SU892682A1 - Device for testing radio noise meters - Google Patents

Description

(5) DEVICE FOR TESTING THE METERS OF RADIOMETERS

Claims (3)

The invention relates to a radio metering technique, in particular, to an apparatus for calibrating radio interference meters, and can also be used in monitoring communications and radar receiving devices operating in the mode of receiving pulse signals. Devices are known for calibrating radio interference meters in the mode of pulsed radio signals, comprising a sound generator, a square pulse generator, and a PZ modulator. The disadvantages of these devices are insufficient accuracy due to the instability of the parameters over time, as well as limited functionality that reduces the performance of the control. The closest technical solution to the invention is a DR-1 type radio pulse shaper containing a frequency source, a frequency divider, a first input connected to the output of a reference frequency source, an input device connected to the second input of a reference frequency source, an output unit connected to the output of the divider frequencies, a high-frequency modulator signal generator, a first input connected to the output of a high-frequency signal generator, a second input to an output of the output unit, and an output modulator a is the output of the whole shaper 2. The disadvantage of this device is that it outputs radio pulses of a fixed amplitude and duration, providing a limited range of variation of the spectral density and does not have a remote control mode, which reduces the accuracy of calibration. The purpose of the invention is to improve the accuracy of verification. The goal is achieved by the fact that the device for calibration of radio interference meters containing a reference frequency source, an input unit, a frequency divider connected to the output of the reference frequency source, a matching stage, a high-frequency signal generator, a modulator connected to the matching stage and with a high-frequency signal generator, a block of registers is connected, connected by an input with an output of an input block, and by outputs connected to a frequency divider and a high-frequency signal generator, a control unit, inputs connected connected to the block of registers and the block of input, and outputs connected to the frequency divider and high-frequency signal generator, interface unit, inputs and outputs connected to the register block and control unit, driver of time parameters, inputs connected to the output of the frequency divider, code input connected to the output a block of registers, control inputs and outputs connected to the control unit, an amplitude driver, a stop and a start input connected to the outputs of a time parameter generator, coded the input is connected to the register block, the control input is connected to the control block, and the output is connected to the input of the matching cascade. The drawing shows a block diagram of the proposed device. The device contains an input unit 1 connected to the inputs of the register 2 and control unit 3, an interface unit k connected to the inputs and outputs with the corresponding outputs and inputs of the register 2 and the control unit 3, the frequency source 5 connected to the frequency divider 6, the second and the third inputs of which are connected to the corresponding outputs of block 2 of registers and block 1 of control, and the output of divider 6 clock is connected to the input of the time generator 7, the second and third inputs of which are connected to the corresponding output The unit 2 registers and control unit 3, and whose start and stop outputs are connected to the corresponding inputs of the amplifier 8 amplitude, and the other inputs of the amplitude generator 8 are connected to the corresponding outputs of the register unit 2 and control unit 3, and the start and stop outputs 2 of which are connected to the corresponding inputs of the amplitude generator 8, the other inputs of the amplitude generator 8 are connected to the corresponding outputs of the register unit 2 and the control unit 3, and the output of the amplitude generator 8 is connected n to the input of the matching stage 9 9i matching stage output connected to a control input of the modulator 10 to a high frequency input of which is connected to the high frequency generator 11 signals. The device works as follows. Using the touch keyboard of the input unit 1, the operation modes (single or continuous) and digital values of the main parameters (modulation pulse repetition period, modulation pulse delay relative to clock pulses, modulation pulse duration, high frequency amplitude, high frequency sinusoidal signals) are set. The digital values of the parameters of the modulating pulses from the input block 1 are entered into the register 2 block, and the signs of the modes are entered into the control block 3. When working remotely as part of automated measuring systems, the digital values of the parameters and signs of the operating modes of the installation are set via the interface line through the interface block. Otherwise, the operation of the plant with local remote control is identical. The formation of signals with a given spectral density is as follows. From the source of the reference frequency 5 to the frequency divider 6 receives highly stable signals of the reference frequency. The value of the reference signals is chosen in such a way that the period of the follow-up of the reference signals is less than the permissible error in the formation of time parameters. Frequency divider 6 reduces the frequency of repetition of signals in accordance with the specified values of the generated time parameters. This expands the dynamic range of the generated parameters without reducing the accuracy of the formation of these parameters. The magnitude of the division factor for each formed parameter value is set to frequency dividers 6 from register 2 block by signals from control block 3. Pulses with indulgence frequencies 10, 0.1 MHz, 100, 10, 1 kHz; 10, 10, 1 Hz, etc. pulsed from source 5. This ensures the stability of the harmonics of the spectrum and its independence from the repetition frequency. The values of the secondary reference frequencies from the output of frequency divider 6 are fed to the time parameter generator 7. The time parameter generator 7 consists of three independent reading counters with preset code. Depending on the set value of the parameter, the corresponding binary-decimal codes are respectively recorded in the counters. The pulses from the divider 6, entering the counters, cause a decrease in the contents of the counters up to the zero state, which is detected by the counter transfer signal. The sequence of formation of time parameters is as follows. The transfer signal from the counter is the beginning of a period and serves to generate a sync pulse. From this time, the delay formation begins, i.e. the arrival of pulses from dividers 6 on the counter. When the number of pulses arriving at the subtracting input corresponds to the preset code, the counter generates a transfer signal, which is a Start signal and fixing the front of the modulating pulse. This signal permits the arrival of pulses from divider 6 to the input of the subtracting counter. The time interval from the sync pulse (Pulse to Start signal is equal to 1 delay value set in input block. Similarly, when a pulse number counter arrives at the subtracting input, corresponding to the modulating pulse duration code recorded in it. Pulse output appears at The stop time interval between the Start and Stop signals is equal to the modulating pulse duration set in the input device 1. To the code inputs of the driver 7 from the register block 2, using the signals from the control unit. "Of the line 3, the digital values of the significant part of the generated parameters are received. With the help of counting circuits, given the values of the parameters, the driver 7 determines the moment of delay of the modulating pulse relative to the sync pulse (time of the beginning of the modulating pulse), the moment of time the end of the modulating pulse and the instant of time of the end of the period of the formation of the modulating pulses. Start pulse forming the beginning of the output pulse, and a pulse termination time Stop End of generating an output pulse. The amplitude driver contains the switching circuit of the Start, Stop, Sign, control trigger, positive and negative pulse current amplifiers, respectively, output driver, output repeater, and pulse polarity switches. The code input of the amplitude generator B from the block of registers 2, the signal from the control unit 3 receives the specified amplitude code of the modulating pulse. In accordance with this code, the amplitude of the output pulse at the output of block 8 is set. The moment of the beginning and end of the output pulse at the output of the amplitude driver 8 corresponds to the beginning of the Start and Stop pulses at the input of the amplitude generator 8. The modulating pulse from the output of the amplitude generator B through the matching stage 9 goes control input of the modulator TO. The purpose of the matching stage 9 to ensure the minimum duration of the fronts of the modulating pulse. At the high-frequency input of the module 10 from the output of the frequency-frequency generator of signals 11, sine-shaped signals of a given amplitude and frequency are received. In the case of application of a programmable oscillator 1, the amplitude and frequency values of the high-frequency signals are sent to the generator 11 from the register block 2 via signals from the control unit 3. The formation of the resulting test signals of a given spectral density occurs in the modulator 10, where, under the action of modulating pulses, a radio-frequency pulse is formed from a continuous high-frequency signal. The spectral density of the output signal can be altered by changing the duration and amplitude values. The carrier frequency (average frequency of the formed spectrum) sweeps change with frequency tuning of the output signals at the output of the generator 11. The repetition period of the test signals can be changed by specifying the corresponding period values at the mapper 7. In addition, the delay of the test signals can be adjusted relative to sync pulses (reference signals by changing the delay values on the driver 7, which can be very valuable for calibrating radio receivers of radar and communication stations Thus, in comparison with the known ones, the proposed device, by introducing additional blocks, has wider limits for adjusting the spectral density of the test signals, and also has the ability to adjust the delay and repetition frequency of the test signals, which expands the range of application of the test setups. interface allows you to significantly increase the rate of change of the test signal parameters (signal amplitudes, repetition period duration, Selective micro voltmeters usually takes the C-in-time hours. When programming installation parameters (50–100 µs) through the interface block, the error is eliminated due to the time drift of the parameters of the device being scanned and, as a result, the resulting calibration accuracy is increased. The duration of the verification operation at volume 8 can be reduced by about 10 times. Claims An apparatus for calibrating radio interference meters comprising a reference frequency source, an input unit, a frequency divider connected to the output of the reference frequency source, a matching stage, a high-frequency signal generator, a modulator connected to the matching stage and a high-frequency signal generator, only so that, in order to improve the accuracy of verification, a block of registers is connected to it, connected by an input with an output of an input block, and by outputs connected to a frequency divider and high-frequency signal generator control unit, inputs connected to the register unit and the input unit, and outputs connected to the frequency divider and high-frequency signal generator, interface unit, inputs and outputs connected to the register unit and the control unit timing generator, inputs connected to the output of the frequency splitter, code input connected to the output of the register unit, control inputs and outputs connected to the control unit, amplitude driver, stop and start input connected to the output of the generator The time parameter generator, the code input connected to the register block, the control input connected to the control unit, and the output to the input of the matching helmet. Sources of information taken into account in the examination 1, Proceedings of the Institutions Committee of Standards, Measures and Instrumentation, Ditch at the USSR Council of Ministers, VNIIFTRI, vol., 65M ,, Standartgiz, 1962, 2, RF pulse generator FR-1, UI 3. Technical specification, 003.TO, Sync pulse