A system includes a window and a microwave amplifier positioned proximate the window. The window has a low-E coating. The microwave amplifier includes a substrate and multiple concentric rings of material that form a Fresnel zone plate lens. The concentric rings are attached to the substrate. The Fresnel zone plate lens is configured to focus an attenuated microwave signal, which is attenuated by the low-E coating of the window, on an antenna, which may (1) amplify the attenuated microwave signal by at least 20 dB and/or (2) provide an image at the antenna such that an area of the Fresnel zone plate lens divided by an area of the image is at least 100 and/or such that the area of the image is approximately equal to an area of the antenna. The attenuated microwave signal has a designated frequency in a range of frequencies from 6 GHz to 80 GHz.

An antenna unit including an antenna array having a plurality of antennas and a lens plate comprising a mask pattern. The antenna array defines a first plane, and the lens plate defines a second plane. The lens plate is spaced apart from the antenna array, and the second plane is parallel to the first plane. The mask pattern is configured to focus first waves incident on the lens plate through diffraction to a region of the antenna array. The first waves are incident on the lens plate at a first angle relative to an axis normal to the second plane. The mask pattern is configured to focus second waves incident on the lens plate through diffraction to the first region of the antenna array. The second waves are incident on the lens plate at a second angle relative to the axis that is different from the first angle.

The present disclosure provides a lens assembly, a terahertz wave tomography system and method, and a terahertz wave filter. The lens assembly includes: a first substrate and a second substrate that are oppositely disposed; a seal, wherein the seal, the first substrate and the second substrate enclose a cavity in which a magnetic fluid is filled; and a plurality of electromagnetic generating units disposed on at least one of a first side of the first substrate close to the second substrate or a second side of the first substrate away from the second substrate, wherein at least a part of the plurality of electromagnetic generating units are configured to generate a magnetic field in a case where a voltage is applied to make the magnetic fluid form a Fresnel zone plate pattern.

A planar conductive millimeter-wave lens includes: a planar conductive plate with a first surface and a second surface, wherein the first surface is parallel to the second surface; a plurality of openings from the first surface through the planar conductive plate to the second surface, where an axis of each opening is perpendicular to the first surface and the second surface. A size of each opening is a function of a position of said each opening on the planar conductive plate such that an insertion phase collectively imposed by the openings on an incident wave causes the incident wave to pass through the first surface and the planar conductive plate, exit from the second surface and to focus at a predetermined distance from the second surface.

The present invention relates to a communication technique for fusing a 5G communication system to support a higher data transmission rate than a 4G system, with IoT technology, and a system thereof. This disclosure is based on 5G communication technology and the IoT related technology and can be applied to intelligent services (for example, smart home, smart building, smart city, smart car or connected car, healthcare, digital education, retail, security, safety-related services, or the like). In addition, the present invention provides an antenna module comprising an antenna and a lens, wherein the antenna comprises a first antenna array which deflects and radiates a radio wave from a vertical plane of the antenna by a predetermined first angle, and the lens can be spaced apart from the antenna by a first determined distance to change the phase of the radio wave radiated from the antenna.

A lens includes a first hemispherical refractive structure having a first effective refractive index based on a first fill pattern of the first hemispherical refractive structure. The lens further includes a second hemispherical refractive structure having a second effective refractive index based on a second fill pattern of the second hemispherical refractive structure. The second hemispherical refractive structure is arranged as a hemispherical shell coupled to and concentric with the first hemispherical refractive structure. The second effective refractive index is different than the first effective refractive index.

Disclosed are multiple-input, multiple-output (MIMO) antenna systems with high gain having an impedance bandwidth greater than 1 GHz and high side-lobe rejection. Suitable systems are configurable to have a radar lens with, for example, an 81 antenna array. Additionally, beam steering architecture that concentrates radiated energy through a dielectric lens to achieve a narrow high-gain beam.

A lens includes a first hemispherical refractive structure having a first effective refractive index based on a first fill pattern of the first hemispherical refractive structure. The lens further includes a second hemispherical refractive structure having a second effective refractive index based on a second fill pattern of the second hemispherical refractive structure. The second hemispherical refractive structure is arranged as a hemispherical shell coupled to and concentric with the first hemispherical refractive structure. The second effective refractive index is different than the first effective refractive index.

A wireless device according to one aspect of the present invention includes an antenna, a focuser, and an absorber. The focuser includes a first and a second region. One of the regions transmits radio waves, and the other blocks them or changes their phase. In a plan view from the antenna, the shape of the first region is a circle and the shape of the second region is an annular ring with an inner diameter equal to the diameter of the first region. The antenna is on the center axis of the circle. A part of the absorber is present between a first plane where the antenna is present and a second plane on which the second region is present. The absorber is present at a position away from the antenna by the outer circumference of the annular ring or longer in a direction perpendicular to the axis.

The invention is a dual and stagger-tuned 8-step FZP antenna for use in VSAT operations. The preferred embodiment achieves the desired antenna gain at the RX band (centered at 11.95 GHz) and the TX band (centered at 14.25 GHz). The flexible antenna is 1-meter diameter and less than 1-inch thick, allowing it to be folded to the size of a tissue box for easy storage and transportability.