RU2554562C2 - Radiating antenna in shielding housing - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to antenna engineering. The set task solved owing to that the radiating antenna 1 is mounted on a flat plate inside a shielding housing 3 consisting of conducting plates, having the shape of a truncated cone, the edge of the butt-end of which is connected to the edge of a shell ring, and the edge of the top of which is connected to the edge of the flat plate.

EFFECT: protecting a radiating antenna from the action of reradiating structural elements in order to eliminate the negative effect thereof on antenna beam pattern parameters.

12 dwg

Description

The invention relates to antenna technology, and in particular to a device that protects a radiating antenna from the negative influence of re-emitting structural elements of the carrier object of the radiating antenna on the parameters of the antenna radiation pattern (BOTTOM).

Angular antennas are known or, as they are called, antennas with an angular reflector [1], in the simplest form consisting of two flat plates forming a reflector (reflector), between which a linear irradiator is placed. As an irradiator, as a rule, either a single vibrator or a linear vibrating grating is used. Typically, the irradiator axis is located in the bisectorial plane of the antenna. With the proper choice of the reflector angle and the distance from the axis of the vibrator to the top of the angle, it is possible to ensure a favorable addition of the wave field reflected from the reflector with the wave field created directly by the vibrator. With a symmetrical arrangement of the irradiator relative to the plates of the reflector and relatively small dimensions of the reflector, maximum radiation is provided mainly in the direction of the bisector of the angle.

Known angular antenna [2], containing an angular reflector formed by two rectangular conductive plates connected at an angle φ and performing the function of the main reflectors, a radiating device located in the cavity of the said angular reflector, additional rectangular conductive plates performing the function of an additional reflector, each additional rectangular the conductive plate is placed at an angle to one of the main reflector plates and is connected along an edge parallel to the connection line main reflectors.

The analysis shows that in the cited information sources [1] - [2], reflector-reflectors are focused only on ensuring the formation of DND in the interest of increasing the gain in a given direction and are not intended to fulfill the protection function from the negative influence of closely located re-emitting structural elements of the object on which placed these antennas (carrier object).

Known antennas of axial radiation [3], built on the principle of placing a system of emitters (vibrators, coils) along the axis of the antenna. When providing phase shifts of currents close to phase shifts in the emitters in an electromagnetic wave propagating in the direction of the antenna axis, such an antenna has a pronounced directivity, the antenna gain depends on the length of the segment on which the emitters are placed (spiral length). Axial radiation antennas are widely used in practice as sector radiation antennas.

A significant drawback of axial radiation antennas is that when placing a large number of transmitting antennas at close distances, for example, on small transport (carrier objects), the roof of a building, etc., when the signal is emitted, DND distortion occurs due to the influence of nearby metal re-emitting objects. The essence of the effect of reemitting objects on the radiation characteristics is as follows. Each vibrator of the radiating antenna 1 (Fig. 1) is located near the metal surface 2, is an elementary antenna having a circular radiation pattern in the horizontal plane. The energy of the emitter wave incident on the nearby re-emitting metal surface 2 is reflected from it in the direction for which the angle of incidence and reflection of the wave is observed, the reflected wave enters another antenna vibrator and changes the amplitude and phase of the current in the vibrator, since this current is the result of the addition of current due to the power supplied to the radiating antenna 1 and the current induced by the reflected wave. The total effect of the influence of all 2 waves reflected from the re-emitting metal surface caused by radiation towards the reflective surface of each vibrator can significantly change the gain of the radiating antenna 1 and its radiation pattern.

A radiating antenna in a shielding case in an open publication from all available sources was not found.

Thus, the technical result of the invention is to protect the radiating antenna from the effects of re-radiating structural elements in the interest of parrying their negative impact on the parameters of the bottom.

This object is achieved by the fact that the emitting antenna is mounted on a flat plate inside a shielding housing, consisting of conductive plates having the shape of a truncated cone, the edge of the end face of the base of which is connected to the edge of the shell, and the edge of the end face of the top is connected to the edge of the flat plate.

Other design solutions for the shielding housing are possible, such as:

- said conductive plates are made in the form of a truncated pyramid, the edge of the end of the base of which is connected to the edge of the shell, and the edge of the end of the top is connected to the edge of the flat plate;

- said shell is made in the form of a rectangle, in which two opposite sides are continued in the form of a trapezoid, interacting with inclined surfaces and a flat plate;

- said shielding body is made in the form of three side plates, one inclined plate and a flat plate.

It is possible to mount a radiating antenna at the junction of the connection of the inclined surface and the flat surface of the shielding housing.

The invention is illustrated in figures 1-12.

In FIG. 1 shows the motion of a wave when a radiating antenna is placed near a metal surface; FIG. 2 shows a general view of a radiating antenna; FIG. 3 shows a general view of a radiating antenna mounted in a shielding housing; FIG. 4 shows a cross section of the shielding housing; FIG. 5 shows the movement of the wave when placing a radiating antenna located inside the shielding housing near a metal surface, FIG. 6 shows a general view of a radiating antenna installed in a shielding case (an embodiment of a shielding case in the form of a truncated pyramid, the edge of the end of the base of which is connected to the edge of the shell, and the edge of the end of the top is connected to the edge of the flat plate), FIG. 7 shows a cross section of a shielding case (an embodiment of a shielding case in the form of a truncated pyramid, the edge of the end face of which is connected to the edge of the shell, and the edge of the end of the top is connected to the edge of the flat plate), in FIG. 8 shows the main electrical characteristics of a radiating antenna without a shielding case and installed in a shielding case in a given frequency range (1.3 ... 1.7 GHz) in free space, in FIG. 9 shows the condition for placing a radiating antenna without a shielding case and installed in a shielding case under conditions unfavorable from the point of view of possible re-emissions, FIG. 10 shows radiation patterns of a radiating antenna in free space and near re-radiating elements, FIG. 11 shows radiation patterns of a radiating antenna mounted in a shielding enclosure located in free space and near re-emitting elements, FIG. 12 shows design options for the shielding housing and the placement of a radiating antenna therein.

The radiating antenna in the shielding housing consists of a radiating antenna 1 and a shielding housing 3.

The shielding housing 3 consists of conductive plates made in the form of a truncated cone 3.2, shell 3.1 and a flat plate 3.3.

Truncated cone 3.2 edge of the base interacts with the edge of the shell 3.1 and the edge of the vertex interacts with the edge of the flat plate 3.3.

The radiating antenna 1 is mounted inside the shielding housing 3 on a flat plate 3.3.

The shell 3.1 isolates the lateral radiation of the vibrators of the radiating antenna 1. The truncated cone 3.2 is a reflector amplifying the radiation of the vibrators of the radiating antenna 1, expressed in the redirection of the radiation of the rear lobes of the radiating antenna 1 in the direction of the maximum radiation pattern. Flat plate 3.3 serves as the basis for mounting the radiating antenna 1.

The operation of the radiating antenna in a shielded housing is as follows. When current is applied to the radiating antenna 1, the vibrators emit electromagnetic waves into the rear hemisphere, the propagation of which into the given hemisphere is prevented by the shielding housing 3. Radiation in the indicated region of space is possible only due to the presence of currents induced by the vibrations of the radiating antenna 1 (wave V1 in FIG. 5) on the leading edge of the shell 3.1. Provided (this condition is practicable in almost all cases) that there is no re-emitting object in the front hemisphere (metal surface 2) reflected from re-emitting objects (metal surface 2), the wave can reach the casing 3.1 only when reflected normal to the surface of the object (wave V2 in Fig. 5). All other waves emitted by the edge of the shell 3.1, for example, wave V4, according to the laws of reflection will be directed to the rear hemisphere (wave V5 in Fig. 5), and will not fall on the edge of the shell 3.1, and therefore can not be reradiated by the edge of the shell 3.1 on the vibrators emitting antennas 1. The proportion of wave energy from re-emitting objects (metal surface 2) due to reflections from them (wave V3 in Fig. 5) will be insignificant, since most of the energy will go in directions other than the normal to the reflecting surface.

Evaluation of the effectiveness of the proposed radiating antenna in a shielding enclosure was verified by comparative simulation on a computer of the processes of radiation energy of a radiating antenna and a radiating antenna in a shielding enclosure having the same electrical characteristics, placed under the same conditions.

Comparative tests of the radiating antenna 1 (8-element log-periodic antenna of Fig. 2) in free space and the radiating antenna 1 installed in the shielding casing 3 (6-element log-periodic antenna of Fig. 3) were carried out.

The dimensions and shape of the shielding case 3 were selected from the condition of compliance of the electrical characteristics of the proposed radiating antenna 1 in the shielded case 3 with the radiating antenna 1 without the shielding case 3. When optimizing the characteristics of the radiating antennas 1, it turned out that the introduction of the shielding case 3 with an increase in overall dimension in a plane perpendicular the radiation axis by 1.45 times reduced the size of the radiating antenna along the axis by 2 times, thereby reducing the maximum overall size of the radiating antenna by twice. This circumstance is due to the increase in gain due to the redirection of the truncated cone 3.2 of the rear lobes of the antenna radiation towards the maximum radiation and decrease due to this number of vibrators. The main characteristics of the radiating antenna 1 and the radiating antenna 1 installed in the shielded case 3 in a given frequency range (1.3 ... 1.7 GHz) operating in free space are shown in FIG. 8. The graph of the standing voltage wave coefficient (VSWR) shows that the VSWR of the emitting antenna 1 installed in the shielding casing 3 is less than that of the emitting antenna 1 operating in free space.

A comparative analysis of the operation of the radiating antenna 1 and the radiating antenna 1 installed in the shielding case 3, when they are placed near the re-radiating elements of the metal surface 2. The situation of the placement of the radiating antenna 1 and the radiating antenna 1 installed in the shielding case 3 near two mutually perpendicular conductive plates was simulated. having a metal surface 2 (Fig. 9).

The obtained simulation result of DND taking into account reemissions is shown in FIG. 10 and FIG. eleven.

From the graph (Fig. 10) it follows that in the entire given frequency range, the effect of reflections from metal surfaces 2 on the operation of the emitting antenna 1 occurs, which leads to a distortion of the shape of the main lobe of the radiation pattern, which consists in reducing the width of the main lobe with the deviation of the maximum radiation from a given directions by 15 ... 35 °.

From the graph (Fig. 11) it follows that in the entire given frequency range there is no effect from metal surfaces 2 on the operation of the radiating antenna 1 located in the shielding case 3. The radiating antenna 1 installed in the shielding case 3 works almost the same as and a radiating antenna in free space.

Other constructive solutions are possible for making the shielding body 3 in the form of a shielding body 4, when the truncated cone 3.2 is made in the form of a truncated pyramid 4.2, the shell 3.1 having a cylindrical shape is made in the form of a shell 4.1 having the shape of a polyhedron, a flat plate 3.3 having a round shape, made in the form of a flat plate 4.3, having the shape of a polygon.

Another constructive solution is possible to make the shielding case 3 in the form of a shielding case 5, when the two sides of the shell 5.1 have a continuation in the form of trapezoid 5.3 interacting with the inclined surfaces 5.2 and the flat plate 5.4.

Another constructive solution of the shielding casing 3 in the form of a shielding casing 6 is possible, when the shielding casing 6 has side conductive sheets 6.1, 6.2, 6.3, an inclined sheet 6.4 and a flat plate 6.5.

The installation of the radiating antenna 1 is carried out on a flat plate 3.3 or 4.3 or 5.4 or 6.5, but it is possible to install the radiating antenna 1 and at the junction of the connection of the inclined surface 6.4 and the flat plate 6.5 of the shielding housing 6.

This technical solution allows you to provide the desired configuration and parameters of the DND in the conditions of a negative impact on the formation of closely spaced re-emitting structural elements of the object on which this radiating antenna is located.

Literature

1. Eisenberg G.Z. and other VHF antennas. Ed. G.Z. Eisenberg. In 2 hours. Part 2. - M.: “The Messenger”. 1977 - p. 122-135.

2. Patent for invention No. 2185696, RU, Corner antenna, IPC H01Q 15/18, H01Q 19/185, published July 20, 2002.

3. Kocherzhevsky G.N. and other Textbook for universities / G.N. Kocherzhevsky, GA. Erokhin, N.D. Kozyrev. - M.: Radio and Communications, 1989 - 352 s: ill. - from. 167-173.

Claims (1)

A radiating antenna in a shielding housing, comprising a radiating antenna mounted on a flat plate inside a shielding housing consisting of conductive plates having the shape of a truncated cone, the edge of the end of the base of which is connected to the edge of the shell, and the edge of the end of the top is connected to the edge of the flat plate.

Images