A beamforming network includes a three-dimensional discrete lens with front and back apertures, each comprising a plurality of discrete elements. Each discrete element of the back aperture is homologous to a respective discrete element of the front aperture. The discrete lens further comprises a plurality of transmission lines connecting respective pairs of homologous discrete elements. The beamforming network can further include a feed array. The feed array illuminates the back aperture, when the lens is working in transmission, and/or receives signals from the back aperture, when the lens is working in reception. A ratio of a size of the back aperture and a size of the front aperture defines a zooming factor. The value of the zooming factor is different from unity, so that angles of emergence of beams of electromagnetic radiation emitted by the front aperture are either tilted towards a center axis of the discrete lens or tilted away from the center axis, compared to angles of incidence of corresponding beams on the back aperture.

A beamforming network includes a three-dimensional discrete lens with front and back apertures, each comprising a plurality of discrete elements. Each discrete element of the back aperture is homologous to a respective discrete element of the front aperture. The discrete lens further comprises a plurality of transmission lines connecting respective pairs of homologous discrete elements. The beamforming network can further include a feed array. The feed array illuminates the back aperture, when the lens is working in transmission, and/or receives signals from the back aperture, when the lens is working in reception. A ratio of a size of the back aperture and a size of the front aperture defines a zooming factor. The value of the zooming factor is different from unity, so that angles of emergence of beams of electromagnetic radiation emitted by the front aperture are either tilted towards a center axis of the discrete lens or tilted away from the center axis, compared to angles of incidence of corresponding beams on the back aperture.

Arrangement of resonators in an aperiodic configurations are described, which can be used for electromagnetic cloaking of objects. The overall assembly of resonators, as structures, do not all repeat periodically and at least some of the resonators are spaced such that their phase centers are separated by more than a wavelength. The arrangements can include resonators of several different sizes and/or geometries arranged so that each size or geometry corresponds to a moderate or high Q response that resonates within a specific frequency range, and that arrangement within that specific grouping of akin elements is periodic in the overall structure. The relative spacing and arrangement of groupings can be defined by self similarity and origin symmetry. Fractal based scatters are described. Further described are boundary condition layer structures that can activate and deactivate cloaking/lensing structures.

An antenna system for beam direction adjustment and shared use ofradio-frequency integrated circuit (RFIC) units includes an array antenna module including feed antenna units for producing at least one input signal, RFIC units respectively electrically connected to the feed antenna units through switching units and less in number than the feed antenna units, a control module for controlling, based on at least one antenna configuration message, some of the switching units to be switched on and the rest thereof to be switched off, and a microwave lens module for forming at least one beam in a particular direction. A feed antenna unit electrically connected to the switched-on switching unit is in a working state, and can receive a signal from the RFIC units and radiate a corresponding input signal to the microwave lens module. The antenna system greatly reduces the number of RFIC units, thereby lowering the overall cost.

An antenna system for beam direction adjustment and shared use ofradio-frequency integrated circuit (RFIC) units includes an array antenna module including feed antenna units for producing at least one input signal, RFIC units respectively electrically connected to the feed antenna units through switching units and less in number than the feed antenna units, a control module for controlling, based on at least one antenna configuration message, some of the switching units to be switched on and the rest thereof to be switched off, and a microwave lens module for forming at least one beam in a particular direction. A feed antenna unit electrically connected to the switched-on switching unit is in a working state, and can receive a signal from the RFIC units and radiate a corresponding input signal to the microwave lens module. The antenna system greatly reduces the number of RFIC units, thereby lowering the overall cost.

Arrangement of resonators in an aperiodic configurations are described, which can be used for electromagnetic cloaking of objects. The overall assembly of resonators, as structures, do not all repeat periodically and at least some of the resonators are spaced such that their phase centers are separated by more than a wavelength. The arrangements can include resonators of several different sizes and/or geometries arranged so that each size or geometry corresponds to a moderate or high Q response that resonates within a specific frequency range, and that arrangement within that specific grouping of akin elements is periodic in the overall structure. The relative spacing and arrangement of groupings can be defined by self similarity and origin symmetry. Fractal based scatters are described. Further described are bondary condition layer structures that can activate and deactive cloaking/lensing structures.

Arrangement of resonators in an aperiodic configurations are described, which can be used for electromagnetic cloaking of objects. The overall assembly of resonators, as structures, do not all repeat periodically and at least some of the resonators are spaced such that their phase centers are separated by more than a wavelength. The arrangements can include resonators of several different sizes and/or geometries arranged so that each size or geometry corresponds to a moderate or high Q response that resonates within a specific frequency range, and that arrangement within that specific grouping of akin elements is periodic in the overall structure. The relative spacing and arrangement of groupings can be defined by self similarity and origin symmetry. Fractal based scatters are described. Further described are bondary condition layer structures that can activate and deactive cloaking/lensing structures.

A radar system includes a transmit front end device including a transmit planar component, and a receive front end device including a receive planar component. Each of the transmit planar component and the receive planar component includes a first end, a second end, a cavity space and a linear array of antennas. The cavity space is bounded by beam ports along a first side of the cavity space and by array ports along a second side of the cavity space. The cavity space is in operative communication with the beam ports and with the array ports to form a Rotman lens. A linear array of antennas is located along the second end of the planar component. The transmit planar component and receive planar component are arranged such that the linear array of antennas of the transmit planar component and the linear array of antennas are perpendicular to one another.

A radar system includes a transmit front end device including a transmit planar component, and a receive front end device including a receive planar component. Each of the transmit planar component and the receive planar component includes a first end, a second end, a cavity space and a linear array of antennas. The cavity space is bounded by beam ports along a first side of the cavity space and by array ports along a second side of the cavity space. The cavity space is in operative communication with the beam ports and with the array ports to form a Rotman lens. A linear array of antennas is located along the second end of the planar component. The transmit planar component and receive planar component are arranged such that the linear array of antennas of the transmit planar component and the linear array of antennas are perpendicular to one another.

A radio wave lens includes a first surface, a second surface, and an optical axis passing through the first surface and the second surface. The first surface has concave portions or convex portions provided concentrically or symmetrically with respect to the optical axis in plan view, and a depth of each of the concave portions or a height of each of the convex portions is set according to a distance from the optical axis.