An integrated device comprises a horn antenna with an antenna waveguide feed, a waveguide transition element comprising a first end connected to the antenna waveguide feed and second end, and an orthomode transducer comprising a common waveguide connected to the second end of the waveguide transition element and at least two separate waveguides. The orthomode transducer is adapted to couple at least two orthogonal linear polarized fields into the common waveguide of the orthomode transducer with the aid of the at least two separate waveguides of the orthomode transducer and/or vice versa. The horn antenna is preferably adapted to support at least two waveguide modes corresponding to the at least two orthogonal linear polarized fields. The integrated device is preferably manufactured in at least two separate blocks such that each part of the at least two piece assembly is constructed as external protrusions and/or holes and/or partial holes.

A radiating element includes at least two feeding guides and one horn common to at least two feeding guides and having an excitation interface, each feeding guide comprising a port guide and an excitation guide connected to the port guide by a port interface and connected to the common horn by the excitation interface, each excitation guide being flared in the direction from the port interface to the excitation interface, each excitation guide not having an axis of symmetry, the two feeding guides being disposed symmetrically relative to one another.

This application provides a feed apparatus, a dual-band microwave antenna, and a dual-band antenna device. The feed apparatus includes a low-frequency feed and a high-frequency feed. The high-frequency feed is embedded into the low-frequency feed. The low-frequency feed includes a plurality of low-frequency array elements arranged in an array. The high-frequency feed includes a plurality of high-frequency array elements arranged in an array. At least one high-frequency array element is embedded into the low-frequency array element, and the low-frequency array element and each high-frequency array element embedded into the low-frequency array element have a common waveguide wall.

An integrated device comprises a horn antenna with an antenna waveguide feed, a waveguide transition element comprising a first end connected to the antenna waveguide feed and second end, and an orthomode transducer comprising a common waveguide connected to the second end of the waveguide transition element and at least two separate waveguides. The orthomode transducer is adapted to couple at least two orthogonal linear polarized fields into the common waveguide of the orthomode transducer with the aid of the at least two separate waveguides of the orthomode transducer and/or vice versa. The horn antenna is preferably adapted to support at least two waveguide modes corresponding to the at least two orthogonal linear polarized fields. The integrated device is preferably manufactured in at least two separate blocks such that each part of the at least two piece assembly is constructed as external protrusions and/or holes and/or partial holes.

Disclosed is a dual polarized horn radiator, in particular for a cellular radio base station, having a first polarization and a second polarization that are fed separately via a first hollow waveguide and a second hollow waveguide. In a first aspect one of the hollow waveguides runs in the direction of beam to its opening into the horn radiator and in so doing has a cross-section that extends in projection onto the aperture plane partially within and partially outside the aperture opening of the horn radiator. In a second aspect the two hollow waveguides run in the direction of beam to their openings into the horn radiator, with at least one of the hollow waveguides having a transformation section by which its polarization in the aperture plane is rotated with respect to the other hollow waveguide before it opens into the horn radiator.

According to the present disclosure, an antenna apparatus which includes a hollow pillar shaped waveguide extending in a first direction and at least one ridge protruding from an inner circumferential surface of the waveguide and extending in the first direction, wherein the ridge has at least one recessed groove formed in the first direction; and an antenna apparatus which includes the waveguide, the ridge and the iris structure protruding from the inner circumferential surface of the waveguide along a plane intersecting the first direction, are provided.

According to the present disclosure, an antenna apparatus which includes a hollow pillar shaped waveguide extending in a first direction and at least one ridge protruding from an inner circumferential surface of the waveguide and extending in the first direction, wherein the ridge has at least one recessed groove formed in the first direction; and an antenna apparatus which includes the waveguide, the ridge and the iris structure protruding from the inner circumferential surface of the waveguide along a plane intersecting the first direction, are provided.

The disclosed apparatus may include (1) an antenna assembly defining an upper cavity with an aperture, the antenna assembly further defining a lower cavity coupled to the upper cavity via a channel along a linear edge of the antenna assembly, where the antenna assembly may include a reflective element within the lower cavity having a concave parabolic contour, and (2) an array assembly positioned in the aperture and including an array of passive elements. The reflective element may transform a divergent radio frequency (RF) beam directed toward the concave parabolic contour within the lower cavity into a collimated RF beam propagating within the lower cavity and into the upper cavity via the channel, and the array of passive elements may radiate a transmitted RF beam from the aperture in response to the collimated RF beam in the upper cavity. Various other apparatuses, methods, and systems are also disclosed.

The disclosed apparatus may include (1) an antenna assembly defining an upper cavity with an aperture, the antenna assembly further defining a lower cavity coupled to the upper cavity via a channel along a linear edge of the antenna assembly, where the antenna assembly may include a reflective element within the lower cavity having a concave parabolic contour, and (2) an array assembly positioned in the aperture and including an array of passive elements. The reflective element may transform a divergent radio frequency (RF) beam directed toward the concave parabolic contour within the lower cavity into a collimated RF beam propagating within the lower cavity and into the upper cavity via the channel, and the array of passive elements may radiate a transmitted RF beam from the aperture in response to the collimated RF beam in the upper cavity. Various other apparatuses, methods, and systems are also disclosed.

Some embodiments of the present disclosure discloses a 5G millimeter-wave novel dual-polarized horn antenna. The antenna includes an upper plate, a lower plate, a front plate, a rear plate and a cover plate, the cover plate is disposed on a rear end of the antenna, the front plate and the rear plate are disposed between the upper and lower plate, an excitation cavity structure is defined in the upper plate, the lower plate, the front plate, the rear plate and the cover plate, an excitation cavity with a rectangular cross section is formed in the cavity structure, the cross section of the excitation cavity is gradually reduced from right to left and then kept unchangeable, the left end of the excitation cavity is sealed through the cover plate, the upper plate, the lower plate, the front plate and the rear plate in the excitation cavity all include a curve ridge.