RU182000U1 - AUTOMATED CONTROL DEVICE - Google Patents

Abstract

The utility model relates to automated test equipment and can be used to verify the operability of electronic equipment of complex objects. An automated control device can be used at various stages of the life cycle of complex objects from development to maintenance, as well as repair of complex objects during their operation.

The technical result is aimed at ensuring verification of the health of objects by measuring the parameters of the receiving channels: sensitivity and dynamic range.

The technical result is achieved by the fact that the automated control device contains a control object, a control and switching unit, a power supply, a communication and control device, an indication device, an input device, an input of a control and switching unit is a power input and is connected to the output of the power supply, and the output is a power output and is designed to connect the power input of the control object to it, the first input-output of the control and switching unit is designed to connect a control input-output to it control object, wherein it differs from the prototype in that it further comprises a high frequency generator. The second input-output of the control and switching unit is connected to the first input-output of the communication and control device, the first input of which is used to connect the video output of the control object to it, the second input is connected to the output of the command input device, and the input of the display device is connected to its output this second input-output of the communication and control device is connected to the input-output of the high-frequency generator, the output of which is designed to connect with it the second input of the control object.

Description

The utility model relates to automated test equipment and can be used to verify the operability of electronic equipment of complex objects. An automated control device can be used at various stages of the life cycle of complex objects from development to maintenance, as well as repair of complex objects during their operation.

An automated control device was selected as a prototype for the claimed technical solution (RU Patent for Utility Model No. 171563, IPC: G05B 23/02, published 06.06.2017), containing a control and switching unit and a power supply unit, an instruction input device, an indication device, and also a communication and control device consisting of a control electronic computer, a video information adapter, an adapter for a multiplex channel for information exchange, and an adapter for a radial channel for information exchange. In this case, the input of the control and switching unit is connected to the output of the power supply, and its output is intended to connect the power input of the control object to it, the first input-output of the control and switching unit is used to connect the control input-output of the control object to it, and its second input is the output is connected to the first input-output of the adapter of the multiplex channel of information exchange, and its third input-output is connected to the first input-output of the adapter of the radial channel of information exchange, the second inputs and outputs of the adapter are multi the information exchange Lexal channel and the information exchange radial channel adapter are connected to the second and third inputs-outputs of the control electronic computer, respectively, while the first input-output of the control electronic computer is connected to the input-output of the video adapter, the input of which is designed to connect to the video output of the control object, in addition, the output of the command input device is connected to the input of the control electronic computer, and connected to its output indication device input.

The technical problem solved by the creation of this utility model is the lack of the ability to verify the operability of objects by measuring the parameters of the receiving channels, which are usually contained in any radar station.

The technical result is aimed at ensuring verification of the health of objects by measuring the parameters of the receiving channels: sensitivity and dynamic range.

The technical result is achieved by the fact that the automated control device contains a control object, a control and switching unit, a power supply, a communication and control device, an indication device, an input device, an input of a control and switching unit is a power input and is connected to the output of the power supply, and the output is a power output and is designed to connect the power input of the control object to it, the first input-output of the control and switching unit is designed to connect a control input-output to it control object, wherein it differs from the prototype in that it further comprises a high frequency generator. The second input-output of the control and switching unit is connected to the first input-output of the communication and control device, the first input of which is used to connect the video output of the control object to it, the second input is connected to the output of the command input device, and the input of the display device is connected to its output this second input-output of the communication and control device is connected to the input-output of the high-frequency generator, the output of which is designed to connect with it the second input of the control object.

The essence of the claimed utility model is illustrated in the drawing, which shows a functional diagram of an automated control device.

The automated control device comprises a control and switching unit 1, a power supply 2, an input device for commands 3, an indication device 4, a communication and control device 5, a control object 6, and a high-frequency generator 7.

The input of the control and switching unit 1 is the power input and is connected to the output of the power supply 2, and its output is the power output and is designed to connect the power input of the control object 6 to it. The first input-output of the control and switching unit 1 is for connecting the control unit to it input-output of the control object 6.

The second input-output of the control and switching unit 1 is connected to the first input-output of the communication and control device 5, the first input of which is used to connect the video output of the control object 6 to it, the second input is connected to the output of the command input device 3, and the input is connected to its output indicating devices 4. In this case, the second input-output of the communication and control device 5 is connected to the input-output of the high-frequency generator 7, the output of which is designed to connect the second input of the control object 6 to it.

The automated control device operates as follows.

Before conducting a health check of the control object 6, the operator, through the command input device 3 into the communication and control device 5, selects the appropriate program designed to verify this control object 6.

When measuring the sensitivity of the receiving channel of the control object 6, the verification program sends a command to the high-frequency generator 7, by which the high-frequency generator 7, changing the attenuation of the built-in attenuator, sets the signal power level below the predicted sensitivity threshold of the receiving channel of the control object 6.

The receiving device of the control object 6 transfers the harmonic signal of the high frequency of the high frequency generator 7 to the intermediate frequency and digitizes it using an analog-to-digital converter (ADC). The computer complex of the control object 6 determines the voltage level of the signal at the ADC output and transmits its value to the communication and control device 5 for processing by the verification program.

In the absence of a signal or in the presence of a signal with a power level below the sensitivity threshold at the input of the receiving channel of the test object 6, the voltage level at the ADC output corresponds to the level of the noise of the receiver channel A1, mV.

After determining the voltage level of the intrinsic noise A1, mV, the verification program calculates the voltage level at the ADC output corresponding to the detection threshold of the signal of the receiving channel A2, mV:

A2 = X⋅A1, mV,

where X is the coefficient setting the signal detection threshold.

To determine the sensitivity threshold of the receiving channel, the test program transmits 7 commands to the high-frequency generator, according to which the high-frequency generator 7, changing the attenuation of the built-in attenuator, sets the signal power level P _min , W, at which the calculated value of the voltage level A2, mV at the ADC output is achieved .

The obtained power level P _min , W corresponds to the detection threshold value of the receiving channel signal, which is the sensitivity of the receiving channel of the control object 6.

To calculate the dynamic range of the receiving channel of the control object 6, it is necessary to determine the maximum signal power level at the input of the receiving channel of the control object 6, at which the signal is not distorted.

To determine the maximum power level of the signal at the input of the receiving channel of the test object 6, the test program sends 7 commands to the high-frequency generator, by which the high-frequency generator 7, changing the attenuation of the built-in attenuator, sets the signal power level P _max , W, at which the voltage level ADC output corresponds to the maximum allowable.

The value of the dynamic range D, dB of the receiving channel, the verification program calculates by the formula:

D = 10⋅lg (P _max / P _min ), dB.

As an indication device 4, which provides visualization of ongoing processes in the control object 6, for example, the FPM-317G ADVANTECH monitor can be used. As a command input device 3, for example, the MK-KTP5 AB-RS IEI keyboard with a touch pad can be used, which is connected to the communication and control device 5 via the PS / 2-PS / 2 KEY, PS / 2 MOUSE adapter. The supply voltage to the control object 6 is transmitted through the control and switching unit 1 from the power supply 2, which is configured to be connected to an external 220 V network. It is advisable to include a power supply in the power supply 2 (for example, MEAN WELL SP-320-27), a converter (e.g. PNBA13-2 / 115 / 400-03K) and a stabilizer (e.g. Lider PS2000W-50). In this case, the power source will be used to provide power to the control object 6 through the DC voltage circuit, the converter to provide power along the AC voltage circuit, and the stabilizer to ensure the stability of the power supply and the converter. As a high-frequency generator 7, a generator controlled by an electronic computer included in the communication and control device 5 was selected. High-frequency generator 7 is configured to generate harmonic signals (carriers) with frequencies in the range of operating frequencies of the receiving radar channels, while the dynamic range of its output power corresponds to the dynamic range of the receiving channels of the checked radar station (power).

Claims (1)

An automated control device for verifying the operability of electronic equipment, comprising a control and switching unit, a power supply unit, a communication and control device, an indication device, a command input device, an input of the control and switching unit is a power input and is connected to the output of the power supply, and its output is an output power supply and is designed to connect the power input of the control object to it, the first input-output of the control and switching unit is designed to connect the control input to it, you the course of the control object, characterized in that it further comprises a high-frequency generator, while the second input-output of the control and switching unit is connected to the first input-output of the communication and control device, the first input of which is intended to connect the video output of the control object to it, the second input is connected with the output of the command input device, and the input of the display device is connected to its output, while the second input-output of the communication and control device is connected to the input-output of the high-frequency generator, the output of which is significant for connecting to it the second input of the control object.

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