DE2138697C3 - Horizontally polarized sector or omnidirectional antenna - Google Patents

Description

There are horizontally polarized round beam antennas or sector beam antennas radiating only in one sector of the horizontal plane known, which consist of two or more directional beam fields arranged perpendicular to each other in a square around the mast axis ("News from Rohde &Schwarz" June / July 1970, p. 29), Each directional beam field consists of several dipole-reflector units arranged vertically one above the other, each of these units being rebuilt from a reflector and at least one dipole arranged in front of it. The horizontal diagram of these antennas, which are used, for example, as television transmission antennas, is mostly pointed relatively sharply due to disruptive interference, especially in the area of the bisector between the directional beam fields. 9 shows such a strongly pointed horizontal diagram I of a known omnidirectional antenna with four directional beam fields distributed around the mast. It follows from this that, for example, at a horizontal angle ψ = 21 °, a strong dip occurs due to vectorial subtraction of the radiation components. This relatively strong dip in the horizontal diagram also occurs when the known rotating field phase feed is used with the directional beam fields offset in the direction of the bisector (Rohde & Schwarz Mitteilungen No. 9, November 1957, pp. 86-95 and DE- PS 10 24 587). It is also known to rotate the individual directional beam fields against each other by 90 ° and to no longer arrange the mast as a square support mast in the middle of the directional beam fields, but to design it as a crossed mast, on whose mast parts protruding radially outward from the mast axis the by 90 ° ° mutually twisted directional beam fields are attached (FR-PS 13 87 182). This should make it possible to produce the necessary smallest possible distance between the source points of the directional beam fields, even with antennas for higher frequencies, and still achieve sufficient mast stability. With this known arrangement, too, a strong peaking of the horizontal diagram is to be expected, especially since there is also the fact that the mast wall or the reflector of the adjacent beam fields comes to lie in the direction of emission directly next to each individual beam field and thus a considerable disturbance of the beam diagram of each individual beam field is to be feared.

It is the object of the invention to design an antenna of the type mentioned in the preamble of claim 1 in such a way that that an annoying peaking is largely eliminated in their horizontal diagram.

This task is based on an antenna according to the invention according to the preamble of the main claim solved by the characterizing features of this main claim. Further advantageous refinements of the antenna according to the invention emerge from the subclaims.

The invention makes use of the knowledge that the penetrating dipole reflector units as long as they cannot influence each other and cause no disruptive interference than the Dipoles are perpendicular to each other. As long as this requirement is met, it is possible to use the Source points of the individual DipoUReflektor = units to be arranged closer together with respect to the common mast axis than in the known arrangement gen was possible. In this way, deep depressions in the horizontal diagram are as great as possible reduced, as shown in diagram II according to FIG. 9 shows for an antenna according to the invention and according to what only slight dips of about -2 dB

or less occur. An ideal omnidirectional diagram with practically no dip at all would be achieved if the source points of the perpendicular dipole reflector units would cherish directly on the mast axis. However, this is practically not feasible and the optimal conditions are therefore ideally achieved when opposing reflectors are directly next to one another with the back and no mast is provided in the middle.

The invention is explained in more detail below with the aid of schematic drawings of exemplary embodiments explained

The F i g. 1, 3, 5 and 7 show the side views, respectively an omnidirectional antenna according to the invention. For the sake of simplicity, only two are vertical here Dipole reflector units lying on top of one another are shown for each directional beam field

The F i g. 2, 4, 6 and 8 show the associated ones, respectively Floor plans.

The omnidirectional antenna according to the invention according to FIGS. 1 and 2 consists of four directional beam fields arranged symmetrically around the vertical axis of a mast. Each directional beam field consists of several dipole reflector units arranged vertically one above the other. The dipoles D of each unit are at a distance of about 0.25 A to the associated reflector R mounted on supports 5 The length of the dipoles D, its aspect ratio and the horizontal width Aedes reflector R in a known manner according to the desired half-value width is preferably 50%, selected. In the exemplary embodiment shown, the dipoles D are shortened full-wave dipoles of approximately 0.7 to 0.9λ in length. The vertical height H of each reflector R is selected approximately between 0.25 and 0.45 A. The horizontal width B of each reflector R is selected approximately between 0.5 and 1.5 λ, in the embodiment shown between A and 1.3 A . The individual dipoles D of each directional beam field are at a mutual vertical distance of about 0.52 to 0.92 λ angeorunet The gap Z between vertically superposed reflectors R each directional beam field is in the shown embodiment, so that about 0.27 to 0.45 a high.

The individual reflectors R with the associated dipoles D of the mutually perpendicular directional beam fields are vertically offset from one another and so nested in one another that the center points of the dipoles, i.e. the source points, of the individual dipole-reflector units, are on a radius r with respect to the mast axis A. come to lie, which is significantly smaller than half the width B of the reflectors R and preferably also smaller than the length of the dipoles D. In the embodiment shown, this radius r is only 038 A large. The reflectors R of one directional beam field therefore cross the reflector plane of the other directional beam field in the gaps Z , the same applies to the dipoles U, as is the case with the top view of FIG. 2 shows. In the example shown, the reflectors R are moved together to a mutual distance of 0.2 A.

With such an omnidirectional antenna, an omnidirectional diagram II according to FIG. 9 can be achieved in which the dip is not greater than 2 dB.

F i g. 3 and 4 show a further embodiment

an omnidirectional antenna according to the invention, in addition to that provided according to the invention Crossing of the individual dipole reflector units also the known rotating field phase supply mentioned at the beginning applied

In the embodiment according to FIGS. 5 and 6, the reflectors R 1 of one of the opposite directional beam fields are shifted further inward in the direction of the common mast axis A than the reflectors R 2 of the other directional beam fields perpendicular thereto. The source points of the dipoles D 1 lie on a radius r = 0.3 A, while the source points of the dipoles D 2 lie on a radius r = 0.65 A. Nevertheless, in this omnidirectional antenna, too, the individual reflectors Λ 1 and R 2 penetrate and intersect, and omnidirectional diagrams with minimal indentations are thus also achieved. > .r, although the dipoles D ί and D 2 do not cross here.

With this arrangement according to FIGS. 5 and 6, the dipoles Di and D 2 can be fed with a phase difference of 90 ° and nevertheless an in-phase addition of the radiation components is effected along the bisector between the fields so that optimally favorable omnidirectional patterns are achieved.

The F i g. 7 and 8 finally show an embodiment in which the ends of the reflectors of one directional beam field are used directly as supports for the dipoles of the directional beam field that is perpendicular thereto. The ends of the reflectors A3 and A4 are rounded or beveled, narrowing sheets and the dipoles D 4 are attached directly to the ends of the reflectors / 3 and the dipoles D 3 to the ends of the reflectors A4. Here, too, the individual reflectors R 3 and RA cross again, as shown in the top view according to FIG. 8 shows the mutual spacing of the individual reflectors R 4 and R 3 is 0.5 A in the exemplary embodiment shown and the source points of the dipoles lie on a radius r = 0.52 A.

The feeding of the dipoles in the illustrated embodiments can either be in a known manner via symmetrical lines, which are fed in the middle of the dipoles, or via coaxial feed lines in the supports (hollow arm feed).

All other known feed arrangements can also be used. The reflectors can be made of metal sheets or grids. It is advantageous, in the sense of FIG. 1, to design the individual reflectors / "the dipole reflector units" -. I of a field in the middle via webs T so that individual fields with reflectors provided between the dipoles - Incisions arise, which are then fixed in place on the mast in the proposed mutual vertical offset and interlocking within the meaning of the invention.

In addition 5 sheets of drawings

Claims (10)

Patent claims: 1. Horizontally polarized sector or omnidirectional antenna with at least two, in particular four, directional beam fields arranged perpendicular to each other in a square around the mast axis, each consisting of several vertically stacked units consisting of a reflector and at least one dipole arranged in front of it, characterized in that m in each case at least one of horizontally adjacent dipole reflector units has moved so close to the mast axis (A) that the reflectors (R) of these adjacent units cross in plan. 2. Antenna according to claim 1, characterized in that the horizontally adjacent units are additionally arranged vertically offset from one another. 3. Antenna according to claim 2, characterized in that the units of a directional beam field each in the middle between the units of the adjacent directional beam field, which is perpendicular to it lie. 4. Antenna according to one of claims 2 or 3, characterized in that both horizontally adjacent units are pressed so close to the mast axis (A) that not only the reflectors (R), but also the dipoles (D) of this Cross units in plan. 5. Antenna according to one of claims 1 to 4, characterized in that at least some reflectors (R) of the Dipc'-Reflei <or units of a directional beam field are combined to form a coherent reflector surface (connecting web T). 6. Antenna according to one of claims 1 to 5, characterized in that the dipoles (D) from the mast axis (A) have a distance (r) which is equal to or less than half the horizontal width (B) * o of the reflector (R). 7. Antenna according to one of claims 1 to 6, characterized in that the vertical height (H) of the reflector (R) of each unit is chosen not to be greater than half the vertical distance between vertically successive dipoles (D) of the directional beam field. 8. Antenna according to one of claims 2 to 7, characterized in that the dipoles (D) from the mast axis (A) have a distance (r) which is smaller than half the length of the dipoles (D). 9. Antenna according to claim 1, characterized in that the dipoles (D 3, D 4) of one unit are attached directly to the ends of the reflector (R 3, R 4) of the adjacent unit lying in the same horizontal plane (F i g. 7 and 8). 10. Antenna according to claim 9, characterized in that the vertical height (H) aer reflectors (R 3, R 4) decreases towards the dipole attachment points (Fig. 7).