DE1616261B1 - Antenna made of two identical waveguide structures, a third waveguide structure and a connection dipole - Google Patents

Description

The invention relates to an antenna that is preferential .groß that the effective surfaces of the waveguide

wise to television reception in the UHF areas do not cover structures.

(470-790MHz) is used. It consists of two equal For two individual dipoles, the most favorable distance is Wenenleitstrakturen, whose longitudinal center lines little-: from this point of view 0.75 λ. For two YAGI least in the receive direction perpendicular 5 antennas provide antenna through a duct to a two-level for the lowest frequency of the reception connected sihd _s is the best drool eich at least a distance of approximately stand between the two planes about 1, 2 λ (A-controllers have half the wavelength of each other, one drive wavelength).

third waveguide structure, which is roughly in the If now that of the waveguide structures on-center is arranged between the first two that to taken power not via lines, but

the three longitudinal axes of the waveguide structures in. through radiation coupling to the connection dipole

are on one level and are led through a line, the distances between the

Connection dipole connected to the receiver, which may be much smaller in individual waveguide structures,

a small distance from the reference point because otherwise the coupling is too weak. The Comfangsrichtung rear end of the middle whites between these two opposing demands

lenleitstruktur is attached. wrestling, which in the known antenna leads to an un-

An antenna of this type is known by which has resulted is due to the satisfactory result

German utility model letter 1879: 120. The three invention has been vastly improved in that

Waveguide structures of this antenna have the two outer waveguide structures in the rich longitudinal center lines (Longitudinal axes that are mutually par- 20 20 to the received transmitter considerably over the

are allele. The elements of the waveguide structures are shortened central protrusions. The one to be paired

matched in half-wave resonance, for the reception necessary small distance between the waveguide

direction of vertical rod-shaped dipoles (half-wave structures are only possible in part of the entire

directors), which belong to the level of the longitudinal center of the. Antennae length present, while the front parts three waveguide structures are perpendicular. _ Behind 25 of the outer waveguide structures there is a larger

the connection dipole is still a reflector screen in front of each other. .

brought out of several parallel to the directors because the height of the effective area and thus the desired

lelen bars. Such an antenna is of the remarkable distance of the waveguide structures from-

Applicant of the utility model also produced each other with the length of the waveguide structures and been expelled. It is assumed for reception, and increases with the one according to the invention

zen UHF ranges (470-790 MHz). Your Ge Measure achievable increase in profit with the

According to the manufacturer's catalog, winn is the length of the outer waveguide structures. From it

only about 1 dB higher than the gain of an advantageous embodiment of the invention

YAGI antenna of the same length, the same antenna according to the invention, which consists of the fact that it is listed for the manufacturer's catalog. This ₃₅ the lowest frequency of the reception range

YAGI antenna corresponds in its effort and both external waveguide structures at least so

in their manufacturing cost of the j are quite _precisely g as two wavelengths, and the mean

Antenna according to the given Gm, if the waveguide structure is at most as long as three half

the additional waveguide structures omitted wavelengths. It has also proven to be beneficial. 40 showed that the central waveguide structure

The gain increase of around 1 dB is proportional. protrudes so far beyond the two outer ones, Because of the effort and cost of the two, the middle waveguide structure roughly corresponds to its additional waveguide structures low. It is half the length between the two outer ones. All Finding the problem is solved, an antenna, preferential voltages, which in some way to instruct to get to the television reception in the HEJF areas 4.5 shot dipole and be added there to create, with less effort, have a phase position that is as similar as possible, so that the ßer gain growth compared to a YAGI-An sum voltage and thus the antenna gain antenna with approximately the same length in the receiving direction should be as large as possible. Through a waveguide structure tion is achieved. _- - - '_- - a wave is led to the connection dipole. the

The invention consists in the fact that with an antenna 50 the propagation speed ν of this wave on the

of the type described above, the mean waveguide structure is smaller than in free space

guide structure is shorter than the two outer and (speed of light c). The ratio v / c is called

this is referred to in the direction of the received transmitter via relative phase velocity. To the

the middle stick out. _ mentioned requirement for phase equality of the

Numerous tests have led to the result that the voltages obtained in the connection dipole are as close as possible to the fact that _{fulfilling the requirements in the cited Gm document be g Ut} , it has proven to be advantageous that the written antenna can thereby be significantly improved relative phase velocity of the mean waves that the central waveguide structure to make the conductive structure smaller than that of the outer, large 'part is omitted. The gain in connection is increased by this measure if the antenna according to the invention easily reaches the elements of the waveguide structures in a suitable manner by arranging those adjacent to the connection dipole. Elements of the middle waveguide structure from one

This surprising fact allows the other to have smaller distances than the elements of

explain the following considerations: outer waveguide structures.

So that two waveguide structures have one as possible 65 A simple and inexpensive structure of the invention Power from the wave field of the received antenna according to this results from the fact that the WeI transmitter and the antenna gain possible grows up, you must be mutual. Distance so - axes) that are parallel to each other. From the

Explanations of the distances between the waveguide structures result that it can also be advantageous to allow the distance between the longitudinal center lines of the two outer waveguide structures to increase at least over part of their length in the direction of the received transmitter. The same elements are suitable for the waveguide structures of the antenna according to the invention as for the known antenna described, namely rod-shaped dipoles (half-wave directors) which are tuned in half-wave resonance and perpendicular to the receiving direction and which are perpendicular to the plane of the longitudinal center lines of the three waveguide structures. But it can also be used all known types of waveguide structures that z. B. in an article in the communications journal (NTZ), 1959, issue 10, pages 501 to 508 are described. Particularly advantageous in their relationship between efficiency and effort or costs are two coaxial half-wave directors, which are equiaxed to the plane of the longitudinal center line of the waveguide structures and whose distance from one another is equal to a small fraction of the wavelength for all frequencies of the receiving range (full-wave directors) as elements of the waveguide structures.

In an advantageous structural embodiment of the antenna according to the invention, each element is the outer waveguide structures with their own support on a longitudinal beam of the central waveguide structure attached. Another advantageous embodiment is that the elements of the outer Waveguide structures are each attached to a longitudinal beam, which is supported by supports on the longitudinal beam the middle waveguide structure is attached.

All known types of connection dipoles can be used for the antenna according to the invention will. However, a connection dipole that is tuned to full-wave resonance is particularly advantageous Dipole with halves acting over a large area (broadband dipole).

To absorb unwanted waves from the rear relative to the receiving direction Television reception antennas with a reflector arrangement are to be used to suppress half-plane as far as possible fitted. All known reflector arrangements can also be used with the antenna according to the invention be used. It is particularly advantageous to be behind the connection dipole as seen from the transmitter to attach a surface reflector, its lying parallel to the longitudinal axis of the receiving dipole Width greater than the length of the receiving dipole and its total height at least as large is like the greatest distance between the longitudinal center lines of the outer waveguide structures.

The figures show two exemplary embodiments of the antenna according to the invention.

In the antenna shown in Fig. 1, a support bracket 3 is attached to a longitudinal member 1 with suitable fastening clips 2, which with a Clamp 4 is attached to a vertical standpipe 5. At one end of the side member 1 is located a reflector screen, which consists of two coves 6 protruding obliquely from the side member 1, on which one Row of reflector rods 7 are attached. To attach the hatchet 6 to the side member 1 is used Holder S.

Furthermore, the longitudinal beam 1, a connection box 8 is mounted α of insulating material, on which the two of two V-shaped rods arranged halves 9 formed of a Breitbanddipols are attached. The broadband dipole 9 is tuned in full-wave resonance. The reflector rods 7 are parallel to the axis of the broadband dipole 9 and are longer than this.

A coupling radiator 10 , which is tuned in half-wave resonance, is provided in front of the broadband dipole 9 on the longitudinal member 1 in relation to the reception direction. This is followed by pairs of half-wave directors 11 and 12 which are each fastened to the longitudinal member 1 by an insulating part 13 at a small distance from one another compared to the operating wavelength (full-wave directors). The distances between the full-wave directors 11/12, which form the central waveguide structure of the antenna, are initially small and increase in the direction of reception.

At the front part of the longitudinal girder-1 there are no full-wave directors of the central waveguide structure. Vertical supports 15 and 16 are also attached to the side member 1, at the ends of which a full-wave director 17 or 18 with an insulator 19 or 20 is attached. The full-wave directors 17 all lie in a plane which is parallel to the plane of the central waveguide structure and form the upper waveguide structure of the antenna. Likewise, the full-wave directors 18 lie in a plane parallel to the other full-wave directors. They form the lower waveguide structure of the antenna. The two outer waveguide structures protrude beyond the central waveguide structure in the receiving direction. The embodiment according to FIG. 2 differs from the exemplary embodiment in FIG. 1 only in a few structural details. All parts of the two antennas that correspond to one another are denoted by the same reference numerals. The full-wave dipoles 17 of the upper waveguide structure are each attached with an insulator 19 to a longitudinal beam 21, which is attached to the central longitudinal beam 1 with two supports 22. Likewise, the full- wave dipoles 18 of the lower waveguide structure with insulators 20 are attached to a longitudinal beam 23, which is attached to the central longitudinal beam 1 with two supports 24. To attach the antenna to a standpipe 5, a support bracket 25 is provided, one end of which is fastened with a clamp 2 on the longitudinal beam 1 and the other end with a clamp 2 on the longitudinal beam 23 of the lower waveguide structure.

Claims (12)

Patent claims: 1. Antenna, preferably for TV reception in the UHF ranges (470-790 MHz), consisting from two identical waveguide structures whose Longitudinal center lines at least in one direction to the receiving direction vertical plane for the lowest frequency of the reception area at least a distance of approximately half a wavelength from each other, a third Waveguide structure, which is arranged approximately in the middle between the first two, that the three longitudinal axes of the waveguide structures lie in one plane, and one through a line connected to the receiver dipole at a short distance from the, attached to the rear end of the central waveguide structure in relation to the receiving direction is characterized by the fact that the mean control structure is shorter than the two outer and these protrude beyond the middle in the direction of the received transmitter. 2. Antenna according spoke 1, characterized in that for the lowest frequency of the Reception area, the two outer waveguide structures are at least as long as two Wavelengths and the middle waveguide structure is at most as long as three half wavelengths. 3. Antenna according to claim 1 and 2, characterized in that the central waveguide structure is about half its length between the two outer ones. 4. Antenna according to claim 1 to 3, characterized in that the adjacent to the connection dipole Elements of the central waveguide structure are spaced from one another less than the elements of the outer pulp structures. 5. Antenna according to claim 1 to 4, characterized in that that the three waveguide structures have straight longitudinal center lines (longitudinal axes), who are paired to each other. 6. Antenna according to Claim 1 to 4, characterized in that the longitudinal center lines of the two outer waveguide structures are spaced apart from one another at least over part of their length in the direction of the received transmitter. 7. Antenna according to claim 1 to 6, characterized in that the elements of the waveguide structures tuned in half-wave resonance, rod-shaped, perpendicular to the receiving direction Dipoles (half-wave directors) are leading to the plane the longitudinal center lines of the three guide structures are perpendicular. 8, antenna according to claim 1 to 7, characterized in that the elements of the wave guide structures Each of two equiaxed lines to the plane of the longitudinal center lines of the guide structures vertical half-wave directors exist, their distance from each other for all frequencies of the reception area is equal to a small fraction of the length of the area (whole area directors). 9. Antennas according to claim 1 to 8, characterized in that each element of the outer Waveguide structures with their own support on a longitudinal beam of the central waveguide structure is attached. 10 * antenna according to claim i to 8, characterized characterized in that the elements of the outer guide structures are each attached to a longitudinal beam are attached, which is attached to the longitudinal beam of the central guide structure by supports. 11. Antenna according to claim 1 to 10, characterized characterized in that a dipole tuned in full resonance as the connecting dipole large-area acting skins (broadband dipole) is provided. 12. Antenna according to claim 1 to ll ·, characterized characterized in that, seen from the transmitter, a surface reflector is attached behind the connection dipole is, whose paraüel to the longitudinal axis of the receiving dipole lying width is greater than the Length of the receiving dipole and its total height is at least as large as the largest ab * stand. of the longitudinal center lines of the outer guide structures. 1 sheet of drawings