RU2742627C1 - Radiating antenna post - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to antenna engineering, particularly to rotary-bearing devices for irradiating and receiving antennae. Technical result is achieved by the fact that the rotary support device or the irradiating antenna post, comprising: "tripod" with the orientation mechanism together with the irradiating antenna mounted thereon; a HF signal generator unit coupled with a HF signal receiver coupled therewith, located on the table in close proximity to the "tripod" and connected by the coaxial cable to the irradiating antenna of the LF harnesses to the remote computer of the automated measurement system and its detector connected to the tested antenna, and through extender - to power supply board; ladder, differs from prototype in that "tripod" with orientation mechanism, table, stepladder with rails and enclosure, handle and shoe of power supply sockets with earthing terminals of extender are installed and fixed on platform with rotary wheels and setting jacks attached to it at corners.

EFFECT: technical result of the invention is to reduce labour intensity when deploying an antenna, higher stability of settings made during adjustment and a significant increase in the stability of the device.

3 cl, 8 dwg, 1 tbl

Description

The technical field to which the invention relates

The invention relates to the field of simple automated measuring complexes (AIC), placed in rooms and designed to measure the amplitude radiation patterns of antennas of high-frequency (HF) and microwave (microwave) frequency ranges.

The post of the irradiating antenna (hereinafter referred to as the POST), which is part of a simple AIK, is a separate device, also consisting of separate parts, manually transported (in preparation for the next measurements) over certain distances inside the antenna laboratory. These specific distances (ranges) between the aperture of the POST feed antenna and the aperture of the antenna under test installed on the AIK rotary stand are calculated and selected depending on the upper operating frequency and the size of the aperture of the irradiating and tested antennas (in the range from 2.5 to 15 meters). This is necessary to obtain a "flat front" of the irradiating electromagnetic signal at the aperture of the antenna under test (at frequencies up to 18 GHz).

The post of the irradiating antenna is designed to emit electromagnetic signals of the corresponding frequency range in the direction to the test antenna adjusted in height, azimuth and elevation, while the adjustment is carried out according to the maximum power received by the said test antenna. In AIK, as a rule, certified ("reference") broadband measuring antennas are used as feed antennas.

The technical result of the invention is to increase the stability of settings, reduce the labor intensity of work at the POST and improve the safety of work on it.

State of the art

The simplest POST is known, given in the Technical Description and the operating instructions for the measuring antenna

P6-23A of the Ministry of Radio Industry of the USSR 1972 [1]. It contains a sliding tripod ("tripod") with an orientation mechanism, including a rotary in azimuth and a sliding in height rod with manual drives, devices for mounting a standard antenna and rotating it in elevation and polarization; irradiating antenna; an RF signal generator located in the immediate vicinity of the "tripod" on the table and connected by a coaxial cable to the irradiating antenna, and through an extension cord to the nearest power supply board; a metal step-ladder removed from the measurement area (brought to the "tripod" to perform appropriate operations on the upper part of its orientation mechanism, and then carried away to its original place to reduce the influence of electromagnetic HF signals reflected from it). The location of the HF signal generator in the immediate vicinity of the "tripod", and, consequently, from the POST irradiating antenna is fundamentally important, since the required length of the coaxial cable is no more than three meters (instead of fifteen meters when the HF signal generator is located near the AIK rotary stand ). At the same time, the power loss in the high-frequency frequency range is significantly lower, and therefore a more accurate measurement of the antenna patterns under test.

Features of the considered device (POST), which coincide with the essential features of the claimed invention: "tripod" with an orientation mechanism, including a rotary in azimuth and retractable in height, a rod with manual drives, devices for mounting a standard antenna and rotating it in elevation and polarization; irradiating antenna; an RF signal generator located in the immediate vicinity of the "tripod" on the table and connected by a coaxial cable to the irradiating antenna, and through an extension cord to the power supply board; ladder.

The disadvantages of the analogue include: high labor intensity, low stability of the settings made when adjusting the POST, low safety of work at the POST.

The reason for the great labor intensity of work at the POST is that the POST consists of separate, manually transported parts: a "tripod" with an irradiating antenna located on its orientation mechanism, a table with an RF signal generator located on it, a metal step-ladder. To move the aforementioned parts of the POST requires: its preliminary partial dismantling, the presence of three employees to safely carry the "tripod" (together with the irradiating antenna attached to its orientation mechanism) and other parts, their installation and restoration of the POST's functionality.

The reason for the low stability of the settings made when adjusting the POST is that one of its parts - the "tripod" - slides on the hard (wooden or concrete) floor of the room. Therefore, it can move from the position set before the alignment and thereby violate the settings made during alignment (operations are performed at a height of 2.5 meters from an unstable ladder), with any mechanical impact on it or on the irradiating antenna (for example, when disconnecting a coaxial cable, and then attaching it to it after calibration).

The reason for the low safety of work at the POST is that one of its parts - the "tripod" - slides on the floor of the room and is unstable to overturning, the other part of it - the step-ladder - is also unstable to overturning, has no railings and fences, as well as the fact that at the POST, a purchased extension cord with spring "earth" contacts is used in its "euro sockets"; it has insufficient length and insufficient protection of the wires of its bundle. Unreliable spring "earth" contacts of "euro sockets" lead to an unacceptable break in the grounding circuit of the POST parts, the insufficient length of the extension cord leads to the fact that it is connected to another (nearest) power supply panel, while an unacceptable potential difference arises between the AIK parts, and insufficient protection extension cord can cause electric shock and short circuits to personnel.

Also known from the prior art is an automated remotely controlled post of the irradiating ("auxiliary") antenna included in the Installation for measuring the parameters of antennas in the far zone of an open type (sites and polygons), published in the book "Automated antenna measurements", A.F. Strakhov, M., "Radio and Communication", 1985, (p. 99, fig. 5.1, p. 10, p. 24 - fig. 2.1; p. 99 - fig. 5.1; p. 103 - fig. 5.2; p. 125, p. 127-fig. 8.3) [2].

The considered automated remotely controlled post of the irradiating ("auxiliary") antenna belongs to the complex and very expensive AIC, which are used in unique open ranges and in expensive anechoic chambers, and therefore it cannot be a close analogue of the proposed device.

Also known (presumably for its advertised parts) is the foreign analogue of POST, published in the "Catalog of Microwave Electronics 2017" by SCARD-Electronics JSC, p .: 104 - photos 1 and 2, 106 - photos 1 and 2. [3]. It contains a movable, on three swivel wheels with friction brakes "tripod" TMU-1 with a rotary support device, including a rod with devices for mounting a standard antenna, moving it along its height, turning to change the polarization and elevation angle, an irradiating antenna, an RF signal generator located in the immediate vicinity of the "tripod" on the table and connected by a coaxial cable to the irradiating antenna, and through an extension cord to the nearest power supply board, as well as a metal step-ladder remote from the measurement zone (brought to the "tripod" to perform the appropriate operations on the upper part of the rod a rotary support, and then carried away to its original place to reduce the influence of electromagnetic HF signals reflected from it).

Features of the considered foreign device (POST), which coincide with the features of the claimed invention: "tripod" with a rotary support device, including a rod with mounting devices for a standard antenna, moving it in height, turning it to change the polarization and elevation; irradiating antenna; an RF signal generator located in the immediate vicinity of the "tripod" on the table and connected by a coaxial cable to the irradiating antenna, and through an extension cord to the power supply board; stepladder.

The disadvantages of this device include: high labor intensity of work at the POST, low stability of the settings made during the adjustment of the POST, low safety of work at the POST.

The reason for the great laboriousness of work at the POST is that the POST consists of separate manually transported parts (a table with an RF signal generator located on it, a metal step-ladder) and a rolling "tripod". For the safe movement of the above-mentioned parts of the POST, it is required: its preliminary partial dismantling, the presence of two employees to carry the HF generator unit together with the table, carry other parts of the device, their installation and restoration of its operability.

The reason for the low stability of the settings made when adjusting the POST is that the wheels of the "tripod" slide along the floor of the room and rotate in the horizontal plane in the support bearings, and therefore it under any mechanical stress on it or on the irradiating antenna, for example, when disconnected from of the irradiating antenna of the coaxial cable and its subsequent connection to it after calibration, may move from the position set before the adjustment and thereby violate the settings made during the adjustment.

The reason for the low safety of work at the POST is that the wheels of the "tripod" slide along the floor of the room and rotate in the horizontal plane in the support bearings, and the metal step-ladder is not stable on the floor of the room, does not have railings and fences (recall that most of the operations on The POST is performed at a height of 2.5 meters), as well as the fact that the POST uses a purchased extension cord with unreliable spring "earth" contacts in its "Euro sockets" and insufficient length and protection of the wires of its harness.

As a prototype, the post of the irradiating antenna, given in the "Technical Description and Operating Instructions for the Measuring Antenna P6-23A of the USSR Ministry of Radio Industry 1972" [1], was chosen, or rather its modernized version with a wider-band measuring antenna P6-23M and with a partially modified "tripod" design. During the first use of the "tripod", it became clear that its new orientation mechanism is worse in many characteristics than the previous one (the rod has a large play in the support bearing, inconvenient and rough rotation mechanisms in azimuth, polarization and elevation of the irradiating antenna), and therefore The proposed device uses a "tripod" from the aforementioned set of measuring antenna P6-23A with "legs" extended in length (by 300 mm) to raise the irradiating antenna to an optimal height (2.5 meters from the floor level of the laboratory room).

The prototype contains a sliding tripod ("tripod") with an orientation mechanism, including a rotary in azimuth and a sliding in height rod with manual drives, devices for mounting a standard antenna and rotating it in elevation and polarization, an irradiating antenna (measuring antenna P6-23M), an RF signal generator unit coupled with an RF signal measuring receiver (P2M-18 network analyzer) located in the immediate vicinity of the tripod on the table and connected by a coaxial cable to the irradiating antenna, low-frequency (LF) harnesses with remote computers of the automated measuring complex and its own a detector connected to the antenna under test, and through an extension cord to the nearest power supply panel, a metal step-ladder, removed outside the measurement area (brought to the "tripod" for performing the appropriate operations on its upper part, and then carried away to its original place to reduce the influence of electromagnetic HF reflected from it signals).

Recall that the above-mentioned automated measuring complex for measuring the amplitude radiation patterns of antennas, in addition to the RF signal generator with a connected irradiating antenna, includes an RF signal measuring receiver coupled to it with a test antenna connected to it. The optimal device for these purposes is the P2M-18 radio measuring device produced by the domestic industry, which contains a coupled RF signal generator and an RF signal receiver (with an external ultra-wideband detector at the input, which allows it to be remotely positioned on the AIK rotary stand through the LF extension cord). At the same time, the said device allows it to be remotely controlled (according to an original program developed at the enterprise) from a remote personal computer of an automated measuring complex.

Features of the prototype, which coincide with the essential features of the claimed invention:

- "tripod" with an orientation mechanism, including a rotary in azimuth and retractable in height rod with manual drives, as well as with devices for mounting a standard antenna and rotating it in elevation and polarization;

- irradiating antenna (measuring antenna P6-23M);

- an RF signal generator unit coupled with an RF signal receiver (P2M-18 network analyzer), located in the immediate vicinity of the "tripod" on the table and connected by a coaxial cable to the irradiating antenna, LF harnesses to the remote computer of the automated measuring complex and its own detector connected to the antenna under test, and through the extension cord to the power supply board;

- a stepladder.

The disadvantages of the prototype include: high labor intensity of work at the POST, low stability of the settings made when adjusting the POST, low safety of work at the POST.

The reason for the great labor intensity of work at the POST is that the POST consists of separate, manually transported parts (a "tripod" with an irradiating antenna located on its orientation mechanism, a table with an RF signal generator located on it, a metal step-ladder). To move the aforementioned parts of the POST requires: its preliminary partial dismantling, the presence of three employees to safely carry the "tripod" (together with the irradiating antenna attached to its orientation mechanism) and other parts, their installation and restoration of the POST's functionality.

The reason for the low stability of the settings made when adjusting the POST is that one of its parts - the "tripod" - slides on the hard (wooden or concrete) floor of the room, and therefore, under any mechanical influences on it or on the irradiating antenna, for example , when disconnecting the coaxial cable from the feed antenna, and then connecting it to it after calibration, it can move from the position set before the alignment and thereby violate the settings made during the alignment. Let us remind you that adjustment operations are performed at a height of 2.5 meters from an unstable ladder.

The reason for the low safety of work at the POST is that one of its parts - the "tripod" - slides on the floor of the room and is unstable to overturning, the other part of it - the step-ladder - is also unstable to overturning, has no railings and fences, as well as the fact that the POST uses a commercially available extension cord with unreliable spring "earthen" contacts in its "euro sockets", insufficient length and insufficient protection of the wires of its harness. Note that unreliable spring "ground" contacts of "euro sockets" lead to an unacceptable break in the grounding circuit of the POST parts, the insufficient length of the extension cord leads to the fact that it is connected to another (nearest) power supply board, while an unacceptable potential difference arises between the AIK parts, and inadequate protection of extension cord wires can result in electric shock and short circuits to personnel.

To eliminate the shortcomings of the prototype, in particular to prevent slipping on the floor of the room and to ensure the possibility of movement, convenience, stability and reliability of the whole structure, the claimed mechanized post of the irradiating antenna was created.

The objective of the invention is to reduce the labor intensity of work at the POST, to significantly increase the stability of the settings made during its adjustment (and, therefore, to significantly increase the accuracy of measurements of the antenna patterns under test) and to significantly increase the safety of work on it.

The task is solved due to the fact that the claimed POST contains: a tripod ("tripod") with an orientation mechanism together with an irradiating antenna fixed on it; an RF signal generator unit together with an RF signal receiver coupled to it, located on the table in the immediate vicinity of the "tripod" and connected by a coaxial cable to the irradiating antenna, LF harnesses to the remote computer of the automated measuring complex and its detector connected to the antenna under test, and through an extension cord to the power supply board; ladder. The proposed POST differs in that a tripod with an orientation mechanism together with an irradiating antenna fixed on it, a table with an RF signal generator unit located on it, a ladder with a handrail and a guardrail, a handle and blocks of power outlets with grounding terminals of the said extension cord are installed and fixed on the platform with swivel wheels and installation jacks attached to it at the corners.

At the same time, the platform, the table installed between the "legs" of the tripod, a ladder with a handrail and a guardrail and a handle are made of plywood and blocks of wood or corresponding synthetic materials with a low coefficient of reflection of electromagnetic waves, and the plug and the tip of the "earth" wire of the flexible corrugated tube, connected to a single power board of the automated measuring complex.

Disclosure of the essence of the invention

The technical result in the claimed device is achieved due to the fact that a "tripod" with an orientation mechanism together with an irradiating antenna attached to it, a table with an RF signal generator unit located on it, a ladder with a handrail and a guardrail, a handle and blocks of power outlets with grounding terminals the mentioned extension is installed and fixed on the platform with rotary wheels and installation jacks attached to it at the corners. At the same time, the platform, the table installed between the "legs" of the tripod, a ladder with a handrail and a guardrail and a handle are made of plywood and blocks of wood or corresponding synthetic materials with a low coefficient of reflection of electromagnetic waves, and the plug and the tip of the "earth" wire of the flexible corrugated tube, connected to a single power board of the automated measuring complex.

The essential features of the inventive Post of the irradiating antenna: a tripod ("tripod") with an orientation mechanism together with the irradiating antenna attached to it; an RF signal generator unit with an RF signal receiver coupled to it, located on the table in the immediate vicinity of the "tripod" and connected by a coaxial cable to the irradiating antenna, LF harnesses to the remote computer of the automated measuring complex and its detector connected to the antenna under test, and through extension cord to the power supply board; ladder.

The proposed post of the irradiating antenna differs in that the "tripod" with an orientation mechanism together with the irradiating antenna fixed on it, a table with an RF signal generator unit located on it, a ladder with a handrail and a guardrail, a handle and blocks of power outlets with grounding terminals of the said extension cord are installed and fixed on a platform with swivel wheels and installation jacks attached to it at the corners.

At the same time, the platform, the table installed between the "legs" of the tripod, a ladder with a handrail and a guardrail and a handle are made of plywood and blocks of wood or corresponding synthetic materials with a low coefficient of reflection of electromagnetic waves, and the plug and the tip of the "earth" wire of the flexible corrugated tube, connected to a single power board of the automated measuring complex.

In general, it is shown that the post of the irradiating antenna consists of a "tripod" with an orientation mechanism together with a fixed irradiating antenna, an RF signal generator unit with an associated RF signal receiver located on the table in close proximity to the "tripod" and connected by a coaxial a cable to the irradiating antenna, LF harnesses to a remote AIK computer and its detector connected to the antenna under test, and through an extension cord to the power supply board and a ladder.

The distinctive features show that a "tripod" with an orientation mechanism together with a radiating antenna fixed on it, a table with an RF signal generator unit located on it, a ladder with a handrail and a guardrail, a handle and blocks of power outlets with grounding terminals of the aforementioned extension cord are installed and fixed on a platform with swivel wheels and installation jacks attached to it at the corners.

At the same time, the platform, the table installed between the "legs" of the tripod, a ladder with a handrail and a guardrail and a handle are made of plywood and blocks of wood or corresponding synthetic materials with a low coefficient of reflection of electromagnetic waves, and the plug and the tip of the "earth" wire of the flexible corrugated tube, connected to a single power supply panel of the entire automated measuring complex.

Table 1 shows the causal relationship between the set of essential features of the claimed object and the achieved technical result.

The invention makes it possible to manufacture simple and cheap mechanized posts of irradiating antennas, which provide a significant reduction in the labor intensity of the work performed on them, increase the stability of the settings made during their alignment (hence, increase the accuracy of measurements of antenna directional patterns) and increase the safety of work on them.

Brief Description of Drawings

The technical essence and principle of operation of the prototype and the proposed devices are illustrated by photographs in which:

FIG. 1 Shows the main part ("tripod" with stretchers, an orientation mechanism and an irradiating antenna fixed on it) of the manually carried station of the irradiating antenna (prototype);

FIG. 2 Shown is the main part ("tripod" TMU-01) of a foreign, partly mobile (on built-in three wheels) and partly manually transported Post of the irradiating antenna (analog);

FIG. 3 The proposed mechanized is shown (on a mobile platform with built-in rotary wheels and adjusting screw jacks) Post of the irradiating antenna (front view);

FIG. 4 The proposed mechanized is shown (on a mobile platform with built-in rotary wheels and adjusting screw jacks) Post of the irradiating antenna (right view);

FIG. 5 The proposed mechanized is shown (on a mobile platform with built-in rotary wheels and adjusting screw jacks) Post of the irradiating antenna (rear view);

FIG. 6 Shown is an enlarged fragment of the proposed mechanized (on a mobile platform with built-in rotary wheels and adjusting screw jacks) Post of the irradiating antenna (view from the right at an angle of 45 degrees);

FIG. 7 The proposed mechanized post of the irradiating antenna with its alignment is shown (view from the right at an angle of 40 degrees);

FIG. 8 The proposed mechanized post of the feed antenna is shown with its alignment (right side view at an angle of 225 degrees).

Implementation of the invention

The possibility of practical implementation of the claimed invention is shown by examples in FIG. 3-6.

The proposed POST consists of: a tripod 1 ("tripod" 1) with an orientation mechanism 2 together with an irradiating antenna 3 fixed on it; the RF signal generator unit together with the associated RF signal receiver 4, located on the table 5 in the immediate vicinity of the "tripod" 1 and connected by a coaxial cable 6 to the irradiating antenna 3 with LF harnesses, 7 to the remote computer of the automated measuring complex and its own detector connected to the antenna under test, and through the extension cord 8 to the power supply board; stepladders 9; characterized in that the "tripod" 1 with the orientation mechanism 2 together with the irradiating antenna 3 fixed on it, the table 5 with the RF signal generator unit 4 located on it, the ladder 9 with the handrail 10 and the guardrail 11, the handle 12 and the sockets for the power outlets 13 with grounding terminals 14 of said extension cord 8 are installed and fixed on platform 15 with rotary wheels 16 and mounting jacks attached to it at the corners 17. In this case, the mentioned platform 15, table 5 installed between the "legs" of the tripod 1, stepladder 9 with handrails 10 and guard 11 and handle 12 for rolling the platform are made of plywood and bars 18 made of wood or corresponding synthetic materials with a low reflectance of electromagnetic waves, and the plug and the tip of the "earth" wire of the extension cord harness 8 protected by a flexible corrugated tube are connected to a single power supply panel AIK ...

Work at the POST is carried out as follows.

Connect the ground terminal of the network analyzer 4 with the appropriate conductor (with lugs) to the ground terminal 14 of the extension cord 8, connect the RF output of the network analyzer 4 with a coaxial cable 6 to the input of the irradiating antenna 3, and connect its LF inputs through the corresponding extension cords 7 to the remote ones (located respectively next to a rotary stand and on a rotary stand AIK) to the AIK control computer and its detector. Insert the plug of the power cord of the network analyzer 4 into the "European socket" 13 of the extension cord 8, and then connect the tip of the "earth" wire of the extension cord 8 to the "ground" terminal and its plug to the 220 Volt "Euro socket" of the single power board of the entire AIK. Switch on the control computer and the rotary stand of the automated measuring complex, and also switch on the network analyzer 4 of its remote Post of the irradiating antenna for warming up. After the completion of warming up (at least 30 minutes), it is necessary to calibrate its equipment in accordance with the AIK instructions. Then, in accordance with the upper operating frequency of the antenna under test and the dimensions of the apertures of the feeding and tested antennas, calculate the "far zone", i.e. the minimum distance (range) between the apertures of the irradiating antenna 3 of the POST and the antenna under test (installed on the AIK rotary stand). Next, install (roll) to the calculated range of the Post of the irradiating antenna, for which first lower its platform 15 from jacks 17 to wheels 16 and roll it back (roll) it by the handle 12 to the calculated distance (range), carefully observing that under the wheels 16 the extension cord 8 and the extension cord 7 did not hit. Then, if necessary (also by the handle 12), install the platform along the line of sight and reinstall it on jacks 17 (until the swivel wheels 16 rotate freely). Then, by visual control, install the irradiating antenna 3 on the POST with the aperture in the direction of the test antenna (using the elevation and azimuth drives of the orientation mechanism 2), and then set the center of the aperture of the irradiating antenna 3 at the same level with the center of the aperture of the antenna under test (using the drive for lifting the rod of the mechanism orientation 2). Further, according to the maximum power received by the antenna under test (indicated on the screen of the AIK control computer in the form of a graph), adjust the radiation of the irradiating antenna 3 in the exact direction to the antenna under test (carefully using first the elevation and then the azimuth drives of the orientation mechanism 2). Then again measure (using a tape measure) the exact value of the distance (range) between the apertures of the mentioned antennas, enter it and other necessary data into the program of the said AIK computer to measure the directional pattern of the antenna under test and start measuring it.

The proposed POST works as follows. The AIK operator on the control computer starts the program for measuring the directional pattern of the antenna under test (with the initial data entered into it beforehand). At the same time, electrical signals for controlling their operation are sent to the POST HF signal generator unit and to the AIK rotary stand (on which the tested antenna is installed) during the entire measurement cycle along the LF harnesses 7 from the AIK computer, and to the AIK computer through the LF harness 7 from the output of the detector The receiving part of the POST unit 4 receives the codes of the power levels of the RF signals received by the antenna under test. According to the codes of the aforementioned electrical control signals, the generator part of the POST block 4, during the measurement cycle of the amplitude radiation pattern of the antenna under test, repeatedly generates and outputs to the irradiating antenna a number of RF signals specified with a certain step in frequency and power level. In this case, the detector receiving part of the unit 4, together with the antenna under test, receives the RF signals emitted by the irradiating antenna 3 of the POST and generates their power level codes (essentially the codes of the measured transmission coefficients between the irradiating and the tested antennas). At the same time, according to the codes of other electrical control signals (coming from the AIK computer), its rotary stand rotates slowly in the azimuthal plane, from minus 90 degrees to 90 degrees, and its angular sensor generates and sends codes of the rotary stand angular position to the AIK control computer (antenna under test). At the same time, practically in real time, the AIK control computer processes the information included in the measurement program (a number of gains of the irradiating antenna 3 in a given frequency range, a number of AIK calibration data, the value of the distance between the apertures of the irradiating and tested antennas), information received from the rotary stand AIK (codes of the angular position of the antenna under test), the information coming from the meter of the transmission coefficient 4 (codes of the transmission coefficients), and builds on the screen of its monitor color graphs of the directional patterns of the antenna under test measured at the given frequencies, expressed along the ordinate by the values of the gain antennas in decibels.

In the process of adjusting (checking) the claimed POST check for compliance with its assembly drawing, the quality of its assembly, the absence of deformations (dents) on its component parts, the absence of damage to the insulation and flexible corrugated (protective) tube on the harnesses, the operability of the manual drives of the "tripod" and its the orientation mechanism, as well as the operability of the swivel wheels and installation jacks attached to the platform.

Literature:

1. Technical description and operating instructions for the measuring antenna P6-23A of the USSR Ministry of Radio Industry 1972

2. Automated antenna measurements, A.F. Strakhov, M. - "Radio and Communication", 1985, p. 99, fig. 5.1.

3. "Catalog of microwave electronics 2017" JSC "SCARD-Electronics", pp. 103, 106.

Claims (3)

1. Post of the irradiating antenna, containing: a "tripod" with an orientation mechanism together with the irradiating antenna attached to it; an RF signal generator unit together with an RF signal receiver coupled to it, located on the table in the immediate vicinity of the "tripod" and connected by a coaxial cable to the irradiation antenna with LF harnesses to a remote computer of the automated measuring complex and its own detector connected to the antenna under test, and through the extension cord to the power supply board; a stepladder, characterized in that a "tripod" with an orientation mechanism, a table, a stepladder with a handrail and a guardrail, a handle and sockets for power outlets with an extension cord grounding terminals are installed and fixed on a platform with swivel wheels and installation jacks attached to it at the corners. 2. Post of the irradiating antenna according to claim 1, characterized in that the platform, the table installed between the "legs" of the "tripod", a ladder with a handrail and a guardrail and a handle are made of plywood and blocks of wood or synthetic materials with a low reflection coefficient electromagnetic waves. 3. The post of the irradiating antenna according to claim 1, characterized in that the plug and the tip of the "ground" wire of the extension cord, protected by a flexible corrugated tube, are connected to a single power supply panel of the automated measuring complex.

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