A waveguide filter having a core including an external face and internal faces defining a channel for filtering and guiding the waves. The channel includes several slots, each having a first and a second face. The first face is inclined in relation to the second face. A method for manufacturing the waveguide filter.

A waveguide arrangement for transmitting microwaves, and for measuring a limit level or a filling level, is provided, the waveguide arrangement for transmitting microwaves including a waveguide tube having a rectangular or elliptical inner cavity and an outer wall; and a jacket, an inner wall of which corresponds at least in sections with a shape of the outer wall of the waveguide tube.

A super-broadband waveguide feed network includes multiple receive (RX) full reject waveguide filters and multiple RX reject clone waveguide filters disposed in a clone carousel about an aperture port and configured to reject RX frequencies, and a branch line coupler configured to couple the multiple RX full reject waveguide filters and RX reject clone waveguide filters to other components of a waveguide feed network. The super-broadband waveguide feed includes an RX polarizer configured to couple to an end of the aperture port. The super-broadband waveguide feed is configured to be fabricated in one to three pieces composed of a single split plane on the zero-current region, and the super-broadband waveguide feed is circularly polarized.

Waveguides and methods for manufacturing a waveguide that include forming a first channel in a first layer of dielectric material, the first channel comprising one or more walls; forming a second channel in a second layer of dielectric material, the second channel comprising one or more walls; depositing electrically conductive material on the one or more walls of the first channel; depositing electrically conductive material on the one or more walls of the second channel; arranging the first layer adjacent to the second layer to form a stack with the first channel axially aligned with and facing the second channel; and heating the stack so that the conductive material on the one or more walls of the first channel and the conductive material on the one or more walls of the second channel connect to form the waveguide.

Waveguide device (1) for guiding a radio frequency signal at a given frequency f, the device (1) including: a core (3) manufactured by additive manufacturing and including side walls with inner and outer surfaces (7, 8), the inner surfaces (7) delimiting a waveguide channel (2), wherein a cross-section of the channel (2) has two straight sides joined together by two half-portions, at least one of the two half-portions being rounded or formed of at least two straight segments the cross-section having a maximum length (a) and a maximum width (b), the ratio between the maximum length (a)/maximum width (b) being between 2.05 and 3.5, preferably between 2.05 and 2.4.

A waveguide structure and a method of manufacturing the same, and an electronic device are provided. The electronic device includes a control module, an antenna module and a waveguide structure connected between the control module and the antenna module. The waveguide structure includes an insulating carrier component and a conductive metal component. The insulating carrier component includes a first insulating carrier and a second insulating carrier matching with the first insulating carrier. The first insulating carrier includes a first groove, and the second insulating carrier includes a second groove in communication with the first groove. The conductive metal component includes a first conductive body accommodated in the first groove of the first insulating carrier and a second conductive body accommodated in the second groove of the second insulating carrier, and the conductive metal component includes a penetrating channel passing therethrough.

A radar sensor having at least one high-frequency component and at least one waveguide structure in the form of a plastic body provided with an electrically conductive surface layer. The radar sensor has at least one further plastic body provided with an electrically conductive surface layer, and the plastic bodies with their conductive surface layers are thermally bonded to one another.

A method for manufacturing a circuit board structure with a waveguide is provided. The method includes: providing a plate including a top wall and sidewalls disposed on the top wall, an opening being defined between ends of two adjacent sidewalls away from the top wall; forming a conductive layer on the plate to obtain a conductive plate; providing a circuit board, the circuit board comprising an outer circuit layer; mounting the conductive plate on the outer circuit layer, causing the outer circuit layer to be disposed on the opening. The two adjacent sidewalls, the top wall between the two adjacent sidewalls, and the circuit board between the two adjacent sidewalls cooperatively constitutes a tube body of the waveguide, and the conductive layer and the outer circuit layer on an inner surface of the tube body cooperatively constitute a shielding of the waveguide.

A waveguide arrangement for guiding electromagnetic waves in a cavity surrounded by conductive material is proposed, wherein the waveguide arrangement comprises a printed circuit board material having an electrically conductive, plate-shaped back, a substrate and a conductive layer arranged on a side of the substrate facing away from the back. According to the invention, it is provided that the back has a surface structure, preferably formed by at least one recess, by which the waveguiding cavity is at least partially directly bounded; and/or that the cavity is formed in split-block technology by joining the printed circuit board material as split-block bottom part with a corresponding cover as split-block top part.

An apparatus includes a tube including an inner surface, an inner diameter, and a length. The apparatus also includes a coil spring. The coil spring includes an outer surface, an outer diameter, and a plurality of coil elements arranged along a length of the coil spring. The coil spring can be positioned within the tube and the outer diameter of the coil spring can be less than the inner diameter of the tube. The coil spring can form a waveguide. Related methods of manufacture and systems are also described herein.