RU2538291C2 - Method of reducing level of lateral radiation of antenna - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to radio engineering, particularly antenna devices, and can be used in radio direction-finding and radio communication systems for various purposes. The method comprises a performing a given arrangement of radiators of an antenna array, forming a low side lobe beam pattern and forming an antenna array, wherein the given arrangement and formation of the radiators of the antenna array is carried out in space based on the geometric shape of the array of various spatial distributions of radiators of the antenna array: double hexagonal structures, wave-like and comb structures, with bending of the rectangular or circular aperture and other areas of arrangement of elements for which a more uniform lateral radiation is obtained while enabling control of amplitude-phase distribution thereof and equidistant arrangement of the beam pattern of the antenna while maintaining energy characteristics of the antenna array, such as directivity, gain and energy potential.

EFFECT: high accuracy of determining coordinates and noise-immunity.

3 cl, 6 dwg

Description

The invention relates to radio engineering, in particular to antenna devices and can be used in radio direction finding and radio communication systems for various purposes.

The level of the side lobes (UBL) of the antenna pattern is the radiation level normalized to the maximum of the radiation pattern (BF) of the antenna in the direction of the side lobes. UBL is the most important characteristic of antenna arrays, determining their noise immunity, electromagnetic compatibility, and in radio-linear systems (radar) - the probability of false detection of targets.

In modern radio engineering systems (RES) UBL should not exceed -20, -25 dB. To achieve such a low UBL value, various methods of synthesis and optimization of the amplitude-phase distribution (AFR), as well as the placement of elements in the antenna array, are used in practice.

Known methods for the synthesis of amplitude distribution for a continuous aperture of a discrete system of emitters [1-3]. The Dolph – Chebyshev excitation is known [1, 4], which makes it possible to minimize the UBL for a given beam width and, conversely, to minimize the beam width for a given UB. In [5, 6], a method of amplitude-phase synthesis of antenna arrays of arbitrary geometry according to a given pattern was proposed.

The application of this method to scanning headlamps is not possible, since it allows you to find the optimal AFR for only one fixed beam direction.

The article [7] discusses the method for determining the excitation currents of a ring transmitting television antenna array from dipoles according to a given shape of the beam in the horizontal plane.

The synthesis of multi-ring antenna arrays radiating along the normal to the plane of the emitters is devoted to [8, 9].

In [9], the problem of optimizing the main characteristics of ring concentric antenna arrays (CCAR) with a uniform amplitude distribution is considered, by the optimal choice of the radii of concentric circles. The paper presents the results of optimization of the radii of the CCAR obtained by the simplex method.

In article [9], the problem of optimizing the placement of elements in order to obtain the minimum SLL in a given area of angles is considered. Elements of the antenna array are located in the nodes of the broken lines forming an N-ray star. For this system, a description of the optimization algorithm and the results of calculating the characteristics for a different number of elements are given.

The monograph [10] discusses various methods of analysis and synthesis of antenna arrays based on atomic functions and gives recommendations on their use for development.

To solve the synthesis problems, the most effective are numerical optimization methods, such as, for example, the genetic algorithm [11].

However, numerical optimization methods are applicable when operating the antenna system in a narrow frequency band, and therefore it is advisable to use combined methods for the synthesis of the amplitude-phase distribution and spatial distribution of the elements of the antenna array.

The closest in technical essence to the claimed method is the selected as a prototype method of reducing the level of lateral radiation of the antenna, which consists in the fact that they carry out the specified placement of the emitters of the antenna array, form radiation patterns with a low level of side lobes and form the antenna array [9], in which UBL minimization is carried out by means of optimal placement of elements on a flat aperture.

A significant drawback of this method is the decrease in the antenna gain compared to its value with uniform and equidistant filling of the aperture. Since the optimization of placement reduces the number of elements. Thus, this method cannot be used in systems for which the most important parameters are the energy potential and UBL with a limited aperture area. Such systems include airborne radar systems and some terrestrial telecommunication systems. To reduce the SLL without changing the coefficient of directional action, it is proposed to use the spatial arrangement of elements in the antenna array, which has several advantages compared to planar and surface placement.

The technical result of the invention is to reduce the level of lateral radiation of antenna arrays without changing the gain and to expand the functionality, namely to increase the accuracy of determining coordinates, noise immunity and energy potential.

The specified technical result is achieved by the fact that in the method of reducing the level of lateral radiation of the antenna, which consists in the fact that they carry out the specified placement of the emitters of the antenna array, form radiation patterns with a low level of side lobes and form the antenna array, the specified placement and formation of the emitters of the antenna array is carried out in space the geometric shape of the lattice with the ability to provide control of their amplitude-phase distribution and equidistant placement of the diagram antenna uniformity while maintaining the energy characteristics of the antenna array, such as directional coefficient, gain and energy potential.

In addition, the emitters are placed on the surface of the antenna array equidistantly in the nodes of the hexagonal array, and the distance between the emitters is increased due to their spacing in space in height.

One of the main advantages of the proposed method is to increase the pitch of the emitters in the array, this is especially required for the active phased array antenna (AFAR) of the millimeter wave range. The same problems apply to combined HEADLIGHTS. To solve the problem of placing the elements of the feeder path, spatial antenna systems with a double hexagonal structure, wave-like, comb-like, etc. are offered. The simplest form is obtained by bending a rectangular or round aperture. In this case, the UBL decreases in the plane of the bend and its value depends on the magnitude of the bend. To reduce the SLL in another plane, it is necessary to use a pyramidal arrangement of emitters in a square aperture and any azimuthally symmetric in a round aperture. The directional characteristics of the spatial antenna array are calculated using formulas known from the theory of antennas. If the radiators of the antenna array emit fields with linear polarization, then the array of the array can be written in the form:

, $$F(\theta ,\phi )={\displaystyle \sum _{p=\mathrm{one}}^M{\displaystyle \sum _{q=\mathrm{one}}^N{A}_{p,q}{e}^{jk[x_{p,q}\sin \theta \cos \phi +y_{p,q}\sin \theta \sin \phi +z_{p,q}\sin \theta ]}}}$$

,

where M, N are the number of elements of the row and column of the lattice, respectively, A _{p, q} is the amplitude of the excitation current of the element (since the uniform amplitude distribution is considered in all calculation examples, then A _{p, q} = 1), θ, ϕ are spatial coordinates of the spherical system.

Previously, spatial antenna arrays did not find wide practical application due to the complexity of distribution systems. Currently, there is a targeted program to create a digital element base on which the distribution system is built. Moreover, the structure of the distribution system is greatly simplified. The distribution system can be implemented both on a modern digital and on an analog element base.

The invention is illustrated by drawings, on which figa, b presents the spatial arrangement of the elements that implement this method, providing preliminary estimates of the directivity of structures to reduce UBL with increasing pitch in the lattice due to the spatial arrangement of the elements, figure 2 shows the bend radiating antenna sheet: 1 - at 30 °, 2 - at 45 °, 3 - at 60 °, figure 2 shows three options for bending the aperture of the beam at 30 °, 45 ° and 60 °, in figures 3 and 4 - same, for convex and concave apertures of the DN, in figure 3: 1 - DN of a planar antenna array with a hexagonal structure, 2 - DN of a convex antenna array with a hexagonal structure bent at 30 °, 3 - DN of a convex antenna array with a hexagonal structure bent by 45 °, 4 - DN of a convex antenna array with a hexagonal structure, bent by 60 °, in Fig. 4: 1 - the bottom of a flat antenna array with a hexagonal structure, 2 - the bottom of a concave antenna array with a hexagonal structure, bent 30 °, 3 - the bottom of a concave antenna array with a hexagonal structure bent by 45 °, 4 - DN concave antenna array and with a hexagonal structure bent at 60 °, Fig. 5 shows the shape of the cosine curve of the surface of the antenna, Fig. 6 shows the DNs: 1 - DNs of a flat antenna array, 2 - DNs of a convex antenna array with a hexagonal structure curved according to a cosine law.

To reduce UBL, other geometrical forms of placement of elements in space can be applied, for example, pyramidal, parabolic, spherical, etc. Moreover, the decrease in SLL depends on the function of placing elements in a spatial hexagonal antenna array.

The proposed method is carried out in the process of turning on the transceiver equipment in the traditional standard mode with the ability to provide work in stationary and mobile conditions.

As computational experiments show, the directivity characteristics of an antenna array with double spatial hexagonality depend on the law of placement of elements in space. Therefore, a further decrease in the side lobes is obtained by synthesizing the spatial distribution of the elements, as well as applying optimization methods.

A significant difference of the proposed method compared to the prototype is that to reduce the UBL does not apply a decreasing amplitude distribution and nonequidistant placement of elements, leading to a decrease in antenna gain.

Thus, the claimed method allows to reduce the UBL, and unlike the prototype, it allows to implement technical solutions for antenna arrays with high energy potential and amplification.

The proposed method can be implemented on a modern digital element base using new methods of manufacturing technologies for antenna fabric, such as electroplating technology.

Reducing the SLL allows on-board radar systems to increase the accuracy of measurements of the coordinates of objects and noise immunity.

Information sources

1. Zelkin EG Construction of a radiating system according to a given radiation pattern. M.-L., Energy Publishing House, 1963.

2. Bahrakh L.D., Kremenetsky S.D. Synthesis of emitting systems. M., "Owls. the radio, 1974.

3. Analysis and synthesis of antenna arrays / Chaplin AF - Lviv: Vishka school. 1987.

4. G.T. Markov, D.M. Sazonov. Antennas - M .: Energy, 1975.

5. D.D. Gabrielyan, S.E. Mishchenko. The method of amplitude-phase synthesis of an antenna array of arbitrary geometry. - Radio engineering and electronics, 1995, T. 40, No. 7.

6. S.E. Mishchenko, S.V. Zemlyansky. Amplitude-phase synthesis of an antenna array with arbitrary placement of emitters according to a given vector radiation pattern. Materials of the All-Russian Conference "Emission and Emission of Electromagnetic Emission", Taganrog, June 18-23. 2001 year

7. P. Knight. "Synthesizing The Radiation Pattern of Ring Aerial", Industrial Electron., 1963, 1, No.10, 538-543 p.

8. M. Vicente-Lozano, F. Ares-Pena, and E. Moreno. "Pencil-Beam Pattern Synthesis with a Uniformly Exited Multi-Ring Planar Antenna," IEEE Trans. Antennas Propagat., Vol. 42, No.6, December 2000.

9. V.I. Dzyuba, L.V. Osipov. Optimization of the placement of the elements of the antenna system with a centrally symmetrical construction. // Antennas: Sat articles. Issue 37. / Ed. A.A. Lemansky. - M .: Radio and communications, 1990.

10. E.G. Zelkin, V.F. Kravchenko, V.I. Gusevsky. Constructive approximation methods in antenna theory. - M: Saynes-Press, 2005, 512 p.

11. Abdul-Aziz A. Abdul-Aziz, Hanna A. Kamala. Sector synthesis of antenna array using genetic algorithm. // Journal of theoretical and applied information technology, 2005 .-- pp. 160-169.

Claims (3)

1. The way to reduce the level of lateral radiation of the antenna, which consists in the fact that they carry out the specified placement of the emitters of the antenna array, form radiation patterns with a low level of the side lobes and form the antenna array, characterized in that the predetermined placement and formation of the emitters of the antenna array is carried out in space in geometric the shape of the array with the ability to provide control of their amplitude-phase distribution and equidistant placement of the antenna radiation pattern when stored and energy characteristics of the antenna array. 2. The method according to claim 1, characterized in that the emitters are placed on the surface of the antenna array equidistantly in the nodes of the hexagonal array. 3. The method according to claim 1, characterized in that the distance between the emitters is increased due to their spacing in space in height.

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