SU972471A1 - Stroboscopic time interval meter - Google Patents

Description

(54) STROBOSCOPIC MEASURER OF TEMPORARY INTERVALS

one

The invention relates to instrumentation and measurement technology and can be used to measure a periodic sequence of nanosecond time intervals.

A stroboscopic meter is known that contains two quartz oscillators, a strobe pulse generator, a stroboscopic mixer, an amplifier expander, a beat signal detector; pulse generator, delay element, control unit and phase shifter 1.

The closest to the invention to the technical essence is a meter containing a beat signal detector, connected at the output of two quartz oscillators, two strobe mixers, inputs connected to the meter input buses and the output of the strobe pulse generator, and outputs connected to the Corresponding amplifiers whose outputs are connected to two inputs of the first switch, the first

The output of which is connected to the first input of the first amplitude gauge and to the first input of the first comparison unit, the second output of the switch is connected to the first input of the second comparison unit and the first input of the second amplitude meter, the outputs of the first and second amplitude meters are connected to the second inputs of the respective comparison blocks, the outputs of which connected to the inputs of the first trigger, the delay unit is connected to the output of the first crystal oscillator and to the input of the start-up pulse shaper, the outputs of the delay unit are connected. The first input of the second switch, the second input of which is connected to the output of the second, crystal oscillator, the detector output is connected to the input of the control unit, the outputs of which are connected to the third input of the second switch, to the inputs of the first and second triggers, the second input connected to the output of the first trigger, and the output of the second trigger connected to the control inputs of the first and second quartz oscillators 2.  The disadvantages of the known gauges are the low accuracy and the long measurement time of the time intervals.  One of the main components of the measurement error is the instability of the frequency difference between quartz oscillators.  The long measurement time is associated with the limited ability to detun the quartz oscillators and change the starting delay.  The latter causes a noticeable increase in the measurement time when measuring time intervals on the decays of the pulses under study.  The absence of p-modulation on the screen of the low-frequency oscilloscope of the measured time interval, logrg level 1 and logical O reduces the accuracy of measurements and makes it difficult to adjust the meter.  The whole invention is to improve the accuracy, speed and integrity of the measurements.  The goal is achieved by the fact that in a stroboscopic time interval meter containing two quartz oscillators, the output of the first of which is connected to the first input of the beat signal detector and the input of the delay unit, the output of the second crystal oscillator is connected to the second input of the beat signal detector, two mixers, the first the inputs of which are connected to the corresponding input tires of the meter, and the second - to the output of the gate generator, and the outputs of the first and second mixers through the first and second respectively the amplifiers are connected to the inputs of the first switch, the first output of which is connected to the first inputs of the first amplitude meter and the first comparison unit, the second output of the first switch is connected to the first inputs of the second amplitude meter and the second comparison unit, the outputs of the first and second amplitude meters are connected to the second inputs, respectively, of the first and second comparison units, the outputs of which are connected to the trigger inputs, the output of which is connected to the first input of the reference block, the second input of which is connected to the first output The control unit, the second output of which is connected to the first input of the second switch, the output of which is connected to the input of the strobe pulse former, and the trigger pulse former, the output of which is connected to the first BUS, has four splitters, two controlled delays, two blocks pre-installation, three switches, standby multivibrator, phase detector, AND and OR elements, two comparison locations, a signal detector and a trigger generator, the output of the second crystal oscillator connected to the first inputs of the first, second and third frequency dividers, the output of the first crystal oscillator is connected to the first inputs of the third switch and the first preset unit, the first output of which is connected to the second input of the third switch, the output of which is connected to the first input of the fourth frequency divider, second input; which is connected to the second input of the first frequency divider and the output of the first presetting unit, the second input of which is connected to the third output of the control unit, and the third is connected to the output of the first beat signal detector, the first inputs of the phase detector and the And element, the second input of which is connected to the output of the waiting the multivibrator and the output to the second input of the third frequency divider, the output of which is connected to the input of the waiting multivibrator and the second input of the phase detector, the output of which is connected to the input of the first quartz oscillator, the output of the first comparison unit through the second presetting unit is connected to the third inputs of the reference unit and the fourth frequency divider, whose output through the first controllable delay unit is connected to the second input of the second switch and the first input of the second beat signal detector, the second input of which connected to the output of the first frequency divider and the input of the first driver pulse start, and the output through the second driver pulse start - with the second output bus meter, additional The pilot outputs of the first amplitude meter are connected to the first input of the third comparison unit, the second input of which is connected to the first output of the first and first inputs of the fourth switch, the third input of the third comparison unit is connected to the fourth output of the control unit, the first input of the fourth comparison unit and the second input of the fourth switch, the third input of which is connected to the second output of the first switch and the second input of the fourth comparison unit, the output of which is connected to the first input of the OR element, the second and the third inputs of which are connected respectively to the outputs of the third comparator unit and the trigger, the output of the OR element is connected to the third output bus of the meter, the additional outputs of the second amplitude meter are connected to. the third input of the fourth comparison unit, the first output of the nth switch is connected to the second input of the second frequency div, the output of which is connected to the first input of the second controlled delays block, the second input of which is connected to the second output of the fifth switch, and the output of the third the input of the second switch, the outputs of the delay unit are connected to the third inputs of the third switch, the second inputs of two amplitude meters and the input of the fifth switch are connected to the fourth output of the control unit whose input is connected to the output Ohm of the second comparison unit, the output of the fourth switch is connected to the fourth output bus of the meter.  FIG.  1 shows a structural diagram of a meter; in fig.  2 - a possible variant of the pre-installation block scheme.  The meter consists of mixers 1 and 2, amplifiers 3 and 4, the first switch 5, meters 6 and 7 amplitudes, the first and second blocks 8 and 9 of the comparison, the generator 10 strobe pulses, the block 11 delays, trigger 12, the first second, third and fourth dividers 13 - 16 frequencies, control delay delays 17 and 18, second switch 19 of control block 20, third and fourth blocks 21 and 22, comparison, reference block 23, third switch 24, fourth and fifth switches 25 and 26, first and second blocks 27 and 28 preset, first and second crystal oscillators 29 and 30, OR gate 31, the first and second detectors 32 and 33 of the beat signal, a phase detector 34, the formation of the first and second ers 35 and 36 of the trigger pulses, AND gate 37 and monostable multivibratora3 Operation is as follows.  The device allows setting both absolute (in volts) and relative (in fractions from the pulse amplitude) time interval reference levels.  When absolute reference levels are set in gauges 6 and 7 of the amplitudes of one generator, voltage levels of the beginning and end of the reference time interval are set.  These voltages are applied to the first and second blocks 8 and 9 of the comparison.  The control unit 20 generates a pulse, resetting the readings of the reference unit 23.  The impulse from the third output of the control unit 20 is supplied to the presetting unit 27.  The presetting unit 27 and the delay unit 11 serve to increase the measurement speed.  The presetting unit 27 may comprise, for example, two serially connected frequency dividers 39 and 40, as well as the memory unit 41.  The operation of the presetting unit 27 in this case is as follows.  Each pulse of the first detector of the 32 beat signals produces a zeroing of the dividers 39 and 4 of the frequency.  The output pulses of the first crystal oscillator 29 produce a counting of pulses in the dividers 39 and 4 O frequencies.  The division factor of the frequency divider 39 is chosen equal to Г) - Q (1) where О is the transformation factor of the time scale; at 1 - the number of delay stages in the block 11 delays; - the repetition period of the first crystal oscillator 29; J.  - the delay time of one stage of the delay block 11 delays.  The division factor of the 40 divider frequency is g.  The output code of the frequency divider 40 is fed to the input of the memory unit 41 (e.g., to the inputs of the D-triggers).  The output code of the memory block 41 is controlled by the switch 24.  The impulse of the control unit 20 entering the presetting unit 27 includes an element 42, and after that the output pulse of the detector 32 of the beat signals 32 not only clears frequency dividers 39 and 40, but also clears the first and fourth frequency dividers 13 and 16, as well as writing to the block 41 of the memory code divider 1 40 frequency.  By zeroing the first and fourth frequency dividers 13 and 16, the phase difference (time delay) of the output signals of the dividers accumulated in them is zero.  Switching the outputs of the block 11 of delays using the third switch 24 provides partial compensation of the instantaneous phase difference of the quartz oscillators 29 and the DA.  The presetting unit 28 serves to increase the speed of measurement of long time intervals in case of cx when this duration is approximately known (e.g., more than 10 not, 50 HC, and so on.  P. ).  Then, the output impulse of the comparison unit 8 starts the presetting unit 28, which in turn shifts the readings of the frequency divider 16 by a certain value.  This allows the breakdown of a portion of the measured time interval.  At the same time, the presetting unit 28 controls the reference unit 23, where the duration of the breakthrough is measured.  In addition, by presetting the frequency divider 16, the strobe pulse delay is changed relative to the signal from O to tc, where tj.  - the period of repetition of the signal under study, by steps through the Preset Setting of the frequency divider 16 and the delay in the controlled delay block 17, which provides a delay to ((), you can set the beginning of the time scale conversion at any point in the period of the signal under study.  This allows you to increase the speed of the meter, and especially when measuring time intervals on the decay of the signals under study.  The signal of the second crystal oscillator 30, divided by frequency in the frequency divider 13 and formed in the start driver 35, starts the circuit under study (not shown).  The signals of the studied circuit are fed to the stroboscopic mixers 1 and 2.  Short strobe pulses are supplied to the second inputs of the mixers, synchronous with the signals of the first crystal oscillator 29, the third switch 24, divided by frequency in the frequency divider 16, the controlled delay block 17, the second switch 19 and the driver 10 strobe pulses.  The frequency of quartz gene. " Ratters 29 and 30 differ by a small amount.  The magnitude of this difference lac can be measured at the output of the 11 detector of 32 beat signals (the T-trigger can serve as a detector) II is equal to F-io-fao 5 where fn lioQ is the frequency of the quartz oscillators 29 and 30.  Since the transformation ratio and the magnitude of 1 in the read step depends on the magnitude and stability of the difference frequency, then for c. In order to stabilize its magnitude, the output signal of the detector of the beat signal 32 is fed to the input of the phase detector 34 (c. For example, the series-connected element EXCLUSIVE OR and active RC can serve as a phase detector. -filter).  The second input of the phase detector 34 is supplied with a signal from a crystal oscillator 30 divided by frequency in frequency divider 15.  Under the action of the control voltage of the phase detector 34, the frequency of the quartz oscillator 29 is adjusted so that the frequency difference of the quartz oscillators 29 and 30 becomes equal to 7.0 I I1, (3) goes to the frequency divider 15 in the frequency divider 15.  Due to the fact that the signal at the output of the frequency divider 15 is formed from the signal of the crystal oscillator 30, the transformation ratio of the time scale of the stroboscopic meter remains constant even with significant frequency instability of this generator and is equal to (4) To make the device easier to enter automatic tuning of the frequency, the output signal of the frequency divider 15 starts the waiting multil T1 tibrator 38.  If the pulse of the multivibrator 38 does not coincide with the leading edge of the output signal of the detector 32 of the beat signal, the And 37 element is turned on, the latter produces a reset pulse, embedding the frequency divider 15.  Resetting the frequency divider 15 is repeated until these pulses coincide in time.  When the temporal coincidence of the pulse of the standby multivibrator 38 and the leading edge of the signal of the detector is 32 beat signals, the phase detector 34 provides automatic tuning of the frequency of the crystal oscillator 29.  Resetting the frequency divider 15 allows the bandwidth of the automatic frequency control to be significantly expanded.  At the outputs of the stroboscopic mixers 1 and 2 there are input signals converted in time.  The magnitude of the transformation factor of the time scale is determined by the expression (1).  Signals with a transformed time scale are set at amplifiers 3 and 4, the first 5 c switch passes to the blocks 8 and 9 of the comparison.  The switch 5 allows the signals of the first and second channels to be sent to block 8 or block 9 of the comparison as chosen by the operator, which makes it possible to measure both the time intervals between the two signals and the temporal parameters of the pulse (the latter are sent to both blocks 8 and 9). A single channel signal is supplied.  If the level of the signal supplied to comparison unit 8 and the constant level set by the operator in the amplitude meter 6, the unit 8 is equal, a pulse is generated that overturns the trigger 12 "With the equalization of the signal supplied to the comparison unit 9 and constant. The first level set by the operator in the amplitude meter 7, in block 9, a pulse is generated, which returns trigger 12 to the initial state.  The output pulse of the trigger 12, which is equal in duration to the duration of the measured time interval in the converted time scale, is fed to the reference block 23 where it is filled with counting pulses and counted by the counter.  The duration of the measured time interval is counted on the board.  In addition, the pulse of the comparison unit 9 is supplied to the control unit 20, where a pulse is generated that prohibits a second counting in the reference unit 23 and, during internal startup, starts an electronic time relay installed in the control unit 2O.  After the next start pulse (or the electronic time relay pulse) arrives, the measurement is repeated.  By changing the frequency ratio (54) of the division INSIDE of the frequency dividers 13 and 16, measurements are made at several fixed frequencies of the signal under study, and by changing the division factor of the frequency divider 15, the change in the ratio of the time scale of the signals under study.  To increase the reliability of measurements, it is possible to control the measured time interval on the screen of the low-frequency oscilloscope.  For this purpose, a switch 25 is installed, the output of which can be connected to an oscilloscope (not shown), on the screen of which you can view 1x: both input signals in the converted time scale.  The synchronization of the start of the oscilloscope and the beginning of the time scale transformation is provided by the formation of a pulse triggering oscilloscope using the beat signal detector 33, the input of which is fed from the outputs of the frequency divider 13 and the control unit 17 for controlling the delay.  The output signal of the beat signal detector 33 is formed in the driver 36 and is output.  The trigger pulse 12, the last element OR 31, arrives at the output for the luminous modulus w of the section of the oslographic image of the syntax studied, corresponding to the measured interval.  When measuring time-1-W1X intervals between relative reference levels (in fractions of the amplitude of the signals under study), the pulse amplitudes are measured first, and the reference levels are set.  Thereafter . The measurement of the 1shter-hall is made as described.  To measure the pulse amplitude, the following operations are performed.  First, it is necessary to establish the location of the amplitude (logical 1) and zero level (logical O).  These operators are produced by the operator during setup of the meter for a specific type of pulse (for example, for a particular Tima of the chips under study).  The setting is as follows.  After switching the pexaiMa meter to relative reference levels |, the start pulse of the control unit 2O switches the switch 19.  In this case, the driver 10 of the strobe pulses is disconnected from the output of the control decelerating block 17 and connected to the control delayed block 18.  Consequently, the start of the strobe pulses occurs at the yi-th pulse of the crystal oscillator 30, where -K034x}) HiBieHT divides the frequency divider 14, equal to the frequency ratio (|) of the divider divisors 16 and 13 of the frequency.  Since the circuit under study in this cjryiae and the strobe pulses are triggered synchronously to the signal of the quartz oscillator 30, it means that there is no shift of the strobe pulses in this case and the schenp gating is performed in one.  Simultaneously with switch 19 of switch 19, a control impulse appears at the output of unit 20, including measuring circuit for measuring amplitude value (logical 1) in meter 6 and switch 26 connecting control unit to its outputs. Setting log.  1, Start  With this, the pro-  A presetter of the frequency divider 14 is determined for the determination of the number of pulses carried out, setting the (coarse) temporal position of the strobe relative to 1 signal.  The exact setting of the strobe pulse delay (the duration of the shorter repetition period of the 1-S oscillator generator) is made by a controllable de-gash unit 18 (for example, a multivibrator with a controlled pulse duration), a control element (potentiometer, adjustable current source, and so on. ) which also commutes. switch 26.  The sum of the delays obtained by presetting the second frequency divider 14 and the pulse delay in the controlled delay block 18 determines the initial delay of the pulse relative to the signal under study.  Consequently, the gating of the investigated signals, entering the inputs of mixers 1 and 2, at one point occurs.  The output voltage of mixers 1 and 2, proportional to the instantaneous values of the input signals, is amplified in. amplifiers x 3 and 4 and goes to switch 5.  At the choice of the operator, any of these signals can be selected with a Start or Stop signal (the Start-from signal of a certain level WHICH begins the counting of the time interval, the Stop signal - from a certain level of which the counting of the temporal level stops).  The start signal is fed to the input of a 6 amplitude meter, where the instantaneous value of the signal is measured.  After that, the control unit 20 switches the amplitude meter 6 to the measurement of the zero (logical O) level, and in the switch 26 controls are connected to its outputs. Setting the log.  Oh, Start.  Similarly, the installation of the new time position of the strobe impulse relative to the signal, measurement and storage of the new instantaneous value of the start signal in the 6 amplitude meter.  Similarly, the measurement of the amplitude and zero values of the Stop signal in the meter 7 amplitudes and switching to the outputs of the switch 26 controls is made. Setting the log.  1, Stop and Set log. ABOUT, .  Stop.  Consequently, thereafter, at the second and third outputs of the meters 6 and 7 amplitudes, there is a voltage equal to the four instantaneous values of the two signals under study.  The control unit 20 removes the pulse from the fourth output, and the second switch 19 returns to its initial state, generating a pulse at the second output, which is the initial phase setting. shock pulse.  (triggered by the synchronous signal of the quartz oscillator 29) and the signal under study (triggered synchronously to the signal of the quartz oscillator 30).  A sequential conversion of the time scale of the studied signals begins.  The converted and amplified signals under study pass the switch 5 and come: the Start signal to the comparison unit 21 (which can be, for example, the 521CA1 chip) and the switch 25, and the Stop signal to the fourth comparison unit 22 and the switch 25.  The inputs of the third and fourth blocks 21 and 22 receive output voltages from the outputs of meters 6 and 7, respectively, of amplitudes.  Since at these outputs of the meters 6 and 7 there are voltages equal to two measured instantaneous values of the Start and Stop signals, respectively, then, at the outputs of the comparison blocks 21 and 22, a signal appears when the instantaneous value. The converted signals exceed the voltage level at the second outputs of the amplitude meters 6 and 7, and the instantaneous values of the converted signals are less than the voltage levels at the outputs of the meters 6 and 7.  The output signal from the control unit 20 is fed to the inputs of the comparison units 21 and 22 and the switch 25.  This signal of block 20 switches the output of the nth switch 25 in such a way that the Start signal or the Stop signal alternately connects to its output.  Simultaneously with the switching on the output of the switch 25 of the Start signal, the pulse of the block 2O switches on the comparison block 21 (for example, control of the 521CA1 chip through the Gating inputs), and when connected to the output of the switch 25, the comparison block 22 is turned on.  The output pulses of the comparison units 21 and 22 pass the OR 31 element and arrive at the output of the meter.  When this output is connected to the input j of the low-frequency oscilloscope, and the output of the switch 25 to the input of the same oscilloscope, the transformed signals are viewed on its screen.  The bright beam modulation on a cathode ray tube separates the areas of the transformed signal that exceed the instantaneous voltages of the signals under study, the temporal position of which is set by the controls Setting Log.  1, Start and Stop, and becomes less than the instantaneous voltages of the studied signals, the time of which the position is determined by the controls. Setting the log.  Oh, Start and Stop.  Consequently, when changing the position of the 139 controls. Setting the log.  1 and log.  O, Start and Stop change the instantaneous values of the signals under study, which are measured and stored in meters 6 and 7 amplitudes.  Thus, by adjusting these controls and controlling the installation of the instantaneous value of the signal under investigation on the screen of the low-frequency oscilloscope, expand the functionality of the meter and measure the instantaneous values of signals of nanosecond durations.  The operator during the adjustment control controls Setting the log.  1 and log.  O, Start and Stop sets the time positions of strobe pulses so that the instantaneous values of signals stored at the outputs of meters 6 and 7 amplitudes correspond to the amplitude values (logical 1) of Start and Stop, respectively, and at other outputs of meters 6 and 7 - zero levels (logical O) of the same signals.  In meters 6 and 7, from the voltages corresponding to the amplitude and zero: Signal levels, the amplitude of the pulse is determined (for example, by using a subtraction circuit on the operational amplifier), the voltage generated by the required fraction of the pulse amplitude (0.1; 0.2; 0.5 and so on.  d. required by the program or set by the operator; the procedure can be performed using a D / A converter) and testing the required reference level (summing up, for example, an operational amplifier, the voltage obtained corresponding to the required amplitude fraction with a zero signal level).   The use of new elements and connections allows to increase the accuracy and speed of measurements.  In addition, the proposed device eliminates the undesirable periodic frequency tuning of quartz oscillators.  By changing the division ratio of frequency dividers 13 and 16, operation at several fixed frequencies is provided, which extends the functionality of the meter.  The measurement result can be monitored on the screen of any low-frequency oscilloscope.  On the screen of the low-frequency oscilloscope, using the luminance modulation, both the measured time interval and the amplitude levels of logical 1 and logical O are highlighted.  7114 This indication on the screen of the meter: llograph and the possibility of changing the time of the measured levels, extends the functionality of the meter to measure the instantaneous values of signals of nanosecond duration.  Formula and. invention Stroboscopic measurement intervals containing two quartz oscillators, the output of the first of which is connected to the first input of the detector -. IG of beat beat and block inlet shut.  The second quartz oscillator connects to the second input of the beat detector, two mixers, the first inputs of which are connected to the corresponding input buses of the meter and the second to the output of the strobe pulse generator, the outputs of the first and second mixers through the first and second amplifiers respectively connected to the inputs of the first switch torus, the first output of which is connected to the first inputs of the first amplitude gauge and the first comparison unit, the second output of the first switch is connected to the first inputs of the second amplitude gauge and the second comparison unit, you first and second amplitude meters are connected to the second inputs of the first and second comparison blocks, respectively, the outputs of which are connected to the trigger inputs, the output of which is connected to the first input of the reference block, the second output of which is connected to the first output of the control unit, the second output which is connected to the first input of the second commutator, the output of which is connected to the input of the strobe impulse generator, and the start pulse shaper, the output of which is connected to the first output bus, due to the fact that, in order to increase the accuracy, speed and reliability of the measurements, four frequency dividers, two controllable delay units, two presetters, three switches, a waiting multivibrator, a phase detector, elements AND and OR, two comparison units , a beat signal detector and a start pulse shaper, the output of the second quartz oscillator is connected to the first inputs of the first, second and third frequency dividers, the output of the first quartz oscillator is connected to the first inputs of the third switch Ator and first unit (preset, first exit

which is connected to the second input of the third switch, the output of which is connected to the first input of the fourth frequency divider, the second input of which is connected to the second input of the first frequency divider and the output of the first preset unit, the second input of which is connected to the third output of the control unit, and the third is connected to the output the first detector of the beat signals, the first inputs of the phase detector and the element I, the second input of which is connected to the output of the waiting multivibrator, and the output to the second input of the third divider frequency, the output of which is connected to the input of the standby -15 multivibrator and the second input of the phase detector, the output of which is connected to the input of the first crystal oscillator, the output of the first comparison unit through the second presetting unit 20 is connected to the third inputs of the reference unit and the fourth frequency divider, the output of which through the first controllable delay unit is connected to the second input of the second switch and the first input of the second 25 beat signal detector, the second input of which is connected to the output of the first frequency divider and the input of the first trigger pulse generator, and the output through the second trigger pulse generator - with the second output bus of the meter; the additional outputs of the first amplitude meter are connected to the first input of the third comparison unit, the second input of which is connected to the first output of the first and first inputs of the fourth switch, the third input of the third unit of comparison is connected to the fourth output

control unit, the first input of the fourth comparison unit and the second input of the fourth switch, the third input of which is connected to the second output of the first switch and the second input of the fourth comparison unit, the output of which is connected to the first input of the OR element, the second and third inputs of which are connected respectively to the outputs of the third block comparison and trigger, the output of the OR element is connected to the third output bus of the meter, the additional outputs of the second meter of amplitudes are connected to the third input of the fourth block compared to However, the first output of the nth switch is connected to the second input of the second frequency divider, the output of which is connected to the first input of the second controllable delay unit, the second input of which is connected to the second output of the nth switch, and the output is connected to the third input of the second switch; the third inputs of the third switch, the second inputs of the two amplitude meters and the input of the fifth switch are connected to the fourth output of the control unit, the input of which is connected to the output of the second comparator unit, the output four The commutator is connected to the fourth output bus of the meter. Sources of information taken into account during the examination 1. USSR author's certificate No. 464823, cl. Q01R 13/20, 1973. 2. USSR author's certificate No. 699439, cl. G04.F 10 / O4, 1976.

Claims (1)

Claim A stroboscopic time interval meter containing two quartz oscillators, the output of the first of which is connected to the first input of the beat signal detector and the input of the delay unit, the output of the second quartz generator is connected to the second input of the beat signal detector, two mixers, the first inputs of which are connected to the corresponding input busbars of the meter and the second - to the output of the driver of the strobe pulses, the outputs of the first and second mixers through the first and second, respectively, amplifiers are connected to the inputs of the first switch RA, the first output of which is connected to the first inputs of the first amplitude meter and the first comparison unit, the second output of the first switch is connected to the first inputs of the second amplitude meter and the second comparison unit, the outputs of the first and second amplitude meters are connected to the second inputs of the first and second comparison blocks, the outputs of which are connected to the inputs of the trigger, the output of which is connected to the first input of the reference unit, the second input of which is connected to the first output of the control unit, the second output of which is connected chen to first vhod5 ^{g of} the second switch, the output of which is connected to the input of the gating pulse, and the generator start pulse, the output of which is connected to the first output line, characterized in that, to improve the accuracy, speed n measurement reliability, four frequency divider introduced therein , two blocks of controlled delay, two blocks of pre-installation, three switches, a standby multivibrator, phase detector, elements AND and OR, two comparison blocks, a detector of beat signals and a pulse shaper ska, and the output of the second quartz oscillator is connected to the first inputs of the first, second and third frequency dividers, the output of the first quartz oscillator is connected to the first inputs of the third switch and the first block | pre-installation, the first output of which is connected to the second input of the third switch, the output of which is connected to the first input of the fourth frequency divider, the second input of which is connected to the second input of the first frequency divider 5 and the output of the first preset unit, the second input of which is connected is connected to the third output of the control unit, and the third is connected to the output of the first beat signal detector, the first inputs of the 10 phase detector and the And element, the second input of which is connected to the output of the standby multivibrator, and the output to the second input of the third frequency divider, the output of which is connected with the input of the waiting 15th multivibrator and the second input of the phase detector, the output of which is connected to the input of the first crystal oscillator, the output of the first comparison unit through the second preset unit 20 is connected to the third inputs of the unit counting and the fourth frequency divider, the output of which through the first block of controlled delay is connected to the second input of the second switch and the first input of the second 25 beat signal detector, the second input of which is connected to the output of the first frequency divider and the input of the first trigger pulse generator, and the output through the second pulse shaper start za- _W d - a second output line meter, additional outputs of the first amplitude meter connected to the first input tretego.bloka comparison, a second input coupled to by the first output of the first and first input of the fourth switch, the third input of the third comparison unit is connected to the fourth output of the control unit, the first input of the fourth comparison unit and the second input of the fourth switch, the third input of which is connected to the second output of the first switch and the second input of the fourth comparison unit, the output of which is connected to the first input of the OR element, the second and third inputs of which are connected respectively to the outputs of the third comparison unit and trigger, the output of the OR element is connected to the third the output bus of the meter, the additional outputs of the second amplitude meter are connected to the third input of the fourth comparison unit, the first output of the fifth switch is connected to the second input of the second frequency divider, the output of which is connected to the first input of the second controlled delay unit, the second input of which is connected to the second output of the fifth switch, and the output is with the third input of the second switch, the outputs of the delay block are connected to the third inputs of the third switch, the second inputs of two amplitude meters and the input of the fifth comm the tator are connected to the fourth output of the control unit, the input of which is connected to the output of the second comparison unit, the output of the fourth switch is connected to the fourth output bus of the meter.