SU987537A1 - Directional pattern direction determination method - Google Patents

Description

The invention relates to techniques for antenna measurements and can be used to measure the radiation patterns of antennas in enclosed spaces directly on the territory of industrial enterprises.

A known method of measuring the radiation pattern, which consists in measuring the signal at the output of the test antenna at various angles of rotation in the field of a stationary auxiliary antenna located in the far zone of the test [1].

The disadvantage of this method is the need to use special expensive landfills.

There is also a method of determining the antenna radiation pattern, including measuring the signal at the output of the test antenna at various angular positions with respect to the collimator field E ² ] ·

However, the known method does not provide high accuracy of measurements, which is due to the influence of the edge field of the collimator on the antenna under test and is most significantly manifested when testing large antennas, the sizes of which are larger or comparable with the size of ⁵ collimators.

The purpose of the invention is to improve the accuracy of measurements.

To achieve this goal, according to method ₁₀ for determining the antenna pattern, the collimator is successively offset in the plane of its aperture, and for each angular position of the antenna under test, complex amplitudes of the signals at its output are measured at successively shifted positions of the collimator, and the value of the radiation pattern is determined by summing the measured complex 20 amplitudes.

The drawing shows a structural diagram of a device that implements the method.

The device includes a generator 1 connected to a collimator 2 fixed 96 * 7537 4 on the movement mechanism 3, which provides the collimator 2 in the plane of its aperture in two mutually perpendicular directions, the antenna under test 4 is mounted on 5 rotary unit 5, which provides rotation in azimuth and to the elevation angle, the ampliometer 6, the first input of which is connected to the output of the antenna under test 4, and the second input - with the second output 10 of the generator 1, calculator 7, the input of which is connected to the ampliometer 6, and the angle sensor 8 connected to the third the input of the amplifier 6.

The method is implemented as follows / '

For each angle of rotation of the antenna under test 4 ° !, P> (S-azimuth, p elevation angle), the complex amplitudes ed <G <of the signal at the output of the antenna under test 4 are measured at sequentially shifted positions of collimator 2 (-Ϊ = 1.2 ... N, where N is the number of successive biases of the collimator 2). These measurements are carried out for all those angles of OC β> of rotation of the antenna under test 4, for which it is necessary to determine the values of its radiation pattern. Successive displacements of the collimato- _3Q pa 2 are carried out in a plane parallel to its opening. Then, for each angle of rotation of the test antenna 4, the radiation pattern values are determined by summing the measured complex · amplitudes G; (αί,> ^t · ^e ·

1-Ί 4C

Measurements of the complex amplitudes of the signal at the output of the antenna under test 4 for successively shifted positions of the collimator 2 are carried out as many as 45 times so that the total opening at all the indicated positions of the collimator 2 is equal to the opening of the collimator 2, sufficient for measurements in its 50 field of the diagram directivity of the tested antenna 4 with the desired accuracy. In practice, the number N of measurement cycles is usually 5 - 10.

The method allows to increase the accuracy of determining the antenna radiation pattern by about an order of magnitude and thus expand the range of measured radiation pattern levels by 10 to 20 dB. The method also allows you to replace the currently used for large antennas method of measuring the radiation pattern in the far eon, which requires special remote polygons, since measurements by this method can be carried out in closed rooms of not large sizes directly on the territory of industrial enterprises. In addition, its use allows you to abandon the manufacture of large collimators, the production of which is associated with significant technological difficulties. '

Claims (2)

The invention relates to the technique of antenna measurements and can be used to measure antenna radiation patterns in enclosed spaces directly on the territory of industrial enterprises. The known method of measuring the radiation pattern, consisting in measuring the signal at the output of the test antenna at different angles of rotation in; the field of a stationary stationary antenna placed in the far zone of the test t} The disadvantage of this method is the need to use special expensive polygons. There is also known a method for determining the antenna radiation pattern, which includes measuring the signal at the output of the antenna under test at different positions of its antenna with respect to the field of the collimator G. However, the known method does not provide high accuracy of measurements, which is caused by the influence of the edge field of the collimator on the antenna under test and is most pronounced when testing large antennas whose dimensions are larger or comparable with the size of the collimator. The goal of isophene is to increase measurement accuracy. To achieve this goal, according to the method of determining the antenna pattern, the collimator is shifted sequentially in the plane of its opening, and for each angular position of the tested antenna, the complex amplitudes of the signals at its output are measured at successively shifted positions of the collimator, and the value of the radiation pattern is determined by summing the measured complex amplitudes. The drawing shows the structural scheme of the implement that implements the method. The device contains a generator 1 connected to a collimator 2 mounted on a displacement mechanism 3 providing movement of collimator 2 in its plane of curvature in two mutually perpendicular directions, the test antenna 4 is mounted on a rotary unit 5 providing rotation in azimuth and elevation, amp phase meter 6, the first input of which is connected to the output of the test antenna 4, and the second input with the second output of the generator 1, calculator 7, the input of which is connected to the amplifier 6, and the sensor 8 ANGLES connected to the third B Amplumometer 6. The method is implemented as follows: For each angle of rotation of the tested antenna 4oi, p) (a-azimuth, p elevation angle), complex amplitudes G. (ct, p) of the signal at the output of the tested antenna 4 are measured with successively shifted The positions of the collimator 2 (-i 1, 2 ... H, where b is the number of consecutive mixes of the collimator 2). These measurements are made for all tones oL, () of the rotation of the tested antenna 4, for which it is required to determine the values of its radiation pattern. The successive displacements of the collimator 2 are conducted in a plane parallel to its opening. Then, for each angle of rotation of the test antenna, the 4 values of the radiation pattern G (, P)) are determined by summing the measured complex amplitudes G, (o, P). i.e. GCoL, ib) -. i: e, C, P The measurements of the complex amplitudes h of the signal at the output of the test antenna 4 with successive displaced fields, the gains of the collimator 2 are carried out as many times as necessary. The total opening at all the specified positions of the collimator 2 was equal to that of the collimator 2, which is sufficient to make measurements in its field of the radiation pattern of the test antenna 4 s, with a numerical accuracy. In practice, the number N of measurement cycles is usually 5-10. The method allows to increase the accuracy of determining the antenna pattern by about an order of magnitude and thus expanding the range of measured radiation pattern levels by 10–20 dB. The method also makes it possible to replace the currently used method for large antennas for measuring the radiation pattern in the far zone, which requires special remote polygons, since measurements by this method can be carried out with small enclosures of small size directly on the territory of industrial enterprises. In addition, its use makes it possible to refuse to manufacture large collimators that are produced by newer ones due to significant technological difficulties. The invention method for determining the antenna radiation pattern, which includes measuring the signal at the output of the antenna under test at different angular positions relative to the collimator field, characterized in that, in order to improve the accuracy, the collimator is shifted sequentially in its opening plane and For each angular position of the test antenna, the complex amplitudes of the signals at its output are measured at successively shifted koshshmator positions, and the value of the radiation pattern is determined by sums measured complex amplitudes. Sources of information taken into account in the examination 1. A. Fradin. 3., Ryzhkov E. V. Measurement of parameters of antenna-feeder devices. M., St. Don, 1972, p. 245-246. 2JoViyi50vi R.C-attcleiCTbetei-niina-tV Dn o iar-iieed avitenna pa-bierMS irow wieasvjrevYienls.-Proceeding oi Ottt, V 6l ,, W, p.1679- 685 oipoTOTWn).