A front end of a radar system is provided with a first front end apparatus and a second front end apparatus. A first transmit planar component and a first receive planar component in the first front end apparatus are arranged to be perpendicular to one another. A second transmit planar component and a second receive planar component in the second front end apparatus are arranged to be perpendicular to one another. A linear array of antennas is located along a second end of each planar component. Polarization of a first set of waves transmitted from the linear array of antennas of the first transmit planar component and polarization of a second set of waves transmitted from the linear array of antennas of the second transmit planar component are perpendicular to one another.

Disclosed is an antenna having a plurality of radiators disposed in a ring or arc around a Luneburg lens. Each of the radiators (e.g., flared-notch radiators) has a center radiating axis that intersects with the center of the Luneburg lens. Each of the radiators radiate into the Luneburg lens such that the Luneburg lens substantially planarizes the beam emitted by each radiator (on transmit) and focuses an incoming wavefront into the radiator (on receiver). This not only enables having numerous well-controlled individual beams, it also allows for combining radiators to create well-defined sector beams with minimal sidelobes and fast rolloff.

The present invention provides an antenna device that has a radiation pattern whose peak direction is independent of a frequency of an electromagnetic wave emitted. The antenna device includes: a ground layer (11) made of an electric conductor; a plurality of array antennas (22) provided in a layer above the ground layer (11); and a Rotman lens (32) provided in a layer below the ground layer (11). Each array antenna (22i) includes: a power feed line (23Li) at a center of which a feedpoint (23Pi) is located; and a plurality of antenna elements (241i through 248i and 251i through 258i) connected to the power feed line (23Li), and has a point symmetric shape with respect to the feedpoint (23Pi) as a center of symmetry. Each feedpoint (23Pi) is coupled to any one output port (322i) of the Rotman lens (32) via a slot (111i) provided in the ground layer (11).

A feeding device is disclosed. The feeding device includes a body and at least one first port, the body includes at least one first contour port, and each of the at least one first contour port corresponds to one of the at least one first port; and the first contour port includes at least two sub-ports, and the at least two sub-ports of the first contour port are connected, by using at least one power splitter, to the first port corresponding to the first contour port. In the foregoing implementation solution, the first contour port is divided into several sub-ports, and the first port and the several sub-ports are connected by using the at least one power splitter.

The disclosed technology includes device, systems, techniques, and methods for mm-wave energy harvesting utilizing a Rotman-Lens-based rectenna system. An energy harvester system can include one or more antenna, a Rotman Lens having a beam port side and an antenna side in electrical communication with the one or more antenna, and a rectifier network in electrical communication with the beam port side of the Rotman Lens. The energy harvester system can also include a power combining network in electrical communication with the rectifier network and having an output. The rectifier network can include a plurality of rectifiers connected to the beam port side of the Rotman Lens. Further, each of the plurality of rectifiers can include a rectifying diode. The power combining network can include a plurality of bypass diodes.

A lens array antenna system that includes a plurality of lens modules, each consisting of an RF lens and a plurality of feeds forming a linear feed region or feed array. Multiple linear feed regions supporting different frequency bands may be used. The lenses and array of feeds jointly rotate and are slidably connected to allow the location of the linear feed region relative to the focal locus of the lens to be changed by an actuator and controller to allow any two focal points corresponding to desired beam scanning directions to be covered by the linear feed region. In this way, a planar hybrid electromechanical beamforming antenna can form two independent beams in the upper hemisphere with only two mechanical actuators and a single axis of electronic beamforming, reducing production cost compared to existing multibeam antenna solutions.

A beamforming apparatus is constructed from a pliable medium and a conductor pattern disposed on the pliable medium to form a foldable Rotman lens.

In an embodiment, a downlight includes: a plurality of light emitting diodes (LEDs) disposed in a housing of the downlight, and a millimeter-wave radar. The millimeter-wave radar includes: an antenna disposed in the housing, a controller configured to: detect a presence of a human in a field-of-view of the millimeter-wave radar, determine a direction of movement of the detected human, and produce log data based on the direction of movement of the detected human, and a wireless module configured to transmit the log data to a wireless server.

A film comprising a first plurality of voids is provided, wherein respective ones of the first plurality of voids have a regular n-gon geometry, and the first plurality of voids are arranged on a regular n-gon lattice having a first size. The film may comprise a second plurality of voids arranged on a regular n-gon lattice having a second size different from the first size. An optical element and manufacturing method are also provided.

The disclosure provides a wireless communications systems that uses a polybeam geometry. A polybeam communications network, a polybeam antenna, a method of communicating are disclosed. In one example, the polybeam communications network includes: (1) a first communications structure, (2) first transceivers, and (3) a first polybeam antenna attached to the first communications structure that transmits first communication beams driven by corresponding ones of the first transceivers, having arcs of less than twenty degrees each and defining overlapping territories of coverage.