SU873133A1 - Stroscopic oscilloscope - Google Patents

Description

The invention relates to electrical engineering and can be used in automatic meters of nanosecond time intervals.

A known stroboscopic oscilloscope containing two mixers, a low-pass filter, a frequency to voltage converter, an adder, a voltage-controlled oscillator and a shaper of straws, impulses fl].

The disadvantage of this device is that it does not ensure the constancy of the duration of the measured time interval, the study of signals of any shape, and the measurement of time intervals with an unknown repetition rate of the input signal.

The closest to this invention by technical essence is a stroboscopic oscilloscope containing two stroboscopic mixers, the first inputs of which are connected to the buses of the signals under study, the second inputs to the output of the strobe generator, and the outputs to the inputs of amplifiers, the outputs of which are electronically connected to the second and third inputs a beam tube, the first input of which is connected to the output of the scan generator, the input connected to the output of the differential frequency allocation unit and the third input of the digital readout block the one whose first input is connected to the first input of the differential frequency allocation unit, the first input of the first switch and the output of the second voltage-controlled generator, the second input - to the third input of the first switch and the output of the control unit, the first input of which is connected to the second input of the second trigger and the first output the second duration normalizer, and the third input - with the first output of the first duration normalizer, the second output of which is connected to the first input of the first adder, the second input - with the output of the second amplifier I and the first input of the second duration normalizer, the first input of the first amplifier output, the second input of the second duration normalizer, the first input of the second trigger and the first input of the first trigger, the output of which is connected to the first input of the coincidence block, the output associated with the second input of the second trigger * the output of which is connected to the input of a sawtooth voltage generator, the output connected to the second input of the first adder and the first input of the second adder, the output of which is connected to the first input of the second control voltage, and the second input - with the third output of the second duration normalizer and the second input of the second voltage-controlled generator, the output of the first adder connected to the input of the first voltage-controlled generator, the output of the controlled phase shifter - with the second input of the differential frequency allocation unit, and the input of the strobe generator - with the output of the first switch [2

The disadvantage of this device is the long measurement time due to the long search time synchronization.

The purpose of the invention is the reduction of measurement time.

For this purpose, a stroboscopic oscilloscope containing two stroboscopic mixers, the first inputs of which are connected to the buses of the studied signals, the second inputs to the output of the strobe generator, and the outputs to the inputs of amplifiers, the outputs of which are connected to the second and third inputs of the cathode ray tube, the first input which is connected with the output of the sweep generator, the input connected to the output of the differential frequency allocation unit and the third input of the digital readout unit, the first input of which is connected to the first input of the output unit differential frequency, the first input of the first switch and the output of the second voltage-controlled generator, and the second input to the third input of the first switch, and the output of the control unit, the first input of which is connected to the second input of the second trigger and the first output, the second normalizer of duration, the second input to the second the output of the second duration normalizer, and the third input - with the first output of the first duration normalizer, the second output of which is connected to the first input of the first adder, the second input - with the third output torogo amplifier and the first input of the second duration normalizer, a first input - with the output of the first amplifier, a second input normalizer second duration, the first input of the second flip-flop and the first input of the first flip-flop, the output kotorog connected to the first input of the coincidence unit ,. the output of the second trigger connected to the second input, the output of which is connected to the input of a sawtooth generator, the output connected to the second input of the first adder and the first input of the second adder, the output of which is connected to the first input of the second voltage-controlled generator, and the second input to the third output of the second normal duration and the second input of the second voltage-controlled generator, the output of the first adder connected to the input of the first voltage-controlled generator, the output of the control the inventive phase shifter with the second input of the differential frequency isolation unit, and the input of the strobe driver with the output of the first switch, is equipped with a pulse divider and a second switch, the first input of which is connected to the output of the frequency divider and the input of the controlled phase shifter, the second input to the input of the frequency divider and the output of the first voltage-controlled generator, the third input - to the output of the second trigger, and the output to the second input of the first switch ', and the output of the differential frequency allocation unit connected to the second inputs of the first trigger and block matches.

The drawing shows a structural electrical diagram of the device. The device consists of two stroboscopic mixers 1 and 2, amplifiers 3 and 4, differential frequency separation unit 5, trigger 6, coincidence unit 7, trigger 8, sawtooth voltage generator 9, second switch 10, first adder 11 first voltage-controlled generator 12, first switch 13, shaper 14 of strobe pulses, first and second duration normalizers 15 and 16, frequency divider 17, control unit 18, second adder 19, second voltage-controlled generator 20, digital reading unit 21, controlled by zovraschatelya 22, sweep generator 23, a cathode ray tube (CRT) 24.

The device operates as follows.

In the absence of an input signal at the input of the stroboscopic mixer 1 at the output of amplifier 3, there is also no signal. The pulse of the differential frequency isolation block 5 overturns the first trigger 6, which opens the coincidence block 7. The next pulse of the differential frequency isolation block 5, passing the coincidence block 7, switches the second trigger 8, which includes the sawtooth voltage generator 9 and the switch 10. A large coefficient is set in the amplifier 3 gain. From this moment, the search for synchronization begins.

The sawtooth voltage generated by the generator 9 is supplied through the adder 11 to the input of the first voltage-controlled generator 12, as a result of which the frequency of this generator gradually increases from f _H to fg, where f || and - the lower and upper frequency of the generator 12, respectively.

to

The output signal of the generator 12 through the included switches 10 and 13 are fed to the input of the shaper 14 of the strobe pulses. The repetition rate of the strobe pulses varies from to f _B. When selecting f _B and f ^ values that differ by an octave, synchronization is provided for all signal repetition frequencies. The change in the frequency of the strobe pulses continues until there is no signal at the output.

If the repetition frequency of the input signal is lower than the repetition frequency of the strobe pulses, then the time scale of the input signal is converted in the frequency sampling mode, while the repetition frequency of the converted signal increases and its amplitude decreases.

After the signal arrives at the input of the stroboscopic mixer 1, the change in the repetition rate of the strobe pulses continues until the signal appears at the output of the amplifier 3. The output converted signal of the amplifier 3 front triggers normalizers 15 and 16 and switches triggers 6 and 8, thereby turning off the sawtooth voltage generator 9 and switch 10 .In amplifier 3, a lower gain is set. Duration normalizers 15 and 16 consist of duration comparators and duration-voltage converters connected in series. The pulse durations at the outputs of the comparators, equal to the durations of the converted measured time intervals (front, pulse duration, interval between two signals, etc.), are converted to voltage. The output voltage of the normalizer 15 passes ‘through the adder 11 and changes the frequency of the generator 12 so that the converted time interval becomes equal to the reference duration T |. When the switch 10 is off, the frequency of the signal of the generator 12 is divided in the divider 17 by η times. Having passed the switches 10 and 13, the signal arrives at the driver of the strobe pulses

14. This turns off the frequency sampling mode and turns on the normal sequential time-scale conversion mode. -

45,

When the time scale of the converted measured interval is set equal to the reference duration T ^, the duration normalizer pulse 15 includes a control unit 18, and the latter switches the switch 13, while the strobe generator 14 is started from the second voltage-controlled generator 20, the frequency of which is controlled by the voltage of the adder 19. The voltage at the output of the adder 19 is equal to the sum of the voltages of the sawtooth generator 9 and the duration normalizer 16. Adding the output voltage of the sawtooth voltage generator 9 makes it possible to more quickly reach a reference duration of 1½. Normalizer 15- conducts the duration to a predetermined value when the measured interval is more or less than the reference duration. Normalizer 16 performs normalization if the converted measured interval is shorter than the reference duration T ₂ . If the converted measured interval is longer than the reference duration T ^, then the control voltage is reset, a reset pulse is applied to the trigger 8 and control unit 18, the control unit 18 switches the switch 13 to the initial position / resets the digital readout unit 21, and synchronization search and normalization begin again duration. It. % continues until the measured time interval, when the normalizer 16 is turned on, becomes shorter than the second reference duration To., the condition is met. T _sig / m> f ^ p, where m

2.3 ... V.

at the same time, it provides 1, measurably, when setting the duration of the time interval, ta Ta., the normalizer 16 generates a pulse that starts the digital readout unit 21, as well as a time relay in the control unit 18, which after a certain time resets the readings of the digital readout unit 21 and switches the switch 13 to initial position, while the measurement cycle is repeated. The output signal: the frequency divider 17 is fed through a controlled phase shifter 22 to a differential frequency separation unit 5, and the signal of the second voltage-controlled generator 20 is fed to the inputs of the differential frequency separation unit 5 and digital reading unit 21. The repetition frequency of the signal at the output of the differential frequency isolation block 5 is equal to the frequency difference of the voltage-controlled oscillator 20 and the frequency divider 17. This difference is equal to the repetition period of the converted test signal. Therefore, if there is no signal at the output of amplifier 3 for two periods of its repetition, the synchronization search mode is activated, which allows to increase the measurement performance, in addition, the signal of the differential frequency allocation unit 5 starts the sweep generator 23 and enters the input of the digital readout block 21, when choosing T ^ = 2T ^. counts the number of frequency periods of the signal of the controlled oscillator 20, which fit into the period of the difference frequency. Measured by time

T ₄ Fp interval is t _M3 =, where

F _p - the differential frequency of the generator 20 and the frequency divider 17;

Г _st r _Г - the frequency of the generator 20., The sawtooth voltage of the generator 23 sweep is fed to the X plate of the CRT 24, on the plate of which the output signals of amplifiers 3 and 4 are received. When measuring the time interval between two signals, the second signal is fed to the mixer 2, to which also serves strobe pulses from the shaper 14 strobe pulses. The signal amplified in amplifier 4 is also fed to the normalizers when the switch is installed in the normalizers of the position durations Front and Recess, etc. Using a controlled phase shifter 22, the phase of one of the signals arriving at the differential frequency isolation unit 5 is changed, as a result of which the on-delay of the oscillator 23 is regulated . This allows . view on the screen of a CRT 24 a portion of the studied signals of interest to the operator.

Using the frequency sampling mode when searching for synchronization reduces the time to search for synchronization by 1000 times. An additional reduction in the measurement time is due to the fact that the search mode switches on after changing the frequency of the input signal no later than after two periods of the transformed studied signal.

Claims (2)

The invention relates to electrical measuring technology and can be used in automatic measuring nanosecond time intervals. A stroboscopic oscilloscope containing two mixers, a low-pass filter, a frequency converter into a voltage, an adder, a voltage-controlled generator and a forma- tor, and two pulses is known. The disadvantage of this device is that it does not provide the irtostate of the duration of the measured time interval, the study of signals of any shape and the measurement of time intervals at an unknown repetition frequency of the input signal. The closest to this invention in terms of technical nature is a stroboscopic oscilloscope containing two stroboscopic mixers, the first inputs of which are connected to the buses of the studied signals, the second inputs - with the output of the generator of pulses, and the outputs - with the inputs of amplifiers, the outputs of which are connected to the second and third inputs of the cathode ray tube, the first input of which is connected with the output of the sweep generator, the input connected to the output of the differential frequency allocation unit and the third input of the digital Counting, the first input of which is connected to the first input of the differential frequency selection block, the first input of the first switch and the output of the second voltage controlled generator, the second input to the third input of the first switch and the output of the control unit whose first input is connected to the second input of the second trigger and the first output of the second normalizer duration, and the third input - with the first output of the first normalizer duration, the second output of which is connected to the first input of the first adder second input - with the output of the second the amplifier and the first input of the second duration normalizer, the first input by the output of the first amplifier, the second input of the second duration normalizer, the first input of the second trigger and the first input of the first trigger, the output of which is connected to the first input of the coincidence unit, the output connected to the second input of the second trigger, the output of which is connected to the input of the sawtooth generator, the output connected to the second input of the first adder and the first input of the second adder, the output of which is connected to the first input of the watt the second input is connected to the third output of the second normalizer and the second input of the second controlled voltage generator, the output of the first adder connected to the input of the first voltage controlled generator, the output of the controlled phase shifter with the second the input of the difference frequency selection block, and the input of the strobe pulse former with the output of the first switch 2 J. The disadvantage of this device is the large measurement time, due to the large error caused by the search for blue ronization. The purpose of the invention is to reduce the measurement time. For this purpose, a stroboscopic oscilloscope containing two stroboscopic mixers, the first inputs of which are connected to the buses of the signals under study, the second inputs - with the output of the generator1 strobes, and the outputs - with the inputs of amplifiers, the outputs of which are connected to the second and third to the inputs of the cathode ray tube, the first the input is connected with the output of the sweep generator, the input connected to the output of the differential frequency selection block and the third input of the digital readout block, the first input of which is connected to the first input of the block the differential frequency allocation, the first input of the first switch and the output of the second voltage controlled generator, and the second input to the third input of the first switch, and the output of the control unit, the first input of which is connected to the second input of the second trigger and the first output of the second normalizer duration, the second input with the second output of the second normalizer of duration, and the third input - with the first output of the first normalizer of duration, the second output of which is connected to the n-first input of the first adder, the second input - with three The output of the second amplifier and the first input of the second normalizer duration, the first input with the output of the first amplifier, the second input of the second normalizer duration, the first input of the second trigger and the first input of the first trigger, the output of which is connected to the first input of the coincidence unit i output associated with the second the input of the second trigger, the output of which is connected to the input of the sawtooth generator, the output connected to the second input of the first adder and the first input of the second sum of the matrix, the output of which The second input is connected to the first input of the second voltage controlled generator, and the second input to the third output of the second normalizer and the second input of the second voltage controlled generator, with the output of the first adder connected to the input of the first controlled voltage generator. of the phase shifter - with the second input of the differential frequency selection block, and the input of the gate generator with the output of the first switch, equipped with a pulse frequency divider and the second switch, the first input The second input is connected to the input of the frequency divider and the output of the first voltage-controlled oscillator, the third input to the output of the second trigger, and the output to the second input of the first switch, with the output of the difference selection unit -. Noah frequency is connected with the second inputs of the first trigger and block of matches. The drawing shows the electrical circuit diagram of the device. The device consists of stroboscopic mixers 1 and 2, amplifiers 3 and 4, block 5 for differential frequency switching, trigger 6, coincidence block 7, trigger 8, sawtooth generator 9, second switch 10, first adder 11 of first voltage generator 12 , the first switch 13, the pulse generator 14, the first and second normalizers 15 and 16 duration, the frequency divider 17, the control unit 18, the second adder 19, the second voltage controlled generator 20, the digital readout unit 21 controlled by zovraschatel 22, sweep generator 23, a cathode ray tube (CRT) 24. The apparatus operates as follows. In the absence of an input signal at the input of the stroboscopic mixer 1 at the output of amplifier 3, there is also no signal. The pulse of the differential frequency allotment unit 5 overturns the first trigger 6, which opens the matching block 7. The next pulse of the differential frequency allocation unit 5, having passed the matching block 7, switches the second trigger 8, including the sawtooth generator 9 and the switch 10. In the amplifier 3, a large gain factor. From this point on, the synchronization search begins. The sawtooth voltage generated by generator 9 is fed through adder 11 to the input of the first voltage controlled generator 12, with the result that the frequency of this generator gradually increases from f to fg, where f and fg are the lower and upper frequencies of the generator 12, respectively. The output signal of the generator 12 through the included switches 10 and 13 post peiot input shaper 14 strobopulsov. The frequency of the strobe pulses varies from f to f. When selecting fg and f values different by octave, synchronization is provided for all signal repetition frequencies. The change in the frequency of strobe pulses continues as long as there is no signal at the output. If the repetition frequency of the input signal is lower than the repetition frequency of the pulse pattern, then the time scale of the input signal is converted in the mode of frequency samples, while the repetition rate of the converted signal increases and its amplitude decreases. After the signal arrives at the input of the stroboscopic mixer 1, the change in the frequency of following the strobe pulses continues until the signal appears at the output of amplifier 3. The output signal of the amplifier 3 is triggered by the front. The duration normalizers 15 and 16 and switches the switching voltage B and 8, thereby turning off the generator 9, a saw-tooth voltage and a commutator 10. In amplifier 3, a smaller gain factor is set. Normalizers 15 and 16 of duration consist of successively connected duration comparators and duration-voltage transducers. The pulse durations at the outputs of the comparators, which are equal to the duration of the converted measured time intervals (the front, the pulse duration, the interval between two signals, etc.), are transformed into voltage. The output voltage of the normalizer 15 passes through the adder 11 and changes the frequency of the generator 12 in such a way that the converted time interval becomes equal to the reference time Ti. When the commutator 10 is turned off, the signal frequency of the generator 12 is divided in divider 17 by n times. Pass the switches 10 and 13, the signal goes to the pulse shaper 14. This turns off the frequency sampling mode and turns on the normal sequential time-conversion mode. When setting the time scale of the transformed measured interval equal to the reference duration, the pulse of the normalizer 15 of duration switches on the control unit 18, and the latter switches the switch 13, while the pulse generator 14 is started from the second voltage controlled generator 20, the frequency of which is controlled by voltage Addition of the adder 19. The voltage at the output of the adder 19 is equal to the sum of the voltages of the generator 9 of the sawable voltage and the normalizer 16 of duration. Adding the output voltage of the sawtooth voltage generator 9 allows the reference duration to be reached faster. The normalizer 15-conducts the duration to the specified value when the measured interval is greater or less than the reference duration T. The normalizer 16 normalizes if the converted measured interval is shorter the reference duration T. If the converted measured interval 1l is longer than the reference duration T, then the control voltage is reset, the trigger 8 and the control unit 18 are impulsed with mildew, the control unit 18 switches the switch 13 to the initial polozhenieu unit 21 resets the digital readout, and again starts searching for synchronization and normalization duration. It. v lasts until the duration of the normalizer 16 is shorter than the second reference duration T-2 when the normalizer 16 is turned on, while the condition is maintained. fcHr / f CTP D m 1, 2.3 ... V. When setting the duration of the measured time interval equal to. Ta., The normalizer 16 generates a pulse triggering digital counting unit 21, as well as a time relay in control unit 18, which after a certain time resets the digital counting unit 21 and switches switch 13 to the initial position while the measurement cycle is repeated. The output signal of the frequency divider 17 through the controlled phase shifter 22 is supplied to the differential-frequency separation unit 5, and the signal of the second voltage-controlled generator 20 to the inputs of the differential-frequency separation unit 5 and the digital reference unit 21. The repetition frequency of the signal at the output of the difference-frequency allocation block 5 is equal to the difference of the frequencies of the generator 20 controlled by the impedance generator 20 and the frequency divider 17. This difference is equal to the repetition period of the transformed signal under study. Therefore, if during two periods of its repetition at the output of the amplifier 3 there is no signal, the synchronization search mode is activated, which allows to increase the measurement performance, in addition, the signal of the differential-frequency separation block 5 starts the sweep generator 23 and enters the input of the digital readout block 21, when choosing . the number of periods of the frequency of the signal of the controlled oscillator 20, laid down in the period of the difference frequency, is calculated, the measured time interval is equal to t ... FROM FP - difference frequency of the generator and frequency divider 17; The f-TDf-frequency of the generator 20. STR. / The sawtooth voltage of the sweep generator 23 is applied to X CRT plates 24, to which plate the output signals of amplifiers 3 and 4 are received. When measuring the time interval between two signals, the second signal is sent to mixer 2, which is also supplied with strobe pulses from a driver 14 strobe pulses. The amplifier 4 amplified in the amplifier is also fed to the normalizers when the switch is installed in the front and backward position duration normalizers etc. By using the controlled phase shifter 22, the phase of one of the signals coming to the difference frequency extractor 5 changes, resulting in the turn-on delay of the sweep generator 23 is controlled. It allows it. view on the CRT 24 screen the current of the studied signals, which is of interest to the operator. The use of the frequency sampling mode when searching for synchronization allows shortening the search time for synchronization by lOOO times. A further reduction in the measurement time is due to the fact that the search mode includes, after changing the frequency of the input signal, no later than two periods of the transformed signal under study. The invention consists of a strobing oscilloscope / containing two stroboscopic mixers, the nepBfcse inputs of which are connected to the buses of the signals under study, the second inputs - with the output of the strobe pulse generator, and the outputs - with the inputs of amplifiers, the outputs of which are connected to the second and third inputs of the cathode ray tube, the first input of which is h. with the output of the sweep generator, the input connected to the output of the difference difference frequency selection block and the third input of the digital readout block, the first input of which is connected to the first input b differential frequency allocation lock, first run of the first switch and. the output of the second voltage controlled generator, and the second input to the third input of the first switch and the output of the control unit, the first input of which is connected to the second input of the second trigger and the first output of the second normalizer of duration, the second input to the second output of the second normalizer of duration, and the third input is with the first output of the first normalizer of duration, the second output of which is connected to the first input of the first adder, the second input with the third output of the second amplifier and the first input of the second normalizer and the duration, first input, with the output of the first amplifier, the second input of the second Normalizer, the first input of the second trigger, and the second input of the first trigger, whose output is connected to the first input of the coincidence unit, the output connected to the second input of the second trigger, output which is connected to the input of the sawtooth generator, the output connected to the second input of the first adder and the first input of the second adder, the output of which is connected to the first input of the second controlled voltage generator a, and the second input with the third output of the second duration normalizer and the second input of the second controlled voltage € M of the generator, the output of the first adder connected to the input of the first voltage controlled generator, the output of the controlled phase shifter - with the second input of the difference frequency selection block and the input of the gate generator with the output of the first switch, which is also distinguished by the fact that, in order to reduce the measurement time, it is equipped with a pulse following frequency divider and a second switch, the first input of which connected to the output of the frequency divider and the input of the controlled phase shifter, the second input to the input of the frequency divider and the output of the first voltage controlled generator, the third input to the output of the second trigger, and the output to the second input of the first switch, and the output of the differential differential section Frequencies are associated with the second inputs of the first trigger and block of matches. Sources of information taken into account in the examination 1.US Patent I 3416087, cl. 328-151,1968. 2. Authors certificate of the USSR. No. 521521, cl. G 01 R 13/20, 1974 (prototype). -H