A waveguide tube connecting member includes a first waveguide tube having a first waveguide path and a flange. The flange has a flange end surface extending from a first opening end of the first waveguide path toward an outer side in a tube radial direction, and a second flange outer peripheral surface which is a part of a first flange outer peripheral surface. The second flange outer peripheral surface is a surface formed in a shape in which a part of the flange has a cavity. An electric length from the first opening end of the flange end surface to the second flange outer peripheral surface along the tube radial direction is (2×N+1)/4 times a wavelength.

A reusable joint for a medical linac, a reusable CF choke flange for a medical linac, a linac and a method for forming a reusable joint for a medical linac are disclosed. The reusable joint comprises a CF choke flange, a CF cover flange and a gasket. The CF choke flange comprises a first waveguide aperture, a choke groove and a first CF groove comprising a first knife-edge, wherein the choke groove is disposed radially inwards from the first CF groove on the CF choke flange. The CF cover flange comprises a second waveguide aperture aligned with the first waveguide aperture and a second CF groove comprising a second knife-edge and aligned with the first CF groove. The gasket is disposed between and in contact with the first CF groove and the second CF groove.

A waveguide arrangement contains a first ridged waveguide and a second waveguide. The first ridged waveguide contains a first casing with a first cavity and a first ridge extending in the first cavity in the longitudinal direction. The first ridge is conductively connected to a wall of the first casing. The second waveguide contains a second casing with a second cavity. The first ridged waveguide overlaps the second waveguide in the longitudinal direction of the waveguide arrangement in a connecting section to produce a capacitive coupling between the first ridge and the second waveguide.

A radio frequency (RF) waveguide housing includes a metal-diamond base with a first surface and a second surface opposite the first surface. The metal-diamond base includes an opening through a thickness of the metal-diamond base, and the opening includes a first side on a side of the first surface of the metal-diamond base and a second side on a side of the second surface of the metal-diamond base. The RF waveguide housing also includes an insert to be inserted in the opening and affixed to the metal-diamond base. The insert defines an interior volume within the opening of the metal-diamond base and a shape of the insert at the first side of the opening is configured to match an end of an RF waveguide coupled to the RF waveguide housing.

A waveguide flange adapter includes a plate; an aperture positioned through the plate; and a plurality of holes arranged in a pattern in the plate and around the aperture. The plate is configured to operatively connect a first waveguide to a second waveguide such that the first waveguide and the second waveguide have a different pattern of holes on the waveguide flanges to one another. The pattern of the plurality of holes may be configured to align with connecting holes in each of the first waveguide and the second waveguide. At least some of the plurality of holes may extend through an entire thickness of the plate. The plate may include electrically-conductive material. The size and shape of the aperture may be complementary to a size and shape of each of the first waveguide and the second waveguide. At least some of the plurality of holes may be tapped or untapped.

A coupling assembly is provided. More specifically, the coupling assembly is configured to form a quick, preferably mechanical and electromagnetic, connection between two devices such as a radio and antenna. The coupling assembly has interchangeable portions can be easily adjusted or adapted to swap parts such as waveguides having different sizes and dimensions while maintaining a standard connection portion that can be used with the different sized and shaped parts, thereby reducing manufacturing costs and increasing the efficiency of field installations.

The present disclosure relates to a waveguide gasket arrangement (1, 1', 1") arranged for electrically sealing a waveguide interface (2) between a first waveguide end (3) and a second waveguide end (4). The waveguide gasket arrangement (1, 1', 1") comprises a carrier arrangement (5, 5', 5") where a carrier aperture (6; 6a, 6b) is formed in the mounted carrier arrangement (5, 5', 5"). The waveguide gasket arrangement (1, 1', 1") further comprises an electrically conducting flexible ribbon arrangement (7) that comprises at least one plurality of electrically conducting members (8a, 8b) forming a coherent common structure. The ribbon arrangement (7) is mounted to a carrier aperture edge (11; 11a, 11b) that circumvents the carrier aperture (6; 6a, 6b) such that for each plurality of electrically conducting members (8a, 8b), a first plurality of electrically conducting members (8a) is adapted to extend towards the first waveguide end (3) and a second plurality of electrically conducting members (8b) is adapted to extend towards the second waveguide end (4).

An example waveguide connector is for making a blind-mate electrical connection between a first waveguide and a second waveguide. The waveguide connector includes a male part connected to the first waveguide, where the first waveguide includes a first conductive channel, and a female part connected to the second waveguide, where the second waveguide includes a second conductive channel. The female part includes a receptacle into which the male part slides to create the blind-mate electrical connection between the first conductive channel and the second conductive channel. A self-alignment feature is on at least one of the male part or the female part. The self-alignment feature is configured to guide the male part into the receptacle while correcting for misalignment of the male part and the female part

A multi-layer signal filter includes at least three physical layers. Each layer has through going apertures arranged with an offset to apertures of at least one adjoining layer, each layer further has a filter channel opening for receiving signals to be filtered. The apertures are arranged along a perimeter outside the filter channel opening and the apertures are arranged with a central surface portion increasing the edge length of the aperture.

An antenna assembly for emitting microwaves comprises a dielectric hollow conductor element and a support element, wherein the hollow conductor element has an electrically conductive surface along a circumferential lateral face, the hollow conductor element has an electrically non-conductive emission face, and the hollow conductor element has a coupler receptacle. The support element contains a material having a modulus of elasticity of no less than 50 GPa. The support element surrounds the hollow conductor element at least along the lateral face. The hollow conductor element is fixed in the support element. The support element has an emission opening, and the emission face aligns with the emission opening. The hollow conductor element has a permittivity of no less than 8 at 2 GHz, the hollow conductor element containing a ceramic material, in particular aluminium oxide, zirconium oxide or titanium oxide.