Claims
- 1. A frequency agile, directive beam patch antenna, comprising:
an array of antenna elements, said antenna array elements loaded with tunable dieletric capacitors in order to tune their frequency response; and an electronic phase shifter controlling said array of antenna elements in order to spatially scan the main radiation beam.
- 2. The frequency agile, directive beam patch antenna of claim 1, wheriein said tunable dielectric capacitor comprises:
a substrate having a low dielectric constant with planar surfaces; a tunable dielectric film on said substrate of low loss tunable dielectric material; metallic electrodes with predetermined length, width, and gap distance; and low loss isolation material used to isolate an outer bias metallic contact and a metallic electrode on said tunable dielectric.
- 3. The frequency agile, directive beam patch antenna of claim 2, wherein the Q factor of the tunable dielectric capacitor is between 50, for very high tuning material, and 300 or higher, for low tuning material.
- 4. The frequency agile, directive beam patch antenna of claim 2, wherein the capacitance of the tunable dielectric capacitors is from 0.1 pF to three pF.
- 5. The frequency agile, directive beam patch antenna of claim 1, wheriein said tunable dielectric capacitor comprises a micro-electromechanical varactor.
- 6. The frequency agile, directive beam patch antenna of claim 5, wherein said micro-electromechanical varactor is made in parallel topology.
- 7. The frequency agile, directive beam patch antenna of claim 6, wherein in the parallel plate structure, a first plate is suspended at a distance from a second plate by suspension springs, said distance can vary in response to an electrostatic force between said first and said second parallel plates induced by applying a bias voltage.
- 8. The frequency agile, directive beam patch antenna of claim 5, wherein said micro-electromechanical varactor is made in an interdigital topology.
- 9. The frequency agile, directive beam patch antenna of claim 8, wherein in the interdigital configuration, moving adjacent fingers comprising the capacitor varies the effective area of the capacitor.
- 10. A method of tuning a patch antenna over a wide frequency range, comprising the steps of:
loading an array of antenna elements with tunable dieletric capacitors in order to tune their frequency response; and controlling said array of antenna elements with an electronic phase shifter in order to spatially scan the main radiation beam.
- 11. The method of tuning a patch antenna over a wide frequency range of claim 10, wheriein said tunable dielectric capacitor comprises:
a substrate having a low dielectric constant with planar surfaces; a tunable dielectric film on said substrate of low loss tunable dielectric material; metallic electrodes with predetermined length, width, and gap distance; and low loss isolation material used to isolate an outer bias metallic contact and a metallic electrode on said tunable dielectric.
- 12. The method of tuning a patch antenna over a wide frequency range of claim 11, wherein the Q factor of the tunable dielectric capacitor is between 50, for very high tuning material, and 300 or higher, for low tuning material.
- 13. The method of tuning a patch antenna over a wide frequency range of claim 11, wherein the capacitance of the tunable dielectric capacitors is from 0.1 pF to three pF.
- 14. The method of tuning a patch antenna over a wide frequency range of claim 10, wherein said tunable dielectric capacitor comprises a micro-electromechanical varactor.
- 15. The method of tuning a patch antenna over a wide frequency range of claim 14, wherein said micro-electromechanical varactor is made in parallel topology.
- 16. The method of tuning a patch antenna over a wide frequency range of claim 15, wherein in said parallel plate structure, a first plate is suspended at a distance from a second plate by suspension springs, said distance can vary in response to an electrostatic force between said first and said second parallel plates induced by applying a bias voltage.
- 17. The method of tuning a patch antenna over a wide frequency range of claim 14, wherein said micro-electromechanical varactor is made in an interdigital topology.
- 18. The method of tuning a patch antenna over a wide frequency range of claim 17, wherein in the interdigital configuration, moving adjacent fingers comprising the capacitor varies the effective area of the capacitor.
- 19. A patch antenna, comprising:
an array of antenna elements, said antenna array elements loaded with tunable dieletric capacitors in order to tune their frequency response, said tunable dielectric capacitor comprising: a substrate having a low dielectric constant with planar surfaces; a tunable dielectric film on said substrate of low loss tunable dielectric material; metallic electrodes with predetermined length, width, and gap distance; and low loss isolation material used to isolate an outer bias metallic contact and a metallic electrode on said tunable dielectric; and an electronic phase shifter controlling said array of antenna elements in order to spatially scan the main radiation beam.
- 20. The patch antenna of claim 19, wherein the Q factor of the tunable dielectric capacitor is between 50, for very high tuning material, and 300 or higher, for low tuning material and the capacitance of the tunable dielectric capacitors is from 0.1 pF to three pF.
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application claims the benefit of priority under 35 U.S.C Section 119 from U.S. Provisional Application Ser. No. 60/372,741, filed Apr. 15, 2002, entitled, FREQUENCY AGILE, DIRECTWE BEAM PATCH ANTENNAS, by Sengupta et al., assigned to Paratek Microwave, Inc. the disclosure of which is hereby incorporated by reference in its entirety for all purposes.
Provisional Applications (1)
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Number |
Date |
Country |
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60372741 |
Apr 2002 |
US |