis of rotation of the rotary joint is defined by a center of a portion of the waveguides. Yet further, the rotary joint allows electromagnetic energy to propagate between the waveguides of the electrical couplings.

A filter that makes it easy to adjust a center frequency of a passband is implemented. The filter (1) includes a post-wall waveguide (11) functioning as a plurality of resonators (11a to 11e) that are electromagnetically coupled to each other and cavities (12a to 12e) stacked on the post-wall waveguide (11). The cavities (12a to 12e) are electromagnetically coupled with resonators (11a to 11e) via coupling windows (112a to 112e) formed in a broad wall (first broad wall (112)) of the post-wall waveguide (11).

Provided herein are various examples of separable waveguide couplers. In one example, a collar element is provided to surround a member comprising a faying surface, a waveguide conduit, and alignment protrusions arranged radially about a perimeter of the faying surface, where the collar element is configured to accept insertion of a mating member comprising a mating faying surface and a mating waveguide conduit. A ball detent assembly is provided having a spring element that retains ball elements in holes formed through the collar element. The waveguide conduit and the mating waveguide conduit are configured to be aligned radially by at least engagement of the alignment protrusions with alignment channels in the mating member and restrained axially by at least engagement of the ball elements with mating divots in the mating member.

A method for producing a waveguide in a multilayer substrate involves producing at least one cutout corresponding to a lateral course of the waveguide in a surface of a first layer arrangement comprising one or a plurality of layers. A metallization is produced on surfaces of the cutout. A second layer arrangement comprising one or a plurality of layers is applied on the first layer arrangement. The second layer arrangement comprises, on a surface thereof, a metallization which, after the second layer arrangement has been applied on the first layer arrangement, is arranged above the cutout and together with the metallization on the surfaces of the cutout forms the waveguide.