DE1042674B - Rotary beacon antenna with improved vertical radiation - Google Patents

Description

The invention relates to an antenna for rotary radio beacons, which have a multi-leaf, with a fundamental frequency and emits one or more harmonics of this frequency rotating radiation pattern, such as z. B. the system for radio navigation that has become known under the name Tacan. The degree of straightening accuracy Such rotary radio beacons are largely of the same quality as the directional diagram of the antenna system addicted. As a result of the rotation of the multi-leaf diagram appears on a distant receiver the received radio frequency energy corresponding to the fundamental frequency of rotation and harmonics amplitude modulated. The beacon also sends out reference signals in all directions with the voltages derived from the modulation envelope are compared with regard to their phase. Through this the azimuth of the receiving station in relation to the beacon is determined in a known manner.

Most of the rotating antennas previously used for navigation purposes were powered by Sliding contacts supplied, which are difficult to protect against the rigors of the weather.

There are also antenna systems known and proposed in which parasitic radiators around a center radiator that z. B. can be designed as a multi-level cone antenna, rotate and so one generate rotating diagram.

The antenna systems for Tacan stations are vertical radiator arrangements that are made in a known manner are arranged one above the other in several levels for the purpose of vertical bundling. The dipoles can be vertical single dipoles, single or double cone emitters. Assuming all Radiator elements have the same input impedance, all vertically stacked dipoles will have Energy of a certain phase fed. However, it has been found in practice that due to the supply lines of different lengths for the top or bottom radiator element, the whole antenna became frequency sensitive, d. H. the phase for the supply, which has been defined once for a specific frequency the individual dipoles will not stay constant if the frequency is changed even by a small amount will. In addition, it was necessary to lay the feed lines outside the radiation field, to avoid disturbing the diagram.

It has also been observed that with a multilevel arrangement of equally spaced superimposed radiators z. B. cone dipoles, the radiation or the received field strength from a certain elevation angle up to 90 ° above the beacon is too small for one in this The area of the flying aircraft could make a location.

Rotary beacon antenna
with improved vertical radiation

Applicant:

International Standard Electric
Corporation, New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
V. St. v. America November 14, 1955

Gus Stavis, Ossining, N.Y.,

and James S. Engel, Tenafly, N.J. (V. St. A.),

have been named as inventors

It is therefore the object of the invention to provide an improved antenna arrangement for the Tacan radio beacons to create, whose multi-leaf directional diagram spreads up to elevation angles of approximately 90 °.

The rotary radio beacon antenna according to the invention, in which the main radiator of several in the longitudinal direction at the same distance one above the other fed individual radiators and in the parasitic radiators around the main radiator to generate a multi-leaf circular directional diagram rotate, is characterized in that to expand the radiation pattern up to one Elevation angle of approximately 90 ° above the main radiator an auxiliary radiator arrangement - consisting from a powered auxiliary radiator and one between the auxiliary radiator and the main radiator located counterweight - is arranged with a corresponding extension of the parasitic radiator, and the distribution of the transmission energy to the individual radiators of the main radiator and the auxiliary radiator of a central feed point - located within the mast approximately in the middle of the main radiator from too unequal amounts.

In order to avoid a mutual disturbance of the individual corners of the radiation diagram and a certain To ensure ground clearance of the diagram, the distance is used in a further embodiment of the invention the auxiliary radiator arrangement different from the top single radiator of the main radiator, preferably greater than the distance between the individual radiators of the

809 677/245

Main radiators chosen one below the other, and the upper radiator elements of the main radiator are opposite the middle and lower are fed out of phase.

The radiation pattern of the antenna arrangement according to the invention has a pronounced focus of the vertical diagram, due to the associated long range of the radio beacon special value is attached. But it is also the reception field strength up to elevation angles of almost 90 ° large enough for a perfect location to be able to make.

The invention will then be explained in more detail with reference to the drawing.

Fig. 1 shows an embodiment of the antenna arrangement schematically in section; in

2 shows a radiator element of the Tacan antenna in section;

Fig. 3 is a perspective view of the antenna with the parasitic radiators or reflectors, wherein part of the outer cylinder is drawn cut away.

From Fig. 1 and 2 it can be seen that the antenna arrangement consists of a plurality of double cone dipoles ! "to 7, which are arranged vertically one above the other. Fig. 2 is a schematic representation of a Part of the arrangement of FIG. 1. This part of the radiator arrangement contains the main feed point 11. The energy distribution takes place within the central part 8 of the antenna, which is designed as a support mast, and the feed lines of the individual radiator elements consist of coaxial, alternately fed line pieces, as will be explained in more detail below. This type of supply reduces the phase shift between the antenna elements and causes a constant radiation pattern over the entire frequency range in question. Naturally, there are impedance transformers at the feed points intended. The lower six radiator elements 1 to 6 are equidistant from one another arranged and represent the main radiator. To raise the vertical diagram or, with In other words, to achieve a radiation from a small elevation angle from the horizontal, the individual radiator elements 1 to 6 are fed in phases such that the lower Elements 1 and 2 with respect to the middle elements 3 and 4 in the same phase, the upper elements 5 and 6 on the other hand, be excited out of phase with respect to the mean in such a way that the diagram opposite the horizontal is raised by a small angle. The top radiator element 7 is in another, preferably arranged at a greater distance from the uppermost main radiator element than the radiator elements 1 to 6 below each other. This is done for the reason in order to also have a good radiation after larger ones To get elevation angles. The dipole 7 works together with the counterweight 9, which is arranged between the dipoles 6 and 7. The element 7 is fed with the same power as the element 3 and 4 and carries due to the larger distance and the phase-shifted supply also helps to raise the vertical radiation pattern.

In order to supply the feed energy to the individual dipoles, the main feed line 8 is connected to the Inner conductor 8 & and the outer conductor 8σ- initially the central feed point 11, where the distribution by means of a distribution network to the others Single radiator takes place.

The distribution network also contains matching transformers for each radiator element, however this is not shown in the figure because of the clarity of the representation.

At the main feed point 11, the entire energy is first divided into two parts. The first Part, about twenty-three of a total of 37 parts, is fed to a further feed point 12 via the Line 8 c supplied, which now acts as an inner conductor in conjunction with the outer conductor 13 as a coaxial line piece. The energy share of about 23 parts At the feed point 12 it is again divided into two amounts of about 18 parts and 5 parts. the 18 parts of the energy are fed to the feed point 14 via a coaxial line piece with the inner conductor 13 and fed to the outer conductor 15. The energy at the feed point 14 is now divided equally, i. H. ever 9 parts, the antenna elements 3 and 4 fed. The remaining 5 parts at feed point 12 are used for Feed point 16, where the cone dipole 1 with one part and the cone dipole 2 with four parts of the Energy to be excited.

The remaining 14 parts of the energy are fed from the central feed point 11 to the feed point 17, from where 9 parts are fed to the double cone 7 and another 5 units are fed to the feed point 18. At This is in turn divided the energy so that 4 units the radiator element 5 and 1 unit the Feed the radiator element 6. Experience has shown that with an energy distribution according to the scheme 1-4-9-9-4-1 on the individual radiator units of the antenna system unwanted side lobes of the radiation do not occur. To increase the radiation characteristics of the antenna system relative to the horizontal, the dipoles 1 and 2 are in phase, and the dipoles 5, 6 and 7 are correspondingly out of phase with the radiators 3 and 4 excited.

The radiator element 7 is to improve the radiation in the vertical direction in the antenna system inserted. The radiator element 7 works together with the counterweight 9, which between the radiator elements 6 and 7 is arranged. The element 7 is energized with 9 energy units and contributes to raising the radiation pattern, as it is out of phase with elements 3 and 4 is fed. The counterweight 9 shields the radiation from the elements 1 to 6 from above, and therefore the radiation originates at large elevation angles up to about 90 ° from the horizontal in the Mainly from the radiator element 7.

The antenna gain of such an antenna compared to a simple dipole is about S db, and the The main angle of radiation is around 5 ° from the horizontal. In this way, incorrect measurements are also avoided of the azimuth, which can be traced back to reflections of the energy on buildings or masts, largely avoided. As a result of the vertical arrangement of the main radiators 1 to 6 and as a result of the greater distance of the top radiator element 7 from the last radiator element 6 of the main radiator a larger proportion of the radiation is emitted in the vertical direction than would be the case without this radiator element 7 would be the case. In this way, an aircraft flying over the beacon can practically without Interrupt the location.

In Fig. 3 is an embodiment of a Tacafl antenna drawn in perspective view. The lower component 19 contains the generators for the reference pulses and the drive means for the antenna

system. The multi-level arrangement of the radiator elements is located within a housing made of fiberglass or other insulating material. To generate the main radiation sheet, a resistance wire is mounted as a parasitic radiator 21 on a non-conductive cylinder 22 which rotates around the central radiator 20. To generate the secondary radiation leaves or, in other words, the harmonic of the fundamental frequency of the rotation, a plurality of parasitic radiators (not shown) are mounted on a second cylinder made of insulating material 23, which is concentric to the central radiator and at a greater distance than the first cylinder . Both cylinders 22 and 23 rotate synchronously around the central radiator. In order to ensure the desired radiation characteristic, the metal plates 24 and 25 are also provided as counterweights or shielding plates, which act in a similar way to the counterweight 9 in FIG. 1.

Claims (6)

20 patent claims: 1. Rotary radio beacon antenna, in which the main radiator consists of several fed individual radiators arranged longitudinally at the same distance above one another and in which parasitic radiators rotate around the main radiator to generate a multi-leaf circumferential directional diagram, characterized in that to expand the radiation diagram up to an elevation angle of approximately 90 ° above the main radiator an auxiliary radiator arrangement · - ■ consisting of a powered auxiliary radiator and a counterweight located between the auxiliary radiator and the main radiator - with a corresponding extension of the parasitic radiator is arranged and the distribution of the transmission energy to the individual radiators of the main radiator and the auxiliary radiator by one - ■ The central feed point, located approximately in the middle of the main radiator within the support mast, is made from too unequal amounts. 2. Antenna arrangement according to claim 1, characterized in that the distance between the auxiliary radiator arrangement different from the top individual radiator of the main radiator, preferably greater than the distance between the individual radiators of the main radiator is dimensioned among each other. 3. Antenna arrangement according to claim 1, characterized in that the feed line through the support mast itself and formed by a conductor laid concentrically within the support mast is. 4. Antenna arrangement according to claim 1, characterized in that the energy distribution, seen from the two central individual radiators, on both sides in a ratio of 9: 4: 1 and that the auxiliary radiator is fed with 9 energy components. 5. Antenna arrangement according to claim 1, characterized in that the feed lines to the individual radiators are formed by nested concentric lines. 6. Antenna arrangement according to claim 1 or one of the following claims, characterized in that that the radiator elements are concentric double-cone radiators. 1 sheet of drawings © 809 677/245 10.58