RU2004113095A - LENS ANTENNA DEVICE - Google Patents

Claims (18)

1. A lens antenna device for radio waves containing a Luneberg hemispherical lens made of a dielectric material, a reflective plate having a larger size than the diameter of the lens, mounted on the cut surface of the lens sphere into two halves, an antenna element mounted at the focal point of the lens, holder, designed to install the antenna element, and the mounting section, designed to install the antenna device on the mounting part, and the reflective plate is adapted to be installed Key to the mounting piece so that it is essentially vertical to the ground. 2. The lens antenna device according to claim 1, characterized in that the mounting part is located on the reflective plate so that the reflective plate can be mounted on the surface of the wall or side surface of the building. 3. A lens antenna device for radio waves containing a Luneberg hemispherical lens made of a dielectric material, a reflective plate having a larger size than the diameter of the lens, mounted on the cutting surface of the lens sphere into two halves, an antenna element mounted at the focal point of the lens, holder, designed to install the antenna element, and the mounting section, designed to install the antenna device on the mounting part, and the reflective plate is adapted to be installed Key to the mounting part with an inclination relative to the ground. 4. A lens antenna device for radio waves, comprising a Luneberg semi-spherical lens made of dielectric material, a reflective plate having a larger size than the diameter of the lens, mounted on the cut surface of the lens sphere into two halves, and an antenna element mounted on the focal point of the lens , as well as a holder for installing an antenna element in which the reflective plate is formed so that it has a non-circular shape, obtained by removing its portion, is not schegosya portion reflecting radio waves arriving from directions in a predetermined range, and wherein the Luneberg lens is mounted on the reflecting plate offset to a direction opposite to the direction in which the lens transmits and receives radio waves. 5. The lens antenna device according to claim 4, characterized in that the reflective plate has the shape of a fan formed by a large arcuate edge concentrically with respect to the center of the lens and having a larger diameter than the lens, a small arcuate edge located near the outer contour of the lens, opposite the large arcuate edge, and the side edges connecting the ends of the large arcuate edge with the ends of the small arcuate edge, or a shape covering such a fan contour. 6. The lens antenna device according to claim 5, characterized in that the large arcuate edge of the reflective plate is cut with the fact that in any area, the smaller the angle of incidence of the radio waves, the smaller the distance from the center of the lens to the edge. 7. The lens antenna device according to claim 5 or 6, characterized in that the reflective plate is asymmetric. 8. The lens antenna device according to claim 5 or 6, characterized in that the reflective plate is symmetrical, while the opening angle of the fan forming the reflective plate is 130 ° or less. 9. A lens antenna device for radio waves, comprising a reflective plate for radio waves, a Luneberg hemispherical lens mounted on a reflective plate such that the cut surface of the sphere into two halves is located on the reflective surface, the antenna element for transmitting, receiving or transmitting and receiving radio waves, and a holder configured to mount the antenna elements in predetermined positions, and there are many antenna elements, the number of which corresponds to the number a number of subscribers involved in the transmission of a radio signal. 10. An antenna device for radio waves comprising a reflective plate for radio waves, a Luneberg hemispherical lens mounted on a reflective plate such that the cut surface of the sphere into two halves is located along the reflective surface, an antenna element for transmitting, receiving or transmitting and receiving radio waves, and an arcuate support bracket enveloping the lens carrying a plurality of antenna elements, further comprising means for mounting the antenna elements at intervals, respectively the existing distances between satellites in geostationary orbits, located on the arcuate portion of the support of the support bracket element passing along the spherical surface of the lens, and a mechanism for controlling the elevation angle, with the possibility of pivoting the support bracket to the desired position around an axis passing through the center of the lens. 11. The antenna device of claim 10, characterized in that it further comprises a mechanism for fine-tuning the azimuth and elevation angle for tuning to polarized waves. 12. The antenna device according to claim 10 or 11, characterized in that it comprises a plurality of support brackets mounted rotatably about a common axis of rotation, the plurality of antenna elements being distributed and mounted on respective support brackets. 13. The antenna device according to any one of paragraphs.10-12, characterized in that the support bracket has a deformed shape such that both ends thereof are not arcuate, and the arcuate section with the antenna element holder is located between these non-arcuate sections while maintaining a constant distance between the support bracket and the spherical surface of the lens. 14. Coordinate map for a lens antenna device for radio waves, made in the form of a coating adapted for putting on a hemispherical Luneberg lens, on the surface of which lines of equal latitude and lines of equal differences of longitude values are drawn, used as indicators for installing antenna elements, as well as an installation a mark defining the reference direction for coating installation on the lens, taking into account the assumption that the latitude of the antenna installation point is θ and its longitude is φ, and also that the longitude the geostationary orbit is equal to φs, and the difference in their longitude values is Δφ = φ-φs, the lines of equal differences in longitude values represent the geometric location of points on a hemispherical surface, obtained by changing θ and maintaining a constant value of Δφ, and the lines of equal latitude represent a geometric location points on a hemispherical surface, obtained by changing Δφ, while maintaining a constant value of θ. 15. Coordinate map for a lens antenna device for radio waves, deposited directly on the surface of a hemispherical Luneberg lens or on a film glued to the indicated surface, containing lines of equal latitude and lines of equal differences of longitude values used as pointers for installing antenna elements, taking into account the assumption that the latitude of the antenna installation point is θ, and its longitude is φ, and also that the satellite longitude in the geostationary orbit is φs, and the difference in their longitude is Δφ = -φs, lines of equal longitude difference values represent the locus of points on a hemispherical surface obtained by changing θ while maintaining a constant and the value Δφ, and the equal latitude lines represent the locus of points on a hemispherical surface obtained by changing Δφ and while maintaining the constant value θ. 16. A lens antenna device for radio waves according to any one of claims 9 to 13, characterized in that it is combined with a coordinate map according to claims 14 or 15. 17. A lens antenna device for radio waves comprising a reflective plate for radio waves, a Luneberg hemispherical lens mounted on a reflective plate, the cut surface of the sphere in two halves being located on the reflective surface, an antenna element for transmitting, receiving or transmitting and receiving radio waves, and holder for the specified antenna element, combined with a coordinate map according to claims 14 or 15. 18. The lens antenna device for radio waves according to claim 17, comprising a lens antenna device for radio waves comprising a reflective plate for radio waves, a Luneberg hemispherical lens mounted on said reflective plate such that the cut surface of the sphere into two halves is located on the reflective surface, and the antenna an element for transmitting, receiving or transmitting and receiving radio waves, combined with a coordinate map according to 14, using a hemispherical antenna cap as a decree the antenna device further comprises an antenna element holder adapted to be mounted on the surface of the antenna cap, an antenna element mounted on said element holder, wherein the position of the antenna element relative to the satellite located in a geostationary orbit is determined by the choice of the installation point of the antenna element on the holder item.