Described embodiments include an antenna and a method. In an embodiment, the antenna includes a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half
Described embodiments include an antenna and a method. In an embodiment, the antenna includes a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna. The aperture is configured to define at least two selectable complex radiofrequency electromagnetic fields on the surface with tangential wavenumbers up to 2π over the aperture element spacing (k_apt=2π/a). In an embodiment, the holographic aperture includes an amplitude and phase modulation holographic aperture. In an embodiment, each electromagnetic wave scattering element has a respective electronically controllable electromagnetic response to an incident radiofrequency electromagnetic wave, and the plurality of individual electromagnetic wave scattering elements are electronically controllable in combination to define the at least two selectable complex radiofrequency electromagnetic fields on the surface.
대표청구항▼
1. An antenna comprising: a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna,
1. An antenna comprising: a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna, the plurality of individual electromagnetic wave scattering elements of the aperture configured to define at least two selectable, arbitrary complex radiofrequency electromagnetic fields on the surface with tangential wavenumbers up to 2π over the aperture periodic inter-element spacing (k_apt=2π/a),wherein the surface is a second surface of a generally planar structure, the planar structure including a first surface configured to receive incident radiofrequency electromagnetic waves, the holographic aperture configured to coherently reconstruct the incident radiofrequency electromagnetic waves responsive to a definition on the second surface of a selected one of the at least two selectable, arbitrary complex radiofrequency electromagnetic fields, and the second surface configured to transmit the coherent reconstruction of the incident radiofrequency electromagnetic waves. 2. The antenna of claim 1, wherein the holographic aperture includes a transmission holographic aperture. 3. The antenna of claim 1, wherein the holographic aperture includes a reflective holographic aperture. 4. The antenna of claim 1, wherein the holographic aperture includes an amplitude and phase modulation holographic aperture. 5. The antenna of claim 1, wherein the holographic aperture includes a plurality of individual electromagnetic wave scattering elements distributed on the surface, each electromagnetic wave scattering element having a respective electronically controllable electromagnetic response to an incident radiofrequency electromagnetic wave, and the plurality of individual electromagnetic wave scattering elements electronically controllable in combination to define the at least two selectable, arbitrary complex radiofrequency electromagnetic fields on the surface. 6. The antenna of claim 5, wherein the aperture element spacing (k_apt=2π/a) includes the inverse of a center-to-center spacing distance between at least two individual electromagnetic scattering elements of the plurality of individual electromagnetic wave scattering elements. 7. The antenna of claim 5, further comprising at least two electromagnetic wave conducting structures respectively coupled to at least two individual electromagnetic wave scattering elements of the plurality of individual electromagnetic wave scattering elements. 8. The antenna of claim 5, wherein the incident radiofrequency electromagnetic waves include an incident wave guide-propagated electromagnetic waves. 9. The antenna of claim 5, wherein the incident radiofrequency electromagnetic waves include incident conductor-propagated electromagnetic waves. 10. The antenna of claim 5, wherein the plurality of individual electromagnetic wave scattering elements are embedded within, located on, or located within an evanescent electromagnetic field of the surface. 11. The antenna of claim 1, wherein the second surface is configured to transmit a coherent reconstruction of the incident radiofrequency electromagnetic waves as free space propagating radiofrequency electromagnetic waves. 12. The antenna of claim 1, wherein the second surface is configured to transmit a coherent reconstruction of the incident radiofrequency electromagnetic waves as waveguide-propagating radiofrequency electromagnetic waves. 13. The antenna of claim 1, wherein the second surface is configured to transmit a coherent reconstruction of the incident radiofrequency electromagnetic waves as conductor-propagating radiofrequency electromagnetic waves. 14. The antenna of claim 1, wherein the generally planar surface includes a generally planar surface curved in one or more directions. 15. The antenna of claim 1, wherein the generally planar surface includes a generally planar structure having a first surface and second surface spaced apart from and generally parallel to the first surface. 16. The antenna of claim 1, wherein the holographic aperture includes a plurality of individual metamaterial electromagnetic wave scattering elements distributed on the surface, each metamaterial electromagnetic wave scattering element having a respective electronically controllable electromagnetic response to an incident radiofrequency electromagnetic wave, and the plurality of individual metamaterial electromagnetic wave scattering elements are electronically controllable in combination to define the at least two selectable, arbitrary complex radiofrequency electromagnetic fields on the surface. 17. The antenna of claim 1, wherein each radiofrequency electromagnetic field respectively defines a radiative near-field radiofrequency electromagnetic radiation pattern. 18. The antenna of claim 17, wherein each radiative near-field radiofrequency electromagnetic radiation pattern respectively defines a pattern configured to direct radiofrequency electromagnetic power at a target device. 19. The antenna of claim 17, wherein each radiative near-field radiofrequency electromagnetic radiation pattern respectively defines a quasi-Gaussian electromagnetic beam having a radiative near-field distribution configured to direct radiofrequency electromagnetic power e at a target device. 20. The antenna of claim 1, wherein each radiofrequency electromagnetic field respectively defines a reactive near-field radiofrequency electromagnetic field. 21. The antenna of claim 20, wherein each reactive near-field radiofrequency electromagnetic field respectively defines radiofrequency electromagnetic field having a predominantly magneto-inductive nature. 22. The antenna of claim 20, wherein each reactive near-field radiofrequency electromagnetic field is respectively configured to direct radiofrequency electromagnetic power to a target device. 23. The antenna of claim 1, wherein the holographic aperture and the surface are configured to transmit radiofrequency electromagnetic waves into free space, the transmitted radiofrequency electromagnetic waves coherently reconstructed by the holographic aperture from received incident waves and have a radiation pattern defined by a selected one of the at least two selectable, arbitrary complex radiofrequency electromagnetic fields. 24. The antenna of claim 1, wherein the periodic inter-element spacing is equal less than one-third of a free space wavelength of an operating frequency of the antenna. 25. The antenna of claim 1, wherein the periodic inter-element spacing is equal less than one-quarter of a free space wavelength of an operating frequency of the antenna. 26. An antenna comprising: a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna, the plurality of individual electromagnetic wave scattering elements of the aperture configured to define at least two selectable, arbitrary complex radiofrequency electromagnetic fields on the surface with tangential wavenumbers up to 2π over the aperture periodic inter-element spacing (k_apt=2π/a),wherein the holographic aperture includes a first holographic aperture and a second holographic aperture configured in combination to define at least two selectable arbitrary complex radiofrequency electromagnetic fields on the surface with tangential wavenumbers up to a over the aperture element spacing (k_apt=2π/a). 27. The antenna of claim 26, wherein the first holographic aperture and the second holographic aperture are configured to be encountered in series by incident radiofrequency electromagnetic waves. 28. The antenna of claim 26, wherein the first holographic aperture is further configured to control an amplitude of electromagnetic radiofrequency waves radiated in response to first arbitrary complex radiofrequency electromagnetic field defined on the surface, and the second holographic aperture is further configured to control a phase of electromagnetic radiofrequency waves radiated in response to a second arbitrary complex radiofrequency electromagnetic field defined on the surface. 29. The antenna of claim 26, wherein the first holographic aperture includes a plurality of individual electromagnetic wave scattering elements distributed on the surface, and the second holographic aperture includes a plurality of liquid crystal phase control elements distributed on the surface. 30. A method comprising: receiving incident radiofrequency electromagnetic waves;establishing a selected arbitrary complex radiofrequency electromagnetic field on a surface using a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna, the plurality of individual electromagnetic wave scattering elements of the aperture configured to define at least two selectable, arbitrary complex radiofrequency electromagnetic fields on the surface with tangential wavenumbers up to 2π over the aperture periodic inter-element spacing (k_apt=2π/a), the arbitrary complex radiofrequency electromagnetic field selected from at least two selectable, arbitrary complex radiofrequency electromagnetic fields;coherently reconstructing the incident radiofrequency electromagnetic waves by the selected complex radiofrequency electromagnetic field established on the surface, the reconstructed radiofrequency electromagnetic waves having a radiation pattern defined by the selected complex radiofrequency electromagnetic field; andtransmitting the coherently reconstructed radiofrequency electromagnetic waves. 31. The method of claim 30, wherein each electromagnetic field respectively defines a radiative near-field electromagnetic radiation pattern. 32. The method of claim 30, wherein each electromagnetic field respectively defines a reactive near-field radiofrequency electromagnetic field. 33. The method of claim 30, wherein the holographic aperture includes a metamaterial holographic aperture. 34. The method of claim 30, further comprising: selecting the arbitrary complex radiofrequency electromagnetic field from the at least two selectable, arbitrary complex radiofrequency electromagnetic fields. 35. The method of claim 30, further comprising: establishing another selected arbitrary complex radiofrequency electromagnetic field on the surface using the plurality of individual electromagnetic wave scattering elements of the holographic aperture, the another selected arbitrary complex radiofrequency electromagnetic field selected from the at least two selectable, arbitrary complex radiofrequency electromagnetic fields;coherently reconstructing the incident radiofrequency electromagnetic waves using the another selected complex radiofrequency electromagnetic field established on the surface, the reconstructed radiofrequency electromagnetic waves having another radiation pattern defined by the another selected complex radiofrequency electromagnetic field; andtransmitting the another coherently reconstructed. 36. A method comprising: receiving radiofrequency electromagnetic waves at a first surface of a generally planar structure having the first surface and a second surface;establishing a selected arbitrary complex radiofrequency electromagnetic field on the second surface using a holographic aperture having a surface including a plurality of individual electromagnetic wave scattering elements distributed thereon with a periodic inter-element spacing equal to or less than one-half of a free space wavelength of an operating frequency of the antenna, the plurality of individual electromagnetic wave scattering elements of the aperture configured to define at least two selectable arbitrary complex radiofrequency electromagnetic fields on the second surface with tangential wavenumbers up to 2π over the aperture periodic inter-spacing (k_apt=2π/a), the arbitrary complex radiofrequency electromagnetic field selected from the at least two selectable arbitrary complex radiofrequency electromagnetic fields;coherently reconstructing the received radiofrequency electromagnetic waves using the selected complex radiofrequency electromagnetic field established on the second surface, the reconstructed radiofrequency electromagnetic waves having a radiation pattern defined by the selected complex radiofrequency electromagnetic field; andtransmitting from the second surface the coherently reconstructed radiofrequency electromagnetic waves. 37. The method of claim 36, further comprising: selecting the arbitrary complex radiofrequency electromagnetic field from the at least two selectable, arbitrary complex radiofrequency electromagnetic fields.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (75)
Lin Zhen Biao ; Lin Jian-Jin ; Robin Seymour, Adaptive nulling methods for GPS reception in multiple-interference environments.
Scheidemann,Adi; Hess,Henry, Analytical instruments using a pseudorandom array of sources, such as a micro-machined mass spectrometer or monochromator.
Sievenpiper, Daniel F.; Colburn, Joseph S.; Fong, Bryan Ho Lim; Ganz, Matthew W.; Gyure, Mark F.; Lynch, Jonathan J.; Ottusch, John; Visher, John L., Artificial impedance structure.
Bauck Jerald L. (2834 S. Calle Rosa Cir. Mesa AZ 85202) Daniel Sam (921 E. Driftwood Dr. Tempe AZ 85282), Electronically scanned space fed antenna system and method of operation thereof.
Smith, David R.; Brady, David; Driscoll, Tom; Hunt, John; Mrozack, Alexander; Reynolds, Matthew; Marks, Daniel, Metamaterial devices and methods of using the same.
Daniel Sam Mordochai ; Ma Stephen Chih-Hung ; Warble Keith Vaclav ; Pan Shao-Wei ; Wang Shay-Ping Thomas, Method and apparatus for producing wide null antenna patterns.
Drabowitch Serge (Paris FRX) Aubry Claude (Paris FRX) Casseau Daniel (Paris FRX), Method and apparatus for reducing the power of jamming signals received by radar antenna sidelobes.
Fong, Bryan H.; Colburn, Joseph S.; Ottusch, John; Sievenpiper, Daniel F.; Visher, John L., Method and system for determining an optimized artificial impedance surface.
Fong, Bryan Ho Lim; Colburn, Joseph S.; Herz, Paul R.; Ottusch, John J.; Sievenpiper, Daniel F.; Visher, John L., Method for designing artificial surface impedance structures characterized by an impedance tensor with complex components.
Collins H. Dale (Richland WA) McMakin Douglas L. (Richland WA) Hall Thomas E. (Kennewick WA) Gribble R. Parks (Richland WA), Real-time holographic surveillance system.
James H. Schaffner ; Daniel Sievenpiper ; Jonathan J. Lynch ; Robert Y. Loo ; Pyong K. Park, Reconfigurable antenna for multiple band, beam-switching operation.
Bily, Adam; Boardman, Anna K.; Hannigan, Russell J.; Hunt, John; Kundtz, Nathan; Nash, David R.; Stevenson, Ryan Allan; Sullivan, Philip A., Surface scattering antennas.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.