Periodic structure assemblies are provided. An example assembly includes: a dielectric layer having a top and a bottom; a first frequency selective layer disposed on the top of the dielectric layer, the first frequency selective layer having a plurality of electrically conductive elements arranged as a first periodic structure; and a second frequency selective layer disposed on the bottom of the dielectric layer, the second frequency selective layer having a plurality of electrically conductive elements arranged as a second periodic structure. Another periodic structure assembly includes: a substrate; and an array of periodic elements defined by a contiguous trace of conductive material supported by the substrate, each of the periodic elements exhibiting side walls, with each of the side walls having an inwardly extending protrusion.

A lens design method is disclosed for designing a lens to reshape an actual far-field radiation pattern of a radiation source, such as a spiral antenna, to a preferred far-field radiation pattern. The method comprises:determining a preferred far-field radiation pattern of the radiation source;deriving a corresponding near-field radiation pattern from the preferred far-field radiation pattern;determining an actual near-field pattern of the radiation source;mapping an electric field and a magnetic field of the actual near-field radiation pattern to the derived near-field radiation pattern using a transfer relationship, the transfer relationship comprising material parameters which characterize the lens; and,determining the material parameters.

An antenna for transmitting electromagnetic radiation. The antenna comprises a core further comprising at least one layer of contiguous core material and windings disposed on the core forming a plurality or winding segments. The windings define gaps between each winding segment. A microprocessor supplies current to the antenna in the form of a bit stream. The microprocessor controlling the current to control parameters of the bit stream, the parameters further comprising bit amplitude, bit width, bit rate, timing, delays, bit direction, bit order, and frequency. A material of the core comprises an amorphous or annealed material, further comprising metal or alloys, comprising one or more of nickel or nano-crystalline or nano-materials.

An antenna for transmitting electromagnetic radiation. The antenna comprises a core further comprising at least one layer of contiguous core material and windings disposed on the core forming a plurality or winding segments. The windings define gaps between each winding segment, wherein parameters of the gaps and parameters of the windings are selected to generate a balanced magnetic field. A material of the core comprises an amorphous or annealed material, further comprising metal or alloys, comprising one or more of nickel or nano-crystalline or nano-materials.

Corrective meta surface lens is used to reduce the illumination and spill-over losses and improve the overall efficiency of a parabolic antenna when is horn-mounted, and/or top-mounted, and/or deposited directly on the frontal reflector surface of the parabolic antenna. For the horn-mounted model, a meta surface lens is placed in front of or in the aperture of the feed horn to reduce side lobe level, which results in lower parabolic antenna spill-over losses and overall efficiency improvement by more than 40% (1.5 dB). For the top-mounted model, the meta surface lens is mounted on top of (or above) the parabolic reflector, which results in reduction in illumination losses, and greater than 70% (2.5 dB) efficiency. The meta surface lens has a wideband response, is lightweight and has a lattice structure which makes it a great candidate for withstanding wind forces.

The present invention discloses a low-profile broadband high-gain filtering antenna. The antenna comprises a radiator, an upper-layer dielectric substrate, a lower-layer dielectric substrate, a microstrip feed-line having open stubs, a ground plane having a plurality of spaced slots, and a metallized via. The radiator generates resonances, provides a broadband and high-gain radiation passband, and meanwhile, adjusting the dimensions of the radiator can adjust the roll-off rate at the upper edge of the passband. The open stub generates a radiation null, and suppresses a resonance in upper band of the antenna. The spaced slot suppresses a resonance in lower band of the antenna. The metallized via connects the microstrip feed-line and the ground plane, generates a radiation null, and improves the roll-off rate at the lower edge of the passband.

The present invention discloses a low-profile broadband high-gain filtering antenna. The antenna comprises a radiator, an upper-layer dielectric substrate, a lower-layer dielectric substrate, a microstrip feed-line having open stubs, a ground plane having a plurality of spaced slots, and a metallized via. The radiator generates resonances, provides a broadband and high-gain radiation passband, and meanwhile, adjusting the dimensions of the radiator can adjust the roll-off rate at the upper edge of the passband. The open stub generates a radiation null, and suppresses a resonance in upper band of the antenna. The spaced slot suppresses a resonance in lower band of the antenna. The metallized via connects the microstrip feed-line and the ground plane, generates a radiation null, and improves the roll-off rate at the lower edge of the passband.

A frequency reflecting unit is provided. The frequency reflecting unit is used as a portion of a frequency reflector. The frequency reflecting unit with a three-dimensional structure includes a metal pattern and at least one via. The metal pattern is disposed on a metal layout layer defined on one side of the frequency reflecting unit. One end of the via is disposed corresponding to the metal pattern. The via forms a non-zero angle with the metal layout layer. The other end of the via is an open circuit.

Antennas such as flat panel, leaky wave antennas with directional coupler feeds and waveguides are disclosed. In one example, an antenna includes a surface having antenna elements, a guided wave transmission line, and a coupling surface. The guided wave transmission line provides a guided feed wave. The coupling surface is between and separates the guided wave transmission line and the surface having antenna elements. The coupling surface controls coupling of the guided feed wave to the antenna elements. The coupling surface can also spatially filter the guided feed wave to provide a more uniform power density for the antenna elements. The guided feed wave can be a high power density electromagnetic wave or a density radially decaying electromagnetic wave.

Periodic structure assemblies are provided. An example assembly includes: a dielectric layer having a top and a bottom; a first frequency selective layer disposed on the top of the dielectric layer, the first frequency selective layer having a plurality of electrically conductive elements arranged as a first periodic structure; and a second frequency selective layer disposed on the bottom of the dielectric layer, the second frequency selective layer having a plurality of electrically conductive elements arranged as a second periodic structure. Another periodic structure assembly includes: a substrate; and an array of periodic elements defined by a contiguous trace of conductive material supported by the substrate, each of the periodic elements exhibiting side walls, with each of the side walls having an inwardly extending protrusion.