DE2150660A1 - Cross dipole antenna - Google Patents

Description

Dipl. -Phys. Leo Thul 2 1 5 U 6 Q U

Patent attorney
7 Stuttgart 3 ο
Short street 8

W. M. Spanos - 9

INTERNATIONAL STANDARD ELECTRIC CORPORATION, NEW YORK

Cross dipole antenna

The invention relates to a transceiver cross dipole antenna for radio communications and / or radio navigation. Because only a limited space for mounting the antennas in aircraft Is available and because an increasing number of antennas with radiators is required for a wide variety of tasks there is more and more about developing compact multi-purpose spotlights that can fulfill more than one function. It is Z. B. at Mobile stations require that radio communications and radio navigation are carried out simultaneously next to one another, either on different ones Frequency bands or on the same frequency band. The required antenna properties with regard to the The radiation diagram and the polarization are usually different. The advent of radio and navigation systems using satellites work together, has the development of common multi-purpose

antennas complicated because the requirements for the 4th lo. 1971

vo / ff

209816 / U36

Radiation diagram and polarization differ from the requirements distinguish between quasi-optical ground-to-ground and ground-to-board radio links. Satellite systems require circular polarization and an omnidirectional diagram of traffic with the ground station.

With the invention, a crossed dipole antenna is to be created as a multi-purpose antenna that can be used in satellite systems, quasi-optical communications and navigation systems. This is achieved according to the invention is that polarized to produce at the same W temporarily existing vertically and / or left-handed and right-handed circularly polarized omnidirectional charts four perpendicularly arranged in a square coaxial cable are provided, which are surrounded by a frustoconical upper whose smaller diameter The end of the coaxial cable is arranged and which is mechanically and electrically connected to the outer conductors of the coaxial cables, that the inner conductors of the coaxial cables protrude beyond the upper end of the truncated cone jacket and are bent at a certain angle to the axis of the jacket and that the four coaxial cables are simultaneously
Signals are excitable.

Coaxial cables simultaneously and / or with each phase shifted by 9o

The invention is explained in more detail with reference to the drawings of an execution example. Show it:

1 shows a perspective view of the crossed dipole antenna and a block diagram the antenna feed circuit,

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209816 / U35

W. M. Spanos - 9

FIG. 2 shows a plan view of the crossed dipole antenna according to FIG. 1,

3 shows the vertical diagram with circular polarization rotating to the left,

Fig. 4 the vertical diagram at right -

rotating circular polarization and

Fig. 5 is the double circle diagram with value polarization.

Some applications of the antenna according to the invention are listed below for explanation.

use

UHF radio link UHF satellite radio link DME / TACAN RSB / IFF

Polarization frequency range

vertical

225-4OO MHz

left-u. clockwise 225-4oo MHz rotating, circular vertical 96o-1125MHz

Radiation diagram

vertical double circle

hemispherical

vertical eighth r double circle

In Figs. 1 and 2 is a crossed dipole antenna with four coaxial cables 1 to 4, the outer conductor being designated by 5 and the inner conductor by 6 in each case. The outer conductor 6 of all Coaxial cables are mechanical and electrical with each other and with a frustoconical jacket 7 at the end 8 with the

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20981 6 / 1A35

smaller diameter connected. The jacket length of the truncated cone jacket 7 is greater than a quarter of the operating wavelength. The inner conductors 6 of the coaxial cables are over the upper end of the truncated cone jacket 7 also extended and form the conductor ends 9, lo, 11 and 12, which represent the dipoles of the crossed dipole antenna. These conductor ends 9 to 12 are each at a certain angle, preferably 9o, bent towards the direction of the associated coaxial cable. These ends of the inner conductors of the four coaxial cables are like this arranged that they are each perpendicular to each other. The truncated cone jacket 7 serves as a reflector. This arrangement the conductor ends 9 to 12 and the truncated cone jacket 7 causes a hemispherical radiation pattern when each of the Coaxial cable pairs are excited with energy that is phase-shifted by 9o from one another or if the truncated cone jacket upon reception 7 and the conductor ends 9 to 12 are excited accordingly. The ladder ends 9 to 12 and the truncated cone jacket 7 is an omnidirectional diagram is achieved that can be circularly polarized both left and right rotating. This cross dipole antenna is therefore suitable for UHF satellite radio links like the one above List can be found.

For vertical polarization with UHF radio links or with DME / TACAN or RSB / IF radio connections, the truncated cone jacket 7 also works as a radiator, like the conductor ends 9 to 12. Each conductor end 9 to 12 is approximately 0.35.D in length of the operating frequency of the antenna, where D is the diameter am corresponds to the lower end of the truncated cone jacket 7 (Fig. 2). Determine the sheath length, the diameter D and the length of the conductor ends the radiation pattern of the antenna. To the desired

20981 6/1435

To obtain a vertically polarized radiation pattern, the coaxial cables 1 to 4 must be fed in phase when transmitting or are excited in phase when receiving.

Fig. 3 shows the hemispherical vertical diagram produced by the left-handed, circularly polarized excitation of the conductor ends 9 to 12 and the jacket 7 is caused. Fig. 4 shows the hemispherical vertical diagram with clockwise, circularly polarized Excitement. Fig. 5 shows the vertical double circle diagram with vertical, polarized excitation.

The switching means belonging to the antenna are also shown in FIG. They are suitable for sending and receiving and exist made up of two 18o fork circuits 13 and 14, a 9o fork circuit and a circuit 16 which divides or divides the energy during transmission. added when receiving.

When transmitting, these switching means work as follows: The transmitter energy with vertical polarization is sent to an input 17 applied to the circuit 16 and fed via this to the in-phase outputs of the 18o fork circuit 13 and 14. The coaxial cable 1 to 4 are therefore excited in phase. This is indicated by the reference sign (+) on the leads leading from these 18o fork circuits 13 and 14 lead to the inner conductors of the coaxial cables 1 to 4, indicated. The in-phase excitation of all coaxial cables is generated by means of the conductor ends 9 to 12 and the jacket 7, the vertical double circle diagram shown in FIG. 5,

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The circularly polarized radiation is transmitted at the same time, namely by being connected to the input 18 of the 9o fork circuit 15 a counter-clockwise circularly polarized signal is applied to input 19 of circuit 15 and a clockwise circularly polarized signal will. This causes the 9o fork circuit to appear on line 2o 15 connects to the 18o fork circuit 13, one around 0 phase-shifted signal for the counterclockwise circular polarization and a signal phase-shifted by 9o for the clockwise Circular polarization. At one output of the 18o fork circuit 13 there is then a 0 phase-shifted signal for the counterclockwise rotation Circular polarization and a 9o phase-shifted signal for clockwise circular polarization are available with which the Coaxial cable 4 is excited. At the other output of the 18o fork circuit 13 there is a signal which is phase shifted by 18o for the counterclockwise rotation and a -9o phase-shifted signal for clockwise circular polarization are available with which the coaxial cable 1 is excited. Just as on line 2o, on line 21 from 9o fork circuit 15 to 18o fork circuit 14 there is a um 9o phase-shifted signal for the left-hand circular polarization and a signal phase-shifted by 0 for the right-hand circular polarization. As a result, at one output of the 18o fork circuit 14 there is a signal phase-shifted by 9o for the counterclockwise and one by 0 phase-shifted signal for the clockwise circular polarization available, with which the coaxial cable 3 is excited. At the other

ο ο

The output of the 18o fork circuit 14 is phase-shifted by -9o Signal for counterclockwise and a phase shifted by 18o signal for clockwise circular polarization available, with which the coaxial cable 2 is excited. The excitation of the four coaxial cables 1 to 4, each with signals shifted by 90 °. causes circularly polarized signals to be emitted by means of the Conductor ends 9 to 12 and the jacket 7.

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209816 / U35

When using the cross dipole antenna as a receiving antenna, the coaxial cables 1 to 4 by means of the conductor ends 9-12 and of the jacket 7 excited with signals with 9o phase shift and the inputs of the 18o fork circuits 13 and 14 are with signals occupied with the phase relationships shown in Fig. 1, namely O and 9o from the coaxial cable 4, 18o and -9o from the coaxial cable 1, 9o and O from the coaxial cable 3 and -9o and 18o from the coaxial cable Then there are output signals at inputs 18 and 19, which are from originate from the left- and right-handed circularly polarized signals. When the antenna picks up vertically polarized radiation, all coaxial cables are excited in phase. This is by the reference symbol (+) at the inputs of the 18o fork circuits 13 and 14 are indicated in FIG. The in-phase signals at the outputs of the 18o fork circuits 13 and 14 are in the Circuit 16 is added and are then present at input 17.

3 claims

Drawings -8-

2098T6 / U35

Claims (3)

Claims , 1.) Transmit / receive cross dipole antenna, especially for the Radio communications and / or radio navigation, characterized in that four vertically standing, square coaxial cables (Ibis4) are provided, W which are surrounded by a frustoconical jacket (7), to generate vertically polarized and / or left and right circularly polarized omnidirectional diagrams , whose small diameter is arranged at the upper end of the coaxial cable and that with the outer conductors (5) of the coaxial cable is mechanically and electrically connected that the inner conductor (6) of the coaxial cable over the upper end of the truncated cone jacket (7) protrude and are bent at a certain angle to the axis of the jacket and that the four coaxial cables simultaneously in phase and / or with each phase shifted by 9ο Signals are excitable. 2. Antenna according to claim 1, characterized in that the w Angle between the bent ends of the conductor (9-12) to the axis of the sheath (7) and between the conductor ends are each 9o. 3. Antenna according to Claim 1 and 2, characterized in that the length of the bent conductor ends (9-12) is equal to l / 4 and the jacket length of the truncated cone jacket (7) is greater than 1/4 of the operating wavelength. 2098 16/1435 Blank page