RU2673451C1 - Method of amplitude direction finding on maximum diagrams of antenna direction - Google Patents

Abstract

FIELD: radar ranging and radio navigation.

SUBSTANCE: invention relates to the field of radio direction finding in which the location of a radio source is determined by antenna devices that do not have a pronounced directivity by changing the antenna pattern in space. Said result is achieved due to the fact that the antenna pattern is scanned with respect to the radiation source, for example, to the right and to the left, while for the direction to the radiation source the line obtained as a result of dividing the scanning sector in half is selected. Direction to the radio emission source is the bearing formed by the angle between the direction to the origin, for example to the north, and the line passing through the center of the antenna and the point dividing the obtained sector of the scanning in half.

EFFECT: increasing the functionality of amplitude direction finders, increasing the accuracy of determining the direction of arrival of radio waves.

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Description

The invention relates to the field of direction finding, radio navigation, and in particular to the area of direction finding, in which the location of the source of radio emission is carried out by antenna devices that do not have a pronounced directivity, by changing the radiation pattern of the antenna in space in order to determine the direction of arrival of radio waves.

There is a method of amplitude direction finding for the maximum radiation pattern of an antenna [1], which consists in the fact that the bearing angle is counted from the direction associated with the reference point, for example, the direction to the north, when the direction to the radiation source corresponds to the maximum level of the received signal.

Along with the obvious advantage associated with the simplicity of its implementation, the method has a significant drawback consisting in the extremely low accuracy of determining the direction of arrival of radio waves, which is due to the flat top of the antenna pattern, for which not a single bearing, but a certain sector of bearings will correspond to the maximum signal level, in which the level of the recorded signal will be the same for any bearing from this sector.

With increasing wavelength, using the same antenna, the width of this sector, as well as the number of bearings on which the maximum signal level is fixed, will increase. Obviously, an increase in this sector will lead to an increase in the error in determining the direction of arrival of radio waves and, as a consequence, to an increase in the error in determining the location of the source of radio emission.

A known method of amplitude direction finding to minimize the antenna radiation pattern [1].

The disadvantages of this method are the difficulty in implementing the method, the complexity in the device of the direction finder, the inability to operate such a direction finder in a wide wavelength range and a sufficiently high error in measuring the minimum audibility of the signal due to an imperfect antenna radiation pattern.

The objective of the invention is to provide a method of amplitude direction finding to the maximum radiation pattern of the antenna, which can significantly increase the functionality of amplitude direction finders, the accuracy of their determination of the direction of arrival of radio waves and, as a result, reduce the error in determining the location of the radio emission source.

This technical result in the proposed method is achieved by the fact that in the direction-finding process, by shifting the radiation pattern of the amplitude direction finder 1, for example to the right and left, relative to the radio emission source 2, the same boundaries 3 of sector 4 are determined, within which the received signal level at both borders 3 takes equal values and decreases by at least 3 dB from the maximum value in the radiation pattern 1 of the scanning antenna located alternately in the leftmost and rightmost positions relative to the radio signal source 2, and then the resulting sector 4 bisect. The direction to the source of radio emission is bearing 5, formed by the angle between the direction of reference 6, for example, to the north, and line 7 passing through the center of the antenna and the point dividing the resulting scanning sector 4 in half, as shown in FIG. one.

As you know, the method of amplitude direction finding for the maximum antenna radiation pattern, in modern interpretation, is significantly inferior in accuracy to the phase method. This is because the accuracy of the method is directly related to the width of the antenna pattern used for direction finding of the source. As a result of direction finding, false bearings may appear within the main lobe of the antenna pattern.

These false readings are determined by the flat portion of the top of the radiation pattern, within which there is no significant change in the level of the received signal at small angular displacements of the antenna pattern relative to the true direction to the radiation source, which, of course, leads to an error in determining the true direction to the radiation source and, as a result, increasing the error in determining the location of the source. At the same time, depending on the wavelength of the direction-finding source of radio emission using the same antenna, the number of false bearings, for example, with increasing wavelength, will only increase, since the antenna radiation pattern width will increase.

In order to compensate for the appearance of false bearings, to increase the accuracy of systems equipped with amplitude direction finders, to reduce the error in determining the location of radio sources in a wide range of wavelengths using the same antenna, the following method is proposed.

To implement the method, it is sufficient to use almost any antenna with a radiation pattern different from circular (spherical), which is also an advantage of the proposed method.

To simplify the implementation of the method, it is proposed to use a parabolic antenna with an aperture of 10 m and an expected beam pattern of 56 degrees. The choice of this antenna is not accidental. It is parabolic antennas of large diameter that contribute to the formation of radiation patterns suitable for implementing the method in a wide range of wavelengths. In the claimed method, the boundaries of the range lie in the range from 30 MHz and above. Obviously, the higher the frequency, the narrower the radiation pattern.

To compensate for the imperfect shape of the antenna radiation pattern, the selected antenna and its radiation pattern can be calibrated using a test radiation source relative to the mechanical antenna rotation system with a rotation angle sensor. Calibration is performed at the frequency that is minimally applicable for the selected antenna, at which the radiation pattern width is maximum, for example, in the embodiment proposed above, 30 MHz.

When a beam is mechanically scanned by a beam relative to a test source, for example, right-left, in 1-s increments, either min or deg, depending on the precision capabilities of the antenna rotation system with a rotation angle sensor, a table of the dependence of the test signal level on the corresponding him the angle of rotation.

Based on the obtained samples, a sector is selected with an equal value of the drops to the left and right sides of the scanned angle relative to the maximum and the width of the obtained sector is determined in seconds, either minutes, or degrees. Then the obtained angle is divided in half and this sample is selected as the optical axis for this radiation pattern and is combined with the zero of the antenna rotation system with the angle sensor.

Thus, it is possible to obtain a wide-range amplitude direction finder, superior in accuracy to the phase direction finder.

It should be noted that the maximum error in determining the direction of arrival of radio waves using this method will depend only on the precision capabilities of the antenna rotation system with the angle sensor.

The proposed method along with the simplicity of its implementation provides a significant increase in the functionality of amplitude direction finders, the accuracy of their determination of the direction of arrival of radio waves and, as a result, can significantly reduce the error in determining the location of the source of radio emission.

A comparative analysis of the essential features of the prototype and the proposed method shows that the claimed invention, due to the fact that for the direction to the radiation source choose a line obtained by dividing in half the scanning sector by the radiation pattern of the antenna relative to the radiation source, for example to the right and left, while the borders of the sector scans are points with an equal decrease in amplitude to a level below 3 dB from the maximum value on the radiation pattern of the scanning antenna located at edno the leftmost and rightmost position relative to the radio signal source provides a technical result consisting in increasing the functionality of the amplitude direction finders, the accuracy of determination of the direction of arrival of radio waves and, consequently, reducing detection error of the radio source location, which was not possible in the prior art.

INFORMATION SOURCES

1. Menshakov Yu.K. Theoretical Foundations of Technical Intelligence: Textbook / Edited by Yu.N. Lavrukhin. - M.: Publishing House of MSTU. N.E. Bauman, 2008 .-- 536 p., P. 71-73.

Claims (1)

The method of amplitude direction finding, which consists in scanning the radiation pattern of the antenna in the direction of the source of radio emission, while the bearing angle is counted from the direction associated with the reference point, when the maximum level of the received signal corresponds to the direction of the radiation source, characterized in that in the process direction-finding directional patterns of the antenna are shifted relative to the source of radio emission, the same boundaries of the scanning sector are determined, within where the received signal level at both borders takes equal values and decreases by at least 3 dB from the maximum value on the radiation pattern of the scanning antenna, then the resulting sector is divided in half, and the direction to the radio source is the bearing formed between the direction taken at the origin, and a line passing through the center of the antenna and a point dividing the resulting scanning sector in half.

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