An antenna has a predetermined operating frequency, corresponding to a predetermined wavelength, and the antenna includes: a conductive sectoral horn including one open end built into a floorplan; short-circuited radiating slots, built into the floorplan, on either side of the open end; and conductive louvres, arranged above the slots and the open end, and configured to be deployed mechanically in a continuous manner to modify a radiation pattern of the antenna. The antenna can be, for example, used in stations for testing electromagnetic fields.

An antenna includes a reflector and a waveguide assembly. The waveguide assembly includes a feed assembly and a support member that extends from behind the reflector to orient the feed assembly for direct illumination of the reflector. The waveguide assembly includes a first waveguide coupled to a first portion of a common waveguide, a second waveguide coupled to a second portion of the common waveguide, and a septum layer that includes a septum polarizer coupled between the common waveguide and the first and second waveguides.

An end-fire antenna for wideband low form factor applications includes a first metal layer, a second metal layer, and a dielectric layer disposed between the first and second metal layers. An open cavity formed in the dielectric layer that is filled with air, the cavity defined by a pair of sidewalls that extend from an aperture of the cavity to a rear wall of the cavity, where the depth of the aperture is defined between the aperture and the rear wall. The cavity is formed by selecting the width of the aperture of the cavity and the depth of the cavity such that the antenna achieves the same gain during operation irrespective of a variation in the thickness of the antenna.

An end-fire antenna for wideband low form factor applications includes a first metal layer, a second metal layer, and a dielectric layer disposed between the first and second metal layers. An open cavity formed in the dielectric layer that is filled with air, the cavity defined by a pair of sidewalls that extend from an aperture of the cavity to a rear wall of the cavity, where the depth of the aperture is defined between the aperture and the rear wall. The cavity is formed by selecting the width of the aperture of the cavity and the depth of the cavity such that the antenna achieves the same gain during operation irrespective of a variation in the thickness of the antenna.

A radar measuring device for level and/or limit level monitoring is provided, including a radar signal source configured to generate and/or transmit a radar signal, an antenna arrangement configured to direct the radar signal, a plano-convex lens with a plane side configured to face a medium and to focus the radar signal, the radar measuring device being configured such that the plane side rests at least partially on a container surface and such that a contact surface is formed between the plano-convex lens and the container.

A radar measuring device for level and/or limit level monitoring is provided, including a radar signal source configured to generate and/or transmit a radar signal, an antenna arrangement configured to direct the radar signal, a plano-convex lens with a plane side configured to face a medium and to focus the radar signal, the radar measuring device being configured such that the plane side rests at least partially on a container surface and such that a contact surface is formed between the plano-convex lens and the container.

A method for achieving multiple beam radiation vertical orthogonal field coverage by means of multiple feed-in dish antenna, comprising using a total metallic disc and plural feed-in antenna components, wherein it is possible to generate multiple sets of radiation beams by applying multiple sets of feed-in antenna components, and the coverage ranges created by different radiation beams may uniformly distribute there between so as to generate multiple communication service coverage areas. Moreover, since the field formed by the reflection of the total metallic disc is characterized in vertical orthogonality, advantages such as effectively increased coverage, improved energy utilization and radiation beam switches or the like can be provided.

A method for achieving multiple beam radiation vertical orthogonal field coverage by means of multiple feed-in dish antenna, comprising using a total metallic disc and plural feed-in antenna components, wherein it is possible to generate multiple sets of radiation beams by applying multiple sets of feed-in antenna components, and the coverage ranges created by different radiation beams may uniformly distribute there between so as to generate multiple communication service coverage areas. Moreover, since the field formed by the reflection of the total metallic disc is characterized in vertical orthogonality, advantages such as effectively increased coverage, improved energy utilization and radiation beam switches or the like can be provided.

A Cassegrain-type metamaterial antenna, includes: a metamaterial main reflector having a central through-hole, a feed source disposed in the central through-hole, and a sub-reflector disposed in front of the feed source, where an electromagnetic wave radiated by the feed source is emerged in a form of a plane wave after being reflected by the sub-reflector and the metamaterial main reflector in sequence; the metamaterial main reflector includes: a first core layer and a first reflection layer disposed on a rear surface of the first core layer, where the first core layer includes at least one first core layer lamella, and the first core layer lamella includes: a first base material and multiple first conductive geometric structures disposed on the first base material; and a far focus of the sub-reflector coincides with a phase center of the feed source. A paraboloid is replaced with a lamellar metamaterial main reflector.

Aspects of the subject disclosure may include, for example, a system for receiving first electromagnetic waves via a transmission medium without utilizing an electrical return path, and inducing second electromagnetic waves at an interface of the transmission medium without the electrical return path. In an embodiment, the first and second electromagnetic waves have a non-optical frequency range. Other embodiments are disclosed.