SU970233A1 - Stroboscopic oscilloscope with sweep non-linearity correction - Google Patents

Description

The invention relates to electrical engineering and can be used in automated stroboscopic oscilloscopes.

Known stroboscopic oscilloscope containing a stroboscopic converter and a built-in sweep calibrator [1].

The disadvantage of this device is the low speed of the correction process for the nonlinearity of the scan.

Closest to the proposed jio technical essence is a stroboscopic oscilloscope with correction of nonlinearity of the scan, containing a stroboscopic converter, the first input of which is connected through the switch to the output of the scan calibrator, the output is connected to the input of the calculator, and the second input is connected to the output of the comparator, the first input of which is connected to the output generator of fast sawtooth voltage, and the second input to the output of the digital-to-analog sweep converter, the input of which is connected to the output of the calculator, and in the course of the fast sawtooth voltage generator is connected to the output of the synchronizer, the input of which through the switch _{t is} connected to the output of the sweep calibrator [2].

The disadvantage of this device is the low speed of the process of correcting the nonlinearity of the sweep, due to the need to re-select the period of the follower of the calibrator signal when the investigated signal changes.

The purpose of the invention is the acceleration of the correction process.

The goal is achieved due to the fact that a stroboscopic oscilloscope with correction of nonlinearity of the scan containing a stroboscopic converter, the first input connected to the output of the comparator, the first input of which is connected to the output 2θ of the fast sawtooth voltage generator, and the second input to the output of the digital-to-analog scan converter, the input of which is connected with the output of the calculator, and the input of the fast sawtooth voltage generator is connected to the output of the synchronizer, equipped with a time interval meter, whose first input is connected to the synchronization output. jam, the second input with the output of the comparator, and the output with the input of the calculator, the first input of the stroboscopic converter connected to the bus of the signal under study, and the input of the synchronizer to the signal bus, the synchronization channel.

‘The drawing shows a structural 5 electrical diagram of the device.

The device consists of a stroboscopic converter 1, a synchronizer 2, a fast saw voltage generator 3, a comparator 4, .10 • a digital-to-analog converter (DAC) 5 | sweep, a meter of time intervals and a calculator 7.

The device operates as follows. ί 15

The synchronization signal is fed to the input of synchronizer 2. The output of the synchronizer, standardized in shape and rigidly tied in phase to the synchronization signal jq, starts the generator 3 fast sawtooth voltage. At the moment of equality of the fast sawtooth voltage and the increasing stepwise sawtooth voltage from the output of the DAC 5 sweep, the comparator 4 generates a strobe pulse. The strobe (pulses automatically shift in time relative to the signal under investigation. At the output of the stroboscopic converter 1, a sequence of extended pulses is generated. Voltages, the amplitude envelope of which follows the shape of the signal under investigation. During the automatic calibration phase, the device operates in self-oscillating mode and the converted signal the indicator screen 8 is not displayed. Block 6 measures the time interval between the start pulse of the generator 3 and the strobe pulses. of the interval for each value of the step-like sawtooth voltage generated by the DAC 5 sweeps are recorded in the memory of the calculator 7. Then 45 these results are compared in the calculator 7 with the values of the reference time intervals, which correspond to a linearly changing fast sawtooth voltage and depend on the value __ slot per one scan point. As a result of comparison _of calculated values of deviations from the reference values of intervals of time that are used calculator 7 as the correction coefficients when forming the corrected DAC code 5. This code is formed in such a way that deviations from the reference values of time intervals are equal to zero.

In the measurement phase, when the device is in standby mode and the converted signal is displayed on the indicator screen, when the DAC 5 of the slow scan of the indicator is formed at each point on the scan line, nonlinearity is corrected due to the nonlinearity of the fast sawtooth voltage.

The device allows you to accelerate the correction process, providing its automation ·.

Claims (2)

The first input of the stroboscopic converter is connected to the bus of the signal under study, and the synchronizer input to the signal bus of the synchronization. The drawing shows a structural electrical circuit of the device. The device consists of a stroboscopic converter 1, a synchronizer 2, a generator 3, a fast saw voltage, a comparator 4, a D / A converter CTSAP) 5 1 sweep, a time interval meter and a calculator 7. The device operates as follows. . . The synchronization signal is fed to the synchronizer input 2. A synchronizer output signal, standardized in shape and rigidly coupled in phase to the synchronization signal, triggers the generator 3 fast sawtooth voltage At the moment of equality of the fast sawtooth voltage and the increasing step sawtooth voltage from the output of the DLC A 5 sweep comparator 4 produces a strobe pulse. Strobe pulses are automatically shifted in time relative to the subject from the bank. At the output of the stroboscopic converter 1, a sequence of extended voltage pulses is formed, the envelope of which amplitudes repeat the shape of the signal under study. During the automatic calibration phase, the device operates in the self-oscillation mode and the converted signal on the display of the indicator 8 is not output. The unit 6 measures the time interval between the start pulse of the generator 3 and the strobe pulse. The results of measuring the time interval for each value of the stepped sawtooth voltage generated by the DAC 5 sweep are recorded in the memory of the calculator 7. Then the results are compared in the calculator 7 with the values of the reference time intervals, which correspond to a linearly varying fast sawtooth voltage and depend on the value of the time interval corresponding to one sweep point. According to the comparison results, the values of deviations from the values of the reference time intervals are calculated, which are used by the calculator 7 as correction coefficients when generating the corrected DAC code 5. This code is formed so that the deviations from the values of the reference time intervals are equal to zero. In the measurement phase, when the device is in standby mode and the converted signal is displayed on the indicator screen, the non-linearity correction due to the non-linearity of the fast sawtooth is corrected when the slow-scan indicator DAC 5 is formed at each point on the scan line. The device allows you to speed up the process of correction, ensuring its automation. A stroboscopic oscilloscope with nonlinearity correction sweep containing a stroboscopic converter, the first input connected to the output of the comparator, the first input of which is connected to the output of the fast sawtooth generator, and the second input to the output of the digital-to-analog conversion converter, the input of which is connected to the output a transmitter, the input of the fast sawtooth generator is connected to the synchronizer output, characterized in that, in order to accelerate the correction process It is provided with a meter time slots, a first input of which is coupled to the output of the synchronizer, the second input - with the output of the comparator, and the output - to the input of the calculator, wherein the first input stroboscopic converter connected to the bus of the signal, and input synchronizer - the bus clock signal. Sources of information taken into account in the examination 1. Description of the oscilloscope C 7-17, USSR, 1980. 2. Description of the automatic signal analyzer MEVL company Anritsu, (Japan), 1980 (prototype ;.