RU2003110373A - METHOD FOR INCREASING THE CURRENT ALTITUDE OF A SMALL-SIZED ANTENNA DEVICE WITH A CONTROLLED DIRECTION DIAGRAM AND A SMALL-SIZED ANTENNA DEVICE FOR IMPLEMENTING THE METHOD - Google Patents

Claims (38)

1. A method of increasing the effective height of a small-sized antenna device, which includes the steps of providing a wave system as an antenna in the form of an oscillating circuit, including a flat or cylindrical capacitor, connecting the circuit to a transmitting or receiving path, ensuring that none of the capacitor plates are in direct contact with common bus of the receiving or transmitting device or with an external braid of an asymmetric feeder, to exclude the capacitor in the long line mode th period of time after exposure to the circuit of electromagnetic signals, ensuring, due to the above connection method, the electrodynamic mode in the circuit, leading to a significant reduction in the electric capacitance of the capacitor of the circuit, ensuring the absence of the action of electric fields of standing waves in the near zone of the circuit operating in steady state for the resonance frequency of the circuit, the implementation of the effective distribution in the said wave system of the currents of the traveling waves of the received or transmitted signals als corresponding to the conditions for increasing the effective height of the antenna element. 2. A method of increasing the effective height of a small-sized antenna device with a controlled radiation pattern, which includes the steps of providing a wave system as an antenna in the form of an oscillating circuit, including a flat or cylindrical capacitor, providing, by fulfilling the condition d << λ / 4, where d Is the thickness of the dielectric layer of the capacitor, λ is the wavelength of the received or transmitted signals, the interaction of standing and traveling electromagnetic waves caused by the action of the same source in a different wave system, ensuring the collinearity of the vectors of the electric fields of the indicated waves and localizing the energy of the traveling waves in the spatial area of the antenna, and the level of said localization, corresponding to an effective increase in the effective height of the antenna, is ensured by linear relationships between the circuit elements, controlling the antenna pattern by changing the distribution the intensity of the traveling waves in the space surrounding the circuit, and the reception and, accordingly, the transmission of traveling waves with an optimal level of harmonization with the receiver and transmit path, respectively. 3. A method of increasing the effective height of a small-sized antenna device, which includes providing as an antenna an oscillating circuit with resonance at a given frequency of a transmitted or received electromagnetic signal and consisting of a flat capacitor, the metal plates of which are separated by a dielectric layer of a certain thickness and at least one inductive element, to ensure asymmetrical connection of the circuit to the output of the transmitting or to the input of the receiving device and the placement of the capacitor at a distance l, which is the height of the antenna, from the conductive common bus, with l <λ / 4. 4. The method according to claim 3, in which the flat capacitor is made with the possibility of bending up to giving it a cylindrical shape or torsion to enable the change of radiation pattern. 5. The method according to claim 3, in which as the at least one element of the inductance used inductance coil or section of a two-wire line. 6. The method according to claim 3 or 5, in which the ground surface is used as a common tire. 7. The method according to any one of claims 3 to 6, in which the maximum linear size of the capacitor is in the range from 0.1 to 0.3 λ / 4. 8. The method according to claim 3, in which said flat capacitor consists of three metal plates: one common, located on one side of the dielectric layer, and two identical, separated from each other by a gap on the other side of the dielectric, and said inductive element is made in in the form of two identical inductors, one of which is connected by one terminal to one of the separated plates, and the second terminal is connected to a common conductive bus, the area of which is equal to or greater than the area of the common capacitor plate, located at a distance l <λ / 4 from the capacitor, the second inductor is connected with one terminal to the second split plate, and the second terminal to the central core of the coaxial cable, the braid of which is connected to the common bus, or to the output of the transmitter or to the input of the receiving devices mounted on a common bus, while providing such a mutual orientation of the circuit elements that the normal to the plane of the capacitor is perpendicular to the plane of the common bus. 9. The method of claim 8, wherein said planar capacitor further comprises a second common plate and an additional dielectric layer superimposed on the divided plates, the second common plate superimposed on the other side of the additional dielectric layer. 10. The method according to any one of claims 3 and 5-9, in which the capacitor and the common bus are located on the same plane or on parallel planes. 11. The method according to any one of claims 3 and 5-9, wherein the normal to the plane of the capacitor is parallel to the plane of the common bus. 12. The method according to any one of claims 3-11, wherein the SWR of the antenna is provided no more than a value equal to two at the edges of the bandwidth of the circuit by setting the optimal distance l. 13. The method according to item 12, in which the optimal distance l is selected from the condition of its inverse proportion to the resonance frequency of the circuit. 14. The method according to any one of claims 3 and 5-13, in which the polarization vector of the electric field of the signals received or transmitted by the antenna has continuous components parallel to the normal to the plane of the capacitor during a round-trip of the normal, and components parallel to the plane of the capacitor having a beam structure. 15. The method of controlling the radiation pattern of a small-sized antenna device, which includes the steps of providing as an antenna an oscillating circuit having a resonance at a given frequency of the transmitted or received electromagnetic signal and containing a flat capacitor, the metal plates of which are separated by a dielectric layer of a certain thickness and at least one inductive element, providing an asymmetric connection of the circuit to the output of the transmitter or to the input of the receiver and location the capacitor at a distance l, which is the height of the antenna, from the conductive common bus, with l <λ / 4, where λ is the wavelength of the received or correspondingly transmitted signal, with the same level of capacitive coupling of the opposite ends (sides) of the capacitor relative to the common bus, to exclude receiving (transmitting) electromagnetic signals whose polarization vector is perpendicular to the normal to the plane of the capacitor, and ensuring deviation of the direction of zero reception (transmission) from the specified normal due to unbalanced CA levels of capacitive coupling of the opposite ends (sides) of the capacitor relative to the common bus. 16. The method according to any one of claims 3-15, in which the common bus area is much larger than the capacitor area, while ensuring the absence of reception (transmission) of electromagnetic signals from the common bus, opposite the antenna connection surface, due to the reflector acting as a common bus . 17. The method according to any one of claims 3-16, in which a metallized surface is used as a common bus, the area of which is selected in the range from values close to the area S of the capacitor, to values significantly exceeding the area S. 18. The method according to any one of claims 3-16, in which a metal rod with a length of the order of λ / 2, or two such rods located at an angle of 90 ° to each other in a plane parallel to the plane of the capacitor, is used as a common bus, corresponding to the middle of the mentioned rods, is the connection point of the first inductance coil and braid of the coaxial cable when using it. 19. The method of claim 8, comprising connecting a capacitor to a communication channel with a transmitting or receiving device by directly connecting one of the separate plates to said channel and connecting the second separate plate to one of the terminals of the inductor, the second terminal of which is connected to a common bus or to braided coaxial cable. 20. The method according to claim 3, in which the capacitor has only two plates, separated by a dielectric layer of thickness d. 21. The method according to any one of claims 3 to 20, comprising determining the area of the capacitor plates from the condition of providing the necessary electrical capacitance that determines the frequency bandwidth of the wave system, taking into account the known values of the signal frequencies, thickness d of the dielectric layer, as well as the degree of influence of the interaction process of standing and traveling waves in the antenna system by the value of the dynamic capacitance of the circuit. 22. The method according to any one of claims 3 to 21, including ensuring the operation of the antenna at several resonant frequencies by introducing additional reactive elements connected in parallel to the inductors and using additional electrical connections due to the effect of mutual induction. 23. A small-sized antenna device containing a flat capacitor, consisting of at least three metal plates: one common, located on one side of the dielectric layer, and two identical, separated from each other by a gap, on the other side of the dielectric layer, two identical inductors , one of which is connected by one terminal to one of the divided plates, and the second terminal is connected to a common conductive bus located at a distance l <λ / 4 from the capacitor, and the second inductor is connected it is single by one output to the second divided lining, and by the second output - to the central core of the coaxial cable, the braid of which is connected to the common bus, or to the output of the transmitting or input of the receiving devices mounted on the common bus. 24. The device according to item 23, in which the normal to the plane of the capacitor is perpendicular to the plane of the common bus, and the polarization vector of the electric field of the signals received or transmitted by the antenna has continuous components parallel to the normal to the plane of the capacitor during a round-trip of the normal, and components parallel to the plane of the capacitor, having a radiation structure. 25. The device according to item 23, in which the normal to the plane of the capacitor is parallel to the plane of the common bus. 26. The device according to item 23, in which the capacitor and the common bus are located on the same plane or on parallel planes. 27. The device according A.25 or 26, made with the possibility of changing the antenna pattern due to the introduction of an additional vibrator having a length close to the value λ / 4, connected to a common bus and located in a plane perpendicular to the common bus and the plane of the capacitor in it the geometric center, at a distance of (0.05-0.15) λ / 4 from the common bus, this ensures that the protrusion of the vibrator exceeds the distance l of the installation of the capacitor relative to the common bus by an order of magnitude (0.2-0.3) λ / 4 . 28. The device according to claims 23-27, wherein said capacitor comprises four plates, including a second common plate and an additional dielectric layer superimposed on the divided plates. 29. A small-sized antenna device containing a flat capacitor, consisting of at least three metal plates: one common, located on one side of the dielectric layer, and two identical, separated from each other by a certain gap, on the other side of the dielectric layer, an inductor connected one terminal to one of the separated plates, and the second terminal to a common conductive bus located at a distance l <λ / 4 from the capacitor, while the second separate plate is connected to the central le coaxial cable whose sheath is connected to the shared bus, either to the output of the transmitter or receiver to the input device, mounted on a common bus. 30. A small-sized antenna device containing a flat capacitor, consisting of two metal plates separated by a dielectric layer, an inductor connected by one terminal to one of the capacitor plates, and the second terminal to a common conductive bus located at a distance l <λ / 4 from capacitor, and the second lining of the capacitor is connected to the Central core of the coaxial cable, the braid of which is connected to a common bus, or to the output of the transmitting or to the input of the receiving devices mounted on a common bus e. 31. The device according to clause 30, in which said capacitor is cylindrical in shape and is a piece of coaxial cable, and the inductor is connected to the cable braid. 32. The device according to any one of paragraphs.23-31, in which the common bus is made in the form of a metallized surface, the area of which is in the range from values close to the area S of the capacitor, to values significantly exceeding the area S. 33. The device according to any one of paragraphs.23-26, 28-30 and 32, having the ability to change the antenna pattern due to the bending of the capacitor along the axis of the central zone separating the plates at a certain angle, or bending under a certain radius of the entire plane of the capacitor, up to before giving it a cylindrical shape. 34. A small antenna device with a variable radiation pattern, having a direction of zero reception (transmission), variable in two coordinates in space, containing a flat capacitor, consisting of at least three metal plates: one common, located on one side of the dielectric layer, and two identical, separated from each other by a certain gap, on the other side of the dielectric layer, two identical inductors, one of which is connected by one output to one of the separated circuits latch, and by the second terminal to the common conductive bus located at a distance l <λ / 4 from the capacitor, and the second inductor is connected by one terminal to the second divided lining, and the second terminal to the central core of the coaxial cable, the braid of which is connected to the common bus either to the output of the transmitter or to the input of the receiving devices mounted on a common bus whose area is equal to or greater than the area of the common lining of the capacitor, while the mutual orientation of the capacitor and the common bus is such that it is normal to the plane of the condenser the ora is perpendicular to the plane of the common bus, providing the direction of zero reception (transmission) of electromagnetic waves, the polarization vector of which lies in a plane perpendicular to the axis that determines the spatial orientation of the antenna, and additional vibrators are connected to the common bus through controlled reactive elements, the degree of their relationship with certain parts of the plane the capacitor at each moment of time determines the orientation of the axis of zero reception (transmission) by the antenna of electromagnetic signals. 35. A small antenna device with a variable radiation pattern, having a direction of zero reception (transmission), variable in two coordinates in space, containing a flat capacitor consisting of two metal plates separated by a dielectric layer, an inductor connected by one output to one of the plates, and the second conclusion - to a common conductive bus located at a distance l <λ / 4 from the capacitor, and the second lining of the capacitor is connected to the Central core of the coaxial cable, braid which is connected to the common bus, either to the output of the transmitting or to the input of the receiving devices mounted on a common bus, the area of which is equal to or greater than the area of the common lining of the capacitor, while the mutual orientation of the capacitor and the common bus is such that the normal to the plane of the capacitor is perpendicular to the plane of the common bus, providing the direction of zero reception (transmission) of electromagnetic waves, the polarization vector of which lies in a plane perpendicular to the axis that determines the spatial orientation of the antenna, and to the common bus e additional vibrators are connected through controlled reactive elements, the degree of interconnection of which with certain sections of the capacitor plane at each moment of time determines the direction of the axis of zero reception (transmission) of the electromagnetic signal by the antenna. 36. The device according to clause 34 or 35, in which the capacitor and the common bus have the shape of such rectangles, the common bus area being two to three times the capacitor area, varactors connected coaxially to the midpoints of the small sides of the common bus are used as controlled reactive elements so that the total length of the section from the ends of the vibrators is as close as possible to λ / 2, in order to ensure, under antiphase control of the varactors, changes in the angular position of the axis of zero reception (transmission) in a certain sector on the plane STI perpendicular to the surface of the capacitor and passing through the mid-planes of the small sides of the capacitor and a common bus. 37. The device according to clause 36, in which the vibrators are located in the same plane at a certain angle to the plane of the common bus and have a length that provides the necessary degree of relationship with the capacitor for a given value of the sector changes direction of zero reception (transmission). 38. The device according to clause 34 or 35, in which the total busbar area is significantly larger than the capacitor area and has an arbitrary shape to exclude the reception of signals of any polarization from the common bus side opposite to the capacitor location, with the possibility of connecting two additional vibrators located through controlled reactive elements in a plane perpendicular to the plane of the location of the first two vibrators, to change the angle of inclination of the axis of zero reception (transmission) simultaneously in two mutually perpendicular planar planes.