IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0099580
(2002-03-15)
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발명자
/ 주소 |
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출원인 / 주소 |
- The United States of America as represented by the Secretary of the Army
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대리인 / 주소 |
Zelenka, MichaelTereschuk, George B.
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인용정보 |
피인용 횟수 :
27 인용 특허 :
6 |
초록
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An electrically small planar tunable microstrip antenna is provided by stacking a radiating element, microstrip dielectric substrate and a ground plane, and coupling the ground plane to a means for tuning. The electrically small, compact, planar tunable microstrip antenna operates at HF and VHF freq
An electrically small planar tunable microstrip antenna is provided by stacking a radiating element, microstrip dielectric substrate and a ground plane, and coupling the ground plane to a means for tuning. The electrically small, compact, planar tunable microstrip antenna operates at HF and VHF frequencies. The microstrip dielectric substrate is composed of a ferrite or ferrite-ferroelectric composite material having a relative dielectric constant similar to a relative magnetic permeability forming a permittivity to permeability ratio of between about 1:1 and about 1:3. The ground plane is coupled to a means for tuning. In the ferrite-ferroelectric embodiment, the present invention provides an antenna length that is substantially shortened to approximately 1% of the length of a monopole antenna or conventional microstrip antenna with tuning accomplished by a multi-turn coil mechanism. The electrically small planar tunable microstrip antenna provides tuning by varying the .di-elect cons.rof the dielectric substrate's ferroelectric material by applying an electric field and by changing the μrof ferrite material in the dielectric substrate by applying a magnetic field to the ferrite material. This invention also encompasses methods for providing substantial reduction in antenna size at the HF and VHF frequencies with electrically small planar tunable microstrip antennas comprising a dielectric substrate composed of ferrite and ferrite-ferroelectric composite materials.
대표청구항
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An electrically small planar tunable microstrip antenna is provided by stacking a radiating element, microstrip dielectric substrate and a ground plane, and coupling the ground plane to a means for tuning. The electrically small, compact, planar tunable microstrip antenna operates at HF and VHF freq
An electrically small planar tunable microstrip antenna is provided by stacking a radiating element, microstrip dielectric substrate and a ground plane, and coupling the ground plane to a means for tuning. The electrically small, compact, planar tunable microstrip antenna operates at HF and VHF frequencies. The microstrip dielectric substrate is composed of a ferrite or ferrite-ferroelectric composite material having a relative dielectric constant similar to a relative magnetic permeability forming a permittivity to permeability ratio of between about 1:1 and about 1:3. The ground plane is coupled to a means for tuning. In the ferrite-ferroelectric embodiment, the present invention provides an antenna length that is substantially shortened to approximately 1% of the length of a monopole antenna or conventional microstrip antenna with tuning accomplished by a multi-turn coil mechanism. The electrically small planar tunable microstrip antenna provides tuning by varying the .di-elect cons.rof the dielectric substrate's ferroelectric material by applying an electric field and by changing the μrof ferrite material in the dielectric substrate by applying a magnetic field to the ferrite material. This invention also encompasses methods for providing substantial reduction in antenna size at the HF and VHF frequencies with electrically small planar tunable microstrip antennas comprising a dielectric substrate composed of ferrite and ferrite-ferroelectric composite materials. 1. A method for controlling an array antenna, said array antenna comprising: a radiating element for receiving a radio signal; a plurality of parasitic elements provided apart from said radiating element by a predetermined distance; a plurality of variable-reactance elements connected to said plurality of parasitic elements, respectively; and controlling means for changing a directivity characteristic of said array antenna by changing each reactance value set to each of said variable-reactance elements so that each of said parasitic elements operates as either one of a director and a reflector, wherein said method includes a step of iterating the following steps of: upon setting the reactance values of said respective variable-reactance elements by randomly perturbing the reactance values from predetermined initial values, calculating predetermined cross correlation coefficients between a received signal and a training sequence signal before and after the perturbation, the received signal being obtained by receiving by said array antenna a training sequence signal contained in a radio signal transmitted from a remote transmitter, and the training sequence signal being generated so as to have a signal pattern identical to that of the transmitted training sequence signal; selecting and setting reactance values when the cross correlation coefficient increases between those before and after the perturbation; and setting reactance values obtained by randomly perturbing the selected reactance values, to the variable-reactance elements, respectively. 2. The method for controlling the array antenna as claimed in claim 1, wherein the initial values are reactance values of said respective variable-reactance elements corresponding to one radiation pattern having the maximum cross correlation coefficient out of the reactance values of said respective variable-reactance elements corresponding to a predetermined plurality of radiation patterns. 3. The method for controlling the array antenna as claimed in claim 2, wherein the plurality of radiation patterns include at least one set of the following patterns: (a) a plurality of sector beam patterns having the maximum gains in directions directed from said radiating element toward said respective parasitic elements, respectively; and (b) a plurality of sector beam patterns having the maximum gains in directions directed from said radiating element toward respective intermediate positions located between respective pairs of mutually adjacent parasitic elements. 4. A method for controlling an array antenna, said array antenna comprising: a radiating element for receiving a radio signal; a plurality of parasitic elements provided apart from said radiating element by a predetermined distance; a plurality of variable-reactance elements connected to said plurality of parasitic elements, respectively; and controlling means for changing a directivity characteristic of said array antenna by changing each reactance value set to each of said variable-reactance elements so that each of said parasitic elements operates as either one of a director and a reflector, wherein said method includes: upon dividing a range of each reactance value available for each of said variable-reactance elements, into two ranges thereof and setting representative values of respective divided two ranges to said variable-reactance elements, respectively, a first step of calculating predetermined cross correlation coefficients between a received signal and a training sequence signal before and after the perturbation, the received signal being obtained by receiving by said array antenna a training sequence signal contained in a radio signal transmitted from a remote transmitter, and the training sequence signal being generated so as to have a signal pattern identical to that of the transmitted training sequence signal, and selecting and setting, as initial values, reactance values of said resp ective variable-reactance elements corresponding to a larger cross correlation coefficient out of the two cross correlation coefficients corresponding to the representative values of the respective divided two ranges; and a second step of dividing a range belonging to the selected reactance values into two ranges thereof, calculating the cross correlation coefficients upon setting of the representative values of the respective divided two ranges to said variable-reactance elements, respectively, and selecting and setting reactance values of said variable-reactance elements corresponding to a larger cross correlation coefficient out of the two cross correlation coefficients corresponding to the representative values of the respective divided two ranges, thereby controlling a main beam and a null(s) of said array antenna so that the main beam is directed toward a desired wave and the null(s) is directed toward an interference wave(s). 5. The method for controlling the array antenna as claimed in claim 4, wherein the first step includes a step of, upon dividing the range of each reactance value available for each of said variable-reactance elements, into two ranges thereof and setting representative values of respective divided two ranges to said variable-reactance elements, respectively, calculating a predetermined cross correlation coefficient between a received signal and a training sequence signal, the received signal being obtained by receiving a training sequence signal contained in a radio signal transmitted from a remote transmitter by said array antenna, and the training sequence signal being generated so as to have a signal pattern identical to that of the received training sequence signal, and selecting and setting, as initial values, reactance values of said respective variable-reactance elements corresponding to a larger cross correlation coefficient out of the two cross correlation coefficients corresponding to medians of the respective divided two ranges, and wherein the second step includes a step of, upon dividing the range belonging to the selected reactance values into two ranges thereof and setting of the medians of the respective divided two ranges to said variable-reactance elements, respectively, calculating the cross correlation coefficient, and selecting and setting reactance values of said variable-reactance elements corresponding to a larger cross correlation coefficient out of the two cross correlation coefficients corresponding to the medians of the respective divided two ranges. 6. The method for controlling the array antenna as claimed in claim 4, further including a step of iterating the process of the second step until a predetermined number of iterations. 7. The method for controlling the array antenna as claimed in claim 4, instead of the first step, said method including, upon setting of reactance values of said respective variable-reactance elements corresponding to a predetermined plurality of radiation patterns to said variable-reactance elements, respectively, calculating the cross correlation coefficient, and selecting and setting, as initial values, reactance values of said respective variable-reactance elements corresponding to one radiation pattern having the maximum cross correlation coefficient. 8. The method for controlling the array antenna as claimed in claim 7, wherein the plurality of radiation patterns include at least one set of: (a) a plurality of sector beam patterns having maximum gains in directions directed from said radiating element toward said parasitic elements, respectively; (b) a plurality of sector beam patterns having maximum gains in directions directed from the radiating element toward respective intermediate positions between respective pairs of mutually adjacent parasitic elements, respectively; and (c) a plurality of radiation patterns having lobes in directions directed from the radiating element toward a plurality of mutually non-adjacent a lternate parasitic elements. 9. A method for controlling an array antenna, said array antenna comprising: a radiating element for receiving a radio signal; a plurality of parasitic elements provided apart from said radiating element by a predetermined distance; a plurality of variable-reactance elements connected to said plurality of parasitic elements, respectively; and controlling means for changing a directivity characteristic of said array antenna by changing each reactance value set to each of said variable-reactance elements so that each of said parasitic elements operates as either one of a director and a reflector, wherein said method includes a control step of: perturbing the reactance values of said variable-reactance elements, respectively, by a predetermined step width, sequentially, calculating a predetermined estimation function value for each of the reactance values, setting post-perturbation values to the reactance values when the estimation function values calculated for each of said variable-reactance elements before and after the perturbation are improved whereas setting pre-perturbation values to the reactance values when the estimation function values calculated before and after the perturbation are not improved, decreasing the step width for a succeeding-iteration process with respect to a reactance value of a variable-reactance element for which the estimation function value is not improved, and further iteratively executing a process of inverting a sign of the step width, thereby calculating and setting reactance values of said variable-reactance elements, respectively, for directing a main beam of said array antenna toward a desired wave and directing a null(s) thereof toward an interference wave(s). 10. The method for controlling the array antenna as claimed in claim 9, wherein the control step includes a step of, when the estimation function values calculated before and after the perturbation is not improved, decreasing a step width for a succeeding-iteration process with respect to a reactance value of a variable-reactance element for which the estimation function value is not improved so that the step width becomes one q-th thereof (where q is a rational number) by using a predetermined step-width change division factor q, and further inverting a sign of the resulting step width. 11. The method for controlling the array antenna as claimed in claim 9, wherein the control step includes a step of, when the estimation function value is not improved at a first-time iteration, maintaining the step width as it is and inverting the sign of the step width at a second-time iteration. 12. The method for controlling the array antenna as claimed in claim 9, wherein the control step includes the following steps of, when the set reactance value reaches a setting-limit value of a variable range for each of the reactance values of said variable-reactance elements, making the sign of the step width inverse to a sign of the step width when the set reactance value reaches the setting-limit value, and further decreasing the step width every iteration. 13. The method for controlling the array antenna as claimed in claim 9, wherein the control step includes the following steps of calculating an absolute value of a gradient value which is a difference between estimation function values before and after the iteration in the preceding-time iteration with respect to said variable-reactance elements, sorting the absolute values of a plurality of calculated gradient values in the descending order, perturbing each of the reactance values of said variable-reactance elements by a predetermined step width sequentially in an order of said variable-reactance elements corresponding to the order in which said variable-reactance elements are sorted. 14. The method for controlling the array antenna as claimed in claim 9, wherein the control step includes the following steps of calculating a gradien t value which is a difference between estimation function values before and after the iteration in the preceding-time iteration with respect to said variable-reactance elements, then when the gradient values calculated for all the variable-reactance elements equal to or smaller than zero, calculating reactance values of said variable-reactance elements for directing a main beam of the array antenna apparatus toward a desired wave and directing a null(s) thereof toward an interference wave(s), so that the estimation function values calculated by using the steepest gradient method are maximized or minimized so as to be improved. 15. A method for controlling an array antenna, said array antenna comprising: a radiating element for receiving a radio signal; a plurality of parasitic elements provided apart from said radiating element by a predetermined distance; a plurality of variable-reactance elements connected to said plurality of parasitic elements, respectively; and controlling means for changing a directivity characteristic of said array antenna by changing each reactance value set to each of said variable-reactance elements so that each of said parasitic elements operates as either one of a director and a reflector, wherein said method includes the following steps of: perturbing the reactance values of said variable-reactance elements, respectively, by a predetermined difference width ΔX sequentially, calculating a predetermined estimation function value for each of the reactance values, and based on the calculated estimation function values and by using a steepest gradient method having a step width μ, iteratively calculating reactance values of said variable-reactance elements, respectively, so that the estimation function value becomes either one of the maximum and the minimum; and upon calculating and setting each of the reactance values of said variable-reactance elements for directing a main beam of said array antenna apparatus toward a desired wave and directing a null(s) thereof toward an interference wave(s), decreasing the difference width ΔX and the step width μ by using a predetermined decreasing function depending either one of on the estimation function value f and on a signal to interference noise ratio SINR calculated from the estimation function f. 16. The method for controlling the array antenna as claimed in claim 15, wherein the following equation is used as a recurrence formula for the steepest gradient method: where μ=αΔX, Xnis a reactance vector whose elements are reactance values of said respective variable-reactance elements at an n-th iteration, ∇ΔXf is a gradient resulting when the estimation function f is perturbed by the difference width ΔX, and α is a predetermined constant. 17. The method for controlling the array antenna as claimed in claim 15, wherein the decreasing function representing the difference width ΔX is represented by the following equation with respect to the signal to interference noise ratio SINR calculated from the estimation function value f: ΔX=ΔX0[1-{log10(SINR)}/γ], in Japan, A-P2000-44, SAT2000-41, MW2000-44, pp. 7-14, Jul. 2000 (English language abstract on p. 7). Ohira, Takashi, "Basic Theory on ESPAR Antenna Equivalent Weight Vector and Its Gradient," Technical Report of IEICE, The Institute of Electronics, Information, and Communication Engineers in Japan, A-P2001-16, SAT2001-3, pp. 15-20, May 2001 (English language abstract on p. 15). Ohira, Takashi, "ESPAR Antenna Blind Adaptive Beamforming Based on a Moment Criterion," Technical Report of IEICE, The Institute of Electronics, Information, and Communication Engineers in Japan, ED2001-155, MW2001-115, pp. 23-28, Nov. 2001 (English language abstract on p. 23).
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