EP0124047A2 - Omnidirectional reception antenna - Google Patents

Abstract

In order to achieve optimum omnidirectional reception of waves of any polarisation from all azimuth and elevation regions while filtering out interference signals from predetermined directions, a rotating cross antenna is connected to a vertical antenna via an adjustable phase shifter and an adjustable attenuator or an adjustable amplifier.

Description

The invention relates to a broadcast antenna according to the preamble of the main claim.

It is known to assemble a turnstile antenna consisting of two crossed horizontal dipoles with a vertical antenna on a mast (antennas HE 002 and HE 001 from Rohde & Schwarz, Radiomentor-Elektronik 1974, issue 10, page 390). The two separate antennas are not electrically interconnected here but can be connected separately to a receiver input depending on the desired reception conditions. However, this known antenna system has a reception possibility from all directions with any polarization.

In recent times, more and more reception systems have been used, particularly for the limit and shortwave range, which make it possible to suppress strong interference signals from certain directions as possible and still enable optimum broadcast reception of signals of any polarization in the rest of the range under all azimuth and elevation angles. The antenna systems customary up to now are not optimally suited for this purpose.

It is therefore an object of the invention to provide a broadcast antenna system that optimally solves this problem.

This object is achieved on the basis of a omnidirectional antenna according to the preamble of the main claim by its characteristic features. An advantageous further development results from the subclaim.

The invention is based on the knowledge that an antenna system known per se, consisting of a horizontal turnstile antenna and a vertical antenna when electrically connecting these two separate antennas, has a spatial hemispherical reception diagram for any polarization and only has a funnel-shaped saddle in a certain elevation in a certain elevation has, namely where the merged output signals of the two antennas are 180 ° out of phase with respect to one another and therefore cancel each other out and in the elevation where the vertical diagram of the turnstile antenna is opposite to the vertical diagram of the rod antenna. Based on this theoretical knowledge, the measure according to the invention of interposing an adjustable phase shifter and an adjustable amplifier or attenuator between the two antenna outputs ensures that this spatial funnel-shaped zero of the spatial hemispherical omnidirectional diagram both in azimuth and in FIG Elevation can be precisely aligned to a possible jamming transmitter and the reception of these jamming signals can thereby be masked out, while the antenna system in the rest of the area has optimal broadcast reception properties for useful signals of any polarization. The azimuth is set here by the phase shifter and the elevation by the amplifier or the attenuator. Both settings are independent of each other, via the intermediate amplifier ker or the attenuator, the size of the received signals of the two antennas can be set separately from one another and in this way the vertical diagram of the vertical antenna and the vertical diagram of the turnstile antenna can be changed independently of one another.

To suppress interference radiation received with a certain polarization, it is known per se to interconnect a horizontal and a vertical dipole via an adjustable phase element and, if appropriate, also via an adjustable amplifier and to control the phase shifter via a control device controlled by the receiver in such a way that the phase shifter the predetermined polarization received radiation is suppressed (GB-PS 2 011 726). The amplifier is controlled in such a way that the amplitude of the two differently polarized dipoles is the same in order to achieve a sharp dip in the radiation diagram for the different polarization and thus for the suppression of the undesired polarization. By using this measure, which is provided for the suppression of differently polarized vibrations, in a known antenna system of the type mentioned at the outset, an omnidirectional antenna for the optimal reception of signals of any polarization and the optimal suppression of interference radiation incident from any direction and elevation is created, i.e. one Antenna system that optimally solves the task mentioned at the beginning.

The invention is explained below with reference to schematic drawings of an embodiment.

FIG. 1 shows the basic circuit diagram of an omnidirectional receiving antenna according to the invention, consisting of an active turnstile antenna 1 and a vertical active rod antenna 2. The turnstile antenna consists of two horizontal dipoles 3 and 4 crossed at 90 °, which are arranged in one plane for reasons of clarity in the figure are shown, but in reality they are arranged spatially crossed horizontally above the floor. The outputs of the two horizontal dipoles 3 and 4 are connected in a known manner via a phase shifter 5 at 90 ^0- phase shift and to the input of a receiver. 6 The output of the rod antenna 2 is also connected to the input of the receiver 6 via an adjustable phase shifter 7 and an adjustable amplifier 8 or an adjustable attenuator. The received signal of the turnstile antenna 1 receives a phase shift within the turnstile antenna which is proportional to the azimuth angle of the incident wave. In contrast, the rod antenna 2 generates a reception voltage at its output, the phase of which is independent of the azimuth angle of the received wave. If the phase of a specific signal received via antenna 2 is 180 ° out of phase with the signal of the turnstile antenna received from a specific direction, this signal is extinguished if the amplitude is equal. The phase shifter 7 can thus be used for any azimuth angle to extinguish the rich direction received signals are set, for all other azimuth directions, however, the antenna according to the invention has optimal reception properties, since for other azimuth angles of the turnstile antenna there is a phase shift deviating from 180 ° with respect to the signal of the rod antenna and the signals therefore do not cancel each other out. In this way, an interference signal incident from a specific azimuth angle can be suppressed and the antenna according to the invention then receives the useful signals incident from other directions only with optimal properties.

The phase shifter 7 could of course just as well be arranged in the connecting line between the turnstile antenna 1 and the interconnection point of the two antennas; the only important thing is that a relative phase shift between the output signals of the antennas 1 and 2 can be set. Instead of the rod antenna 2, which is excited asymmetrically with respect to the bottom 9, a symmetrical vertical dipole could also be used.

The vertical diagram of the turnstile antenna 1 is just opposite to the vertical diagram of the rod antenna 2, as shown in FIG. By damping or amplifying the output voltage of one of the two antennas 1 or 2, the zero 10 of the radiation diagram can be pivoted in elevation independently of the azimuth, as is indicated schematically by dashed lines for a corresponding damping of the vertical diagram of the two antennas 1 and 2 in FIG and whereby the zero 10 of the elevation between the angular ranges 11, 12 and 13 can be changed. This can be achieved by the additionally provided adjustable amplifier 8 or an appropriately adjustable attenuator, which in turn could just as well be arranged in the feed line to the turnstile antenna 1. That can also do that Vertical diagram optimally aligned to the suppression of an interfering signal, which is particularly important in the shortwave range. With the adjustable attenuator or amplifier 8, differences between the two receive voltages of the antennas 1 and 2 can also be compensated for, which result from the polarization of the received waves.

The phase shifter 7 or the device 8 for influencing the amplitude of the received signals can either be installed directly at the base of the antennas 1 or 2, but they can also be accommodated in remote devices, for example in the receiver 6 or in the feed line thereto, but before the interconnection point of the Antennas 1 and 2. The latter is advantageous, for example, for retrofitting an existing antenna system or when several receivers are connected to a common antenna system.

The phase shift or adjustment of the damping or amplification can be carried out by the user by hand, but automation is also possible if appropriate criteria for

Suppression of corresponding interference signals are present. It is thus possible, for example, to automatically control the phase shifter 7 and / or the adjustable amplifier or the adjustable attenuator 8 by means of a suitable control circuit 14, depending on the received signal, so that a specific interference signal is masked out. becomes. All that is necessary is that, for example electronically all the azimuth and elevation angle range from e ^g-examined. Interference signals can be masked out in a particularly simple manner if the useful signal transmitter also emits a corresponding identifier, so that the control circuit 14 can distinguish between useful signals and interference signals.

Claims (2)

1.Radio receiving antenna with a turnstile antenna consisting of at least two crossed horizontal dipoles and a vertical antenna, characterized in that the outputs of the two antennas (1, 2) via an adjustable phase shifter (7) and an adjustable attenuator and / or an adjustable amplifier ( 8) are interconnected. 2. Antenna according to claim 1, characterized in that the adjustable phase shifter (7) and / or the attenuator or the amplifier (8) is automatically adjustable via a control circuit (14) controlled as a function of the received signal.

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