An antenna horn includes a waveguide having an open end and an end allowing access to transmitted signals, the widest opposite walls constituting a first pair of walls, two first ridges inside the waveguide, in the middle and over the whole length of the walls of the first pair of walls, a flat central wall connecting the walls of the second pair of walls at their midpoints at the level of the accesses, stopping in the direction of the open end so as to polarize signals transmitted by the two accesses according to orthogonal circular polarizations, and forming two ridges in the middle of the walls of the second pair of walls from the side of the open end, and with an antenna, an item of radio communication equipment and a method using the horn.

Some embodiments of the present disclosure provide a miniaturized horn antenna suitable for ultra-wideband measurement, and relates to the technical field of horn antennas. The antenna includes a horn antenna body, a coaxial connector and a mounting base, wherein the horn antenna body includes an upper plate, a lower plate, a side plate and a cover plate which are provided with ridges, mounting seats being formed on front and rear sides of an upper half cavity and a lower half cavity, several threaded holes being provided in the mounting seats separately, an upper mounting groove and a lower mounting groove being formed between the mounting seats of the upper plate and between the mounting seats of the lower plate respectively, the upper mounting groove and the lower mounting groove jointly forming a mounting space of a protrusion part at a left end of the cover plate.

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.

Some embodiments of the present disclosure provide a miniaturized horn antenna suitable for ultra-wideband measurement, and relates to the technical field of horn antennas. The antenna includes a horn antenna body, a coaxial connector and a mounting base, wherein the horn antenna body includes an upper plate, a lower plate, a side plate and a cover plate which are provided with ridges, mounting seats being formed on front and rear sides of an upper half cavity and a lower half cavity, several threaded holes being provided in the mounting seats separately, an upper mounting groove and a lower mounting groove being formed between the mounting seats of the upper plate and between the mounting seats of the lower plate respectively, the upper mounting groove and the lower mounting groove jointly forming a mounting space of a protrusion part at a left end of the cover plate.

An antenna horn includes a waveguide having an open end and an end allowing access to transmitted signals, the widest opposite walls constituting a first pair of walls, two first ridges inside the waveguide, in the middle and over the whole length of the walls of the first pair of walls, a flat central wall connecting the walls of the second pair of walls at their midpoints at the level of the accesses, stopping in the direction of the open end so as to polarize signals transmitted by the two accesses according to orthogonal circular polarizations, and forming two ridges in the middle of the walls of the second pair of walls from the side of the open end, and with an antenna, an item of radio communication equipment and a method using the horn.

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.

A sensor has an antenna. The antenna includes a radiation source and a wave guide. The radiation source is formed on a substrate. The wave guide internally propagates electromagnetic waves radiated from the radiation source and radiates the electromagnetic waves as a beam. The wave guide has a radiation-side opening in which a first direction and a second direction are orthogonal to each other, and the second direction is longer than the first direction. In a cross-sectional shape of the beam, perpendicular to a radiation direction of the beam radiated from the wave guide, a first direction and a second direction are orthogonal to each other, and the second direction is narrower than the first direction.

An epsilon-and-mu-near-zero (EMNZ) metamaterial. The EMNZ metamaterial includes a waveguide. A length l of the waveguide satisfies a length condition according to l0.1, where is an operating wavelength of the EMNZ metamaterial. The EMNZ metamaterial further includes a magneto-dielectric material deposited on a lower wall of the waveguide. The waveguide includes an impedance surface placed on the magneto-dielectric material.

A horn antenna configured for use in a radio frequency (RF) anechoic test chamber is provided. The horn antenna includes one or more conductive radiating elements. The horn antenna further includes an electromagnetic interference (EMI) suppressing material covering at least a portion of a surface of the one or more conductive radiating elements such that the EMI suppressing material at least partially suppresses a surface current associated with the surface of the one or more conductive radiating elements during a test operation.

A method of manufacturing an integrated radio frequency (RF) module, comprising structurally forming at least one RF waveguide and at least one RF radiator of a metalized ceramic material. The RF waveguide(s) and the RF radiator(s) are connected and operatively coupled with each other. Each of the RF radiator(s) comprises a metalized outer wall and at least one metalized axial ridge extending along an inner surface of the outer wall. The method further comprises sintering the metalized ceramic material to create a monolithic structure comprising the RF waveguide and RF radiator, and operatively coupling RF circuitry to the RF waveguide(s).