Claims
- 1. An electrically small, compact planar tunable microstrip antenna, comprising:a microstrip dielectric substrate sandwiched between a radiating element and a conductive ground plane; said microstrip dielectric substrate, being composed of a material having a relative dielectric constant, ∈r, similar to a relative magnetic permeability, μr, where said ∈r>1.0 and said μr>1.0, forming a permittivity to permeability ratio of between about 1:1 and about 1:3, said material being selected from group of materials consisting of ferrite compounds and ferrite-ferroelectric composite compounds; a means for tuning; said antenna having a given length, Al; said radiating element having a narrow portion and a wide portion; said narrow portion having a shorted end shorted to said ground plane, and said wide portion, having a central region near said narrow portion and a junction point opposing said shorted end, provides a given impedance; said dielectric substrate having an effective impedance value and a decreased wavelength due to said permittivity to permeability ratio; said narrow portion causing a reduced effective impedance at said junction point; and said decreased wavelength, a refractive index factor and said reduced impedance permitting a reduced antenna length, Ar, that operates at HF and VHF frequencies.
- 2. The electrically small, compact planar tunable microstrip antenna, recited in claim 1, further comprising said permittivity to permeability ratio being about 1:1.
- 3. The electrically small, compact planar tunable microstrip antenna, as recited in claim 2, further comprising said material being a ferrite compound.
- 4. The electrically small, compact planar tunable microstrip antenna, as recited in claim 3, further comprising said ferrite compound being selected from the group of ferrite compounds consisting of the garnet material aluminum doped compound, garnet material Gadolinium doped compound, magnesium ferrite compound and nickel ferrite compound.
- 5. The electrically small, compact planar tunable microstrip antenna, as recited in claim 4, further comprising said tuning means being a tuning coil.
- 6. The electrically small, compact planar tunable microstrip antenna, as recited in claim 5, further comprising said garnet material aluminum doped compound where said ∈r=13.8, said μr=11 and 11 is an initial relative permeability without any applied magnetic field.
- 7. The electrically small, compact planar tunable microstrip antenna, as recited in claim 5, further comprising said garnet material Gadolinium doped compound where said ∈r=15.4 and an initial μr=26.0.
- 8. The electrically small, compact planar tunable microstrip antenna, as recited in claim 5, further comprising said magnesium ferrite compound where said ∈r=12.7 and an initial μr=50.0.
- 9. The electrically small, compact planar tunable microstrip antenna, as recited in claim 5, further comprising said nickel ferrite compound where said ∈r=9.0 and an initial μr=23.0.
- 10. The electrically small, compact planar tunable microstrip antenna, as recited in claim 5, further comprising said reduced antenna length, Ar, being shorter than said given length, Al.
- 11. The electrically small, compact planar tunable microstrip antenna, as recited in claim 10, further comprising said radiating element being composed of a first metal.
- 12. The electrically small, compact planar tunable microstrip antenna, as recited in claim 11, wherein said first metal is copper.
- 13. The electrically small, compact planar tunable microstrip antenna, as recited in claim 10, further comprising said ground plane being composed of a second metal.
- 14. The electrically small, compact planar tunable microstrip antenna, as recited in claim 13, further comprising said second metal being selected from the group consisting of aluminum and copper.
- 15. The electrically small, compact planar tunable microstrip antenna, as recited in claim 10, further comprising said tuning coil being located beneath said ground plane.
- 16. The electrically small, compact planar tunable microstrip antenna, recited in claim 15, further comprising said dielectric substrate is positioned on top of said ground plane.
- 17. The electrically small, compact planar tunable microstrip antenna, recited in claim 16, further comprising said dielectric substrate having a thickness greater than said radiating element.
- 18. The electrically small, compact planar tunable microstrip antenna, recited in claim 17, further comprising said ground plane being thinner than said dielectric substrate.
- 19. The electrically small, compact planar tunable microstrip antenna, as recited in claim 18, further comprising said dielectric substrate having a refractive index factor of {square root over (∈rμr)}>18.
- 20. The electrically small, compact planar tunable microstrip antenna, as recited in claim 19, further comprising said antenna operating at about 3 MHz.
- 21. The electrically small, compact planar tunable microstrip antenna, as recited in claim 20, further comprising said reduced antenna length, Ar, is 10 cm.
- 22. The electrically small, compact planar tunable microstrip antenna, as recited in claim 21 further comprising said dielectric substrate being cylindrical.
- 23. The electrically small, compact planar tunable microstrip antenna, as recited in claim 2, further comprising said material being a ferrite-ferroelectric composite compound.
- 24. The electrically small, compact planar tunable microstrip antenna, recited in claim 23, wherein said tuning means is a DC bias.
- 25. The electrically small, compact planar tunable microstrip antenna, as recited in claim 24, further comprising said ferrite-ferroelectric composite compound being barium strontium titanate.
- 26. The electrically small, compact planar tunable microstrip antenna, as recited in claim 25, further comprising said barium strontium titanate compound having a fixed μr being tunable by varying an applied electric field on said dielectric substrate.
- 27. The electrically small, compact planar tunable microstrip antenna, recited in claim 26, further comprising said tuning means being a DC bias voltage on said barium strontium titanate compound changing its electric permittivity and thus changing its dielectric constant and frequency.
- 28. The electrically small, compact planar tunable microstrip antenna, as recited in claim 27, further comprising said dielectric substrate being cylindrical.
- 29. An electrically small, compact planar tunable microstrip antenna, comprising:a microstrip dielectric substrate sandwiched between a radiating element and a conductive ground plane; said microstrip dielectric substrate, being composed of a ferrite material having a relative dielectric constant, ∈r, similar to a relative magnetic permeability, μr, where said ∈r>1.0 and said μr>1.0, forming a permittivity to permeability ratio of between about 1:1 and about 1:3; a means for tuning; said antenna having a given length, Al; said radiating element having a narrow portion and a wide portion; said narrow portion having a shorted end shorted to said ground plane, and said wide portion, having a central region near said narrow portion and a junction point opposing said shorted end, provides a given impedance; said dielectric substrate having an effective impedance value and a decreased wavelength due to said permittivity to permeability ratio; said narrow portion causing a reduced effective impedance at said junction point; and said decreased wavelength, a refractive index factor and said reduced effective impedance permitting a reduced antenna length, Ar, that operates at HF and VHF frequencies.
- 30. The electrically small, compact planar tunable microstrip antenna, recited in claim 29, further comprising said permittivity to permeability ratio being about 1:1.
- 31. The electrically small, compact planar tunable microstrip antenna, as recited in claim 30, further comprising said ferrite material being selected from the group of ferrite compounds consisting of garnet material aluminum doped compound, garnet material Gadolinium doped compound, magnesium ferrite compound and nickel ferrite compound.
- 32. The electrically small, compact planar tunable microstrip antenna, as recited in claim 31, further comprising said tuning means being a tuning coil.
- 33. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said garnet material aluminum doped compound where said ∈r=13.8, said μr=11 and 11 is an initial relative permeability without any applied magnetic field.
- 34. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said garnet material Gadolinium doped compound where said ∈r=15.4 and an initial μr=26.0.
- 35. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said magnesium ferrite compound where said ∈r=12.7 and an initial μr=50.0.
- 36. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said nickel ferrite compound where said ∈r=9.0 and an initial μr=23.0.
- 37. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said reduced antenna length, Ar, being shorter than said given length, Al.
- 38. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said radiating element being composed of a first metal.
- 39. The electrically small, compact planar tunable microstrip antenna, as recited in claim 38, wherein said first metal is copper.
- 40. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said ground plane being composed of a second metal.
- 41. The electrically small, compact planar tunable microstrip antenna, as recited in claim 40, further comprising said second metal being selected from the group consisting of aluminum and copper.
- 42. The electrically small, compact planar tunable microstrip antenna, as recited in claim 32, further comprising said tuning coil being located beneath said ground plane.
- 43. The electrically small, compact planar tunable microstrip antenna, recited in claim 42, further comprising said dielectric substrate is positioned on top of said ground plane.
- 44. The electrically small, compact planar tunable microstrip antenna, recited in claim 43, further comprising said dielectric substrate having a thickness greater than said radiating element.
- 45. The electrically small, compact planar tunable microstrip antenna, recited in claim 44, further comprising said ground plane being thinner than said dielectric substrate.
- 46. The electrically small, compact planar tunable microstrip antenna, as recited in claim 45, further comprising said dielectric substrate having a refractive index factor of {square root over (∈rμr)}≧18.
- 47. The electrically small, compact planar tunable microstrip antenna, as recited in claim 46, further comprising said antenna reaching the lower frequency of the HF range.
- 48. The electrically small, compact planar tunable microstrip antenna, as recited in claim 47, further comprising said reduced antenna length, Ar, is 10 cm.
- 49. The electrically small, compact planar tunable microstrip antenna, as recited in claim 48, further comprising said dielectric substrate being cylindrical.
- 50. An electrically small, compact planar tunable microstrip antenna, comprising:a microstrip dielectric substrate sandwiched between a radiating element and a conductive ground plane; said microstrip dielectric substrate, being composed of a ferrite-ferroelectric composite material having a relative dielectric constant, ∈r, similar to a relative magnetic permeability, μr, where said ∈r>1.0 and said μr>1.0, forming a permittivity to permeability ratio of between about 1:1 and about 1:3; a means for tuning is coupled to a DC power source; said antenna having a given length, Al; said radiating element having a narrow portion and a wide portion; said narrow portion having a shorted end shorted to said ground plane, and said wide portion, having a central region near said narrow portion and a junction point opposing said shorted end, provides a given impedance; said dielectric substrate having a decreased wavelength due to said permittivity to permeability ratio; said narrow portion causing a reduced effective impedance at said junction point; and said decreased wavelength, a refractive index factor and said reduced effective impedance permitting a reduced antenna length, Ar, that operates at HF and VHF frequencies.
- 51. The electrically small, compact planar tunable microstrip antenna, as recited in claim 50, further comprising said permittivity to permeability ratio being about 1:1.
- 52. The electrically small, compact planar tunable microstrip antenna, as recited in claim 51, further comprising said ferrite-ferroelectric composite material being barium strontium titanate.
- 53. The electrically small, compact planar tunable microstrip antenna, recited in claim 52, wherein said tuning means is a DC bias.
- 54. The electrically small, compact planar tunable microstrip antenna, as recited in claim 53, further comprising said reduced antenna length, Ar, is shorter than said given length, Al.
- 55. The electrically small, compact planar tunable microstrip antenna, as recited in claim 54, further comprising said radiating element being composed of a first metal.
- 56. The electrically small, compact planar tunable microstrip antenna, as recited in claim 55, wherein said first metal is copper.
- 57. The electrically small, compact planar tunable microstrip antenna, as recited in claim 54, further comprising said ground plane being composed of a second metal.
- 58. The electrically small, compact planar tunable microstrip antenna, as recited in claim 57, further comprising said second metal being selected from the group of consisting of aluminum and copper.
- 59. The electrically small, compact planar tunable microstrip antenna, recited in claim 54, further comprising said dielectric substrate is positioned on top of said ground plane.
- 60. The electrically small, compact planar tunable microstrip antenna, as recited in claim 59, further comprising said dielectric substrate having a thickness greater than said radiating element.
- 61. The electrically small, compact planar tunable microstrip antenna, recited in claim 60, further comprising said ground plane being thinner than said dielectric substrate.
- 62. The electrically small, compact planar tunable microstrip antenna, recited in claim 61, further comprising said dielectric substrate having a refractive index factor of {square root over (∈rμr)}≧18.
- 63. The electrically small, compact planar tunable microstrip antenna, recited in claim 62, further comprising:said tuning means includes a chip capacitor; said chip capacitor being coupled to said DC power source by a plurality of RF blocking inductors; and said chip capacitor being coupled to said radiating element.
- 64. The electrically small, compact planar tunable microstrip antenna, recited in claim 63, further comprising said chip capacitor being located in the vicinity of said RF inductors.
- 65. The electrically small, compact planar tunable microstrip antenna, as recited in claim 64, further comprising said barium strontium titanate compound having a fixed μr being tunable by varying an applied electric field on said microstrip dielectric substrate.
- 66. The electrically small, compact planar tunable microstrip antenna, as recited in claim 65, further comprising said antenna being an HF antenna operating in the 3 MHz range.
- 67. The electrically small, compact planar tunable microstrip antenna, as recited in claim 66, further comprising said reduced antenna length, Ar, is 10 cm.
- 68. The electrically small, compact planar tunable microstrip antenna, as recited in claim 67, further comprising said ground plane being cylindrical.
- 69. A method for shortening a planar tunable microstrip antenna with a given length, Al, comprising the steps of:inserting a microstrip dielectric substrate between a radiating element and a conductive ground plane; forming said microstrip dielectric substrate from a material having a relative dielectric constant, ∈r, similar to a relative magnetic permeability, μr, where said ∈r>1.0 and said μr>1.0, forming a permittivity to permeability ratio of between about 1:1 and about 1:3, said material being selected from group of materials consisting of ferrite compounds and ferrite-ferroelectric composite compounds; coupling a means for tuning; forming said radiating element with a narrow portion having a shorted end shorted to said ground plane; forming said radiating element with a wide portion, said wide portion, having a central region near said narrow portion and a junction point opposing said shorted end, provides a given impedance; providing an effective impedance value and a decreased wavelength in said dielectric substrate due to said permittivity to permeability ratio; causing a reduced effective impedance at said junction point; and providing a reduced antenna length, Ar, due to said decreased wavelength, a refractive index factor and said reduced impedance that operates at HF and VHF frequencies.
- 70. The method for shortening a planar tunable microstrip antenna, as recited in claim 69, further comprising the step of providing said permittivity to permeability ratio at about 1:1.
- 71. The method for shortening a planar tunable microstrip antenna, as recited in claim 70, further comprising the step of forming said material from a ferrite compound.
- 72. The method for shortening a planar tunable microstrip antenna, as recited in claim 71, further comprising the step of selecting said ferrite compound from the group of ferrite compounds consisting of:a garnet material aluminum doped compound where said ∈r=13.8, said μr=11 and 11 is an initial relative permeability without any applied magnetic field; a garnet material Gadolinium doped compound where said ∈r=15.4 and an initial μr=26.0; a magnesium ferrite compound where said ∈r=12.7 and an initial μr=50.0; and a nickel ferrite compound where said ∈r=9.0 and an initial μr=23.0.
- 73. The method for shortening a planar tunable microstrip antenna, as recited in claim 72, further comprising the step of forming said tuning means from a tuning coil.
- 74. The method for shortening a planar tunable microstrip antenna, as recited in claim 73, further comprising the step of forming said radiating element from a first metal.
- 75. The method for shortening a planar tunable microstrip antenna, as recited in claim 74, further comprising the step of forming said radiating element from copper.
- 76. The method for shortening a planar tunable microstrip antenna, as recited in claim 73, further comprising the step of forming said ground plane from a second metal.
- 77. The method for shortening a planar tunable microstrip antenna, as recited in claim 76, further comprising the step of selecting said second metal from the group consisting of aluminum and copper.
- 78. The method for shortening a planar tunable microstrip antenna as recited in claim 73, further comprising the step of providing said dielectric substrate with a refractive index factor of {square root over (∈rμr)}≧18.
- 79. The method for shortening a planar tunable microstrip antenna, as recited in claim 78, further comprising the step of forming an antenna operating at the 3 MHz range.
- 80. The method for shortening a planar tunable microstrip antenna, as recited in claim 79, further comprising the step of permitting said reduced antenna length, Ar, to be 10 cm.
- 81. The method for shortening a planar tunable microstrip antenna, as recited in claim 80, further comprising the step of forming said dielectric substrate into a cylindrical shape.
- 82. The method for shortening a planar tunable microstrip antenna, as recited in claim 70, further comprising the step of forming said material from a ferrite-ferroelectric composite compound.
- 83. The method for shortening a planar tunable microstrip antenna, as recited in claim 82, further comprising the step of forming said tuning means from a DC bias.
- 84. The method for shortening a planar tunable microstrip antenna, as recited in claim 83, further comprising the step of forming said ferrite-ferroelectric composite compound from barium strontium titanate.
- 85. The method for shortening a planar tunable microstrip antenna, as recited in claim 84, further comprising the step of providing said barium strontium titanate compound with a fixed μr being tunable by varying an applied electric field on said dielectric substrate.
- 86. The method for shortening a planar tunable microstrip antenna, as recited in claim 85, further comprising the step of applying a DC bias voltage on said barium strontium titanate compound to change its electric permittivity and thus change its dielectric constant and frequency.
- 87. The method for shortening a planar tunable microstrip antenna, as recited in claim 86, further comprising the step of forming said dielectric substrate into a cylindrical shape.
GOVERNMENT INTEREST
The invention described herein may be manufactured, used, imported, sold, and licensed by or for the Government of The United States of America without the payment to me of any royalty thereon.
US Referenced Citations (6)