RU1775673C - Method of generating sweep voltage for time-scale converter - Google Patents

Abstract

Usage: the invention relates to electrical engineering and can be used in time-scale converters with automatic selection of sweep speed. The invention makes it possible to automatically set the recording scan speed when registering single, rarely repeating and periodic test signals with previously unknown durations. The inventive device comprises an autostart unit 2, a current generator 3, a unit 4 timing capacitors, an output unit 5, a control unit 6, a random access memory: device 7, a matrix of currents 8, a matrix of ranges 9, a master oscillator 10, a counter 17 Code switch 12, digital-to-analog converter 13. Band switch 14, block 15 level comparators, block 16 calibration comparators, mode switch 17, circuit I 18, address counter 19. OR circuit, scale generator, comparison unit, analog-to-digital converter atel, microcomputer and display unit. 1 s.p. f-ly, 2 ill. & Yo

Description

The invention relates to electrical engineering and can be used in time-scale converters with automatic sweep speed selection.

A known recording sweep generator is used in the special time-domain oscilloscope converter C9-6. However, in this recording sweep generator, the sweep speed is switched using a mechanical biscuit switch, which excludes the possibility of programmatically switching the sweep speed and, thus, automating the process of setting the sweep speed when recording the signals under study.

The closest technical solution is the oscilloscope sweep voltage generating device, which can be used as a recording sweep in time-scale converters, which contains a synchronization block, the input of which is connected to the bus of the signal under investigation, and the output - with the first input of the frequency divider and the first input electronic switch, the second input of which is connected to the output of the frequency divider, the third input to the second input of the frequency divider, the second output of the automatic control unit, the second sweep speed display unit and switcher speed multiplier switch input VI VJ

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current, and the output - to the first input of the automatic control unit and the first input of the scan voltage generator, the second input of which is connected to the first output of the automatic control unit, and the output to the second input of the automatic control unit and the first input of the horizontal deviation amplifier, the second input which is connected to the output of the switcher speed multiplier switch, wherein the first input of the sweep speed indication unit is connected to the third output of the automatic control unit. This device allows the oscilloscope to automatically determine the sweep speed when examining periodic signals. However, this device does not allow the study of single and repeating signals, as well as signals that are generated with a certain frequency, but with different durations.

It is an object of the invention to provide time-scale converters for automatically setting the recording scan speed when registering single, rare repeating and periodic test signals with previously unknown durations.

The object is achieved in that the scanning voltage generating device for a time-scale converter, comprising a synchronization unit, a comparison unit and a scale generator, is provided with an autostart unit, a sweep generator, a mode control unit, random access memory, a master oscillator, a tuning counter, a code switch, level comparator unit, calibration comparator unit, mode switch, AND circuit, address counter, OR circuit, analog-to-digital converter, linear a generator and a display unit, wherein the input of the synchronization unit is the input of the scan voltage generating device for the time-scale converter, the first output of the synchronization unit is connected to the first input of the autostart unit, the second output is connected by two-way communication with the first input of the mode control unit, the second input of which connected to the output of the address counter, with the first input of the sweep generator, with the first input of the scale generator and through random access memory with the first input of the switch a torus of codes, the third input of the mode control unit is connected to the first output of the AND circuit, through the comparison unit

the output of the scale generator, with the first input of the tuning counter, with the second input of the code switch and with the first input of random access memory,

the fourth input of the mode control unit is connected to the output of the calibration comparator unit, through the AND circuit with the first input of the mode switch unit, with the first input of the comparison unit, with the second input of the scale generator and with the second input of the master oscillator, the output of which is via the adjustment counter and switch codes connected to the second input of random access memory and the second input

5 of the sweep generator, the third input of which is connected to the second output of the autostart unit, and the fourth input of the sweep generator is connected to the first output of the mode control unit, the second output of which is connected to the first input of the address counter, the third output is connected to the first input of the OR circuit, the fourth output through the mode switch and the OR circuit are connected to the second input of the address counter, the fifth output of the mode control unit is connected to the second input of the autostart unit, the sixth output of the mode control unit is connected to the fifth input of scan generator, seventh output of the mode control unit

0 connected by a two-way communication line | with the first input of the linear converter and the second input of the comparison unit, and the eighth output of the control unit is connected to the first input of the level comparator unit, the output of which is connected to the third input of the mode switch, and the second input is connected to the input of the calibration comparator unit and the first output of the sweep generator, the second output whom

0 is connected via an analog-to-digital converter, a line converter to the input of the display unit, which is the output of the scan voltage generator for the time-scale converter.

A sweep generator comprising a current generator, a capacitor unit and an output unit is provided with a matrix to achieve the above circuit

0 currents, a range matrix, a digital-to-analog converter and a range switch, the input of the range matrix connected to the input of the current matrix being the first input of the scan generator, the input of the digital-to-analog converter is the second input of the scan generator, the first input of the current generator is the third input of the sweep generator, the input of the range switcher is the fourth input of the sweep generator, the second input of the current generator is the fifth input of the sweep generator, the first output is the output of the first block is the first output of the sweep generator, the second output of the output block is the second output of the sweep generator, and the input of the output block is connected to the output of the capacitor block, the input of which is connected to the output of the band switch, the input of which is connected to the output of the range matrix and the input of the current generator Connected to the output of the digital-to-analog converter, the input of which is connected to the output of the current matrix.

In FIG. 1 shows a block diagram of a scan voltage generating apparatus for a time-scale converter: FIG. 2 shows a block diagram of a scan generator.

The scan voltage generating device for the time-scale converter consists of a synchronization unit 1, a scale generator comparison unit 3, an autostart unit 4, a scan generator 5, a mode b control unit, random access memory 7, a generator 8, a tuning counter 9, a code switch 10, a block of level 11 comparators, a block of calibration comparators 12, a mode switch block 13, an AND element 14, an ardes counter 15, an OR element 16, an analog of a digital converter 17, a linear converter Atelier 18, display unit 19.

The sweep generator consists of a current generator 20, a block of capacitors 21, an output block 22, an array of currents 23, an array of ranges 24, a digital-to-analog converter 25, and a range switch 26.

A voltage forming device for a time-scale converter operates as follows. The control unit 6, after applying the supply voltage generates an installation pulse, which sets the address counter 15 to its initial state (the start address code is set at the output of the address counter 15), blocks the writing of the address code to the linear converter 18 and sets the mode switch 13 to at which the channel is open for connecting the output of the AND element 14 to the input of the OR element 16. The start address code from the output of the address counter 15 is sent to the sweep generator 5. Autostart unit 4, in the absence of triggering pulses at its input,

works in self-oscillating mode. The pulse from the output of the startup block 4 with the enable signal coming from the control unit 6, is fed to the input of the generator

5 sweep 5. The formation of a linearly increasing voltage begins, the slew rate of which corresponds to the code of the starting address, which is fed to the input of the analog-to-digital converter and

0 inputs of the block of level 11 comparators and the block of calibration comparators 12. The block of calibration comparators 12 contains two comparators and a trigger. The reference voltages of the calibration comparators are selected

5 in such a way that the first comparator operates at the upper sawtooth voltage level, and the second comparator at the lower (zero) sawtooth voltage level. Comparation pulses from the outputs of the comparators are fed to the R and S inputs of the trigger, respectively. The trigger output is the output of the calibration comparator unit. When the sawtooth voltage of the sweep generator 5 reaches the top 5 level of comparation, the upper level comparator is activated and the voltage level from the output of the unit of calibration comparators 12 goes to the control unit 6. where a blocking pulse is generated

0 of the autostart block 4 and the sweep generator 5, in which the master capacitor stops and starts to discharge. At the end of the digit, the time of the master capacitor is when

5, the zero level is set at the input of the calibration comparator block, the lower level comparator is triggered, and the output of the comparator block 12 enters the control device 6, the level 0 is the same, under the influence of which the control device 6 unlocks the autostart device 4 and the sweep generator 5. The formation starts again sawtooth voltage. Sweep Generator 5

5 operates in self-oscillating mode. From the output of the unit of calibration comparators 12, the pulses are fed to the first input of the comparison unit 2 and to the triggering input of the scale generator 3. Scale generator 3 in

0, in accordance with the code received at the control input, from the address counter 15 generates pulses of standard duration, the duration of which is equal to the duration of the sawtooth voltage specified in

5 code received at the control input. From the output of the scale generator 3, pulses of a standard duration synchronous with the triggering pulses are fed to the second input of the comparator 2, in which they are compared in duration with the pulses arriving at the first input of the comparator 3 from the unit of calibration comparators 12. If the pulses do not coincide block 3 generates an error signal. This is a pulse of constant amplitude, the duration of which is equal to the time t of adjusting the duration of the sawtooth voltage until the error with a small addition of AT is eliminated, which is then compensated. This is achieved in that the pulses generated by comparing pulses of a standard duration with a sawtooth voltage by subtraction, having a repetition period T, are fed to a single-shot, which generates pulses of duration t + A T. As a result, an error signal is generated at the output of the single-shot, duration which is equal to the tuning duration plus A T.

The error pulse prohibits the passage of pulses through the element And 14 from the block of the calibration comparators 12, unlocks the input of the master oscillator 8, unlocks the tuning counter 19 and the code switch 10 and sets the random access memory 7 in recording mode.

The pulse from the output of the unit of the comparator calibration 12 is fed to the input of the master oscillator 8 and the recession starts a single-vibrator, which generates a pulse of duration g DT. This pulse is triggered by its decline in the second one-shot in the generator 8 in the presence of an error pulse at the control input of the driver 8. The use of two one-shots in the driver 8 allows you to compensate for the increase in the duration of the error signal by A T during its formation.

A single pulse from the output of the master oscillator 8 is fed to the input of the tuning counter 9 and changes the code of the tuning counter 9 at its output. The code from the output of the tuning counter 9 through the code switch 10 is supplied to the control input of the scan generator 5 and is written into the random access memory 7 in the cell with the address matching the sawtooth voltage code coming from the address counter 15.

As a result of the code received in the sweep generator, the duration of the sawtooth voltage changes from the output of the trim counter. Block adjustment comparators 12 generates at its output a pulse equal in duration to the changed duration of the sawtooth voltage, which is fed to the first input

comparator 2, where it is compared with the reference duration of the pulse supplied to the second input of comparator 2. In case of unequal duration of the compared pulses, comparator 2 continues to generate an error pulse, which unlocks the input of the master oscillator 8. A single pulse from the output of the master oscillator 8 goes to

0, the input of the trim counter 9 and changes the code at the output of the trim counter 9, and thus the ramp duration changes. This process continues until the duration of the sawtooth voltage is equal to the duration of the reference pulse duration generated by the scale generator 3. With this equality, the error pulse at the output of the comparator 2

0 is absent, as a result, the input of the master oscillator 8 is blocked, the code switch 10 is blocked, the adjustment counter 9 is set to the initial state, and the input of the element 14 is unlocked. The next 5 comparation pulse from the output of the calibration comparators 12 is received through the element 14, the mode switch 13, the OR element 16 to the input of the address counter 15, which sets the code on its output

0 next address. At the output of the sawtooth generator, the duration of the sawtooth voltage is set in accordance with this code. The duration of the pi5 low-voltage voltage is adjusted. If the sawtooth voltage durations and the reference pulse are equal, the address counter 15 sets the following address at its output. In this way, the entire ramp duration of the sweep generator is checked and adjusted. After that, with the arrival of the output of the address counter 15 to the control unit 6, the code of the last address and signal

5 errors from the output of the comparison unit 2, the control unit 6 unlocks the synchronization unit 1 at the input, puts the autostart unit 4 into standby mode, unlocks the channel 13 for the mode switch

0 the passage of signals from the block of level 11 comparators to the input of the OR element 16, while blocking the channel for passing pulses from the And 14 element to the input of the OR element 16, sets the address counter 15 to its initial state, at which the initial counter output 15 is set the address corresponding to the shortest duration of the sawtooth voltage blocks the comparison device 2, the output of which sets a signal; the absence of an error is transferred to the read mode random access memory 7 linearly th converter and unlocks the input,

The trigger pulse received at the input of the synchronization unit 1 is amplified to the necessary limits and, through the autostart unit 4, starts the sweep generator. The formation of a sawtooth voltage of minimum duration begins, which is fed to the input of the analog-to-digital converter 17 and to the input of the level comparator block 11. The level comparator block contains a set of comparators with different operating levels (different reference voltages are applied to the second inputs of the comparators) and the element OR. combining the outputs of these comparators. The number of comparators in the block of level 11 comparators is equal to the number of sweep ranges generated by the sweep generator. The magnitude (step) of the response levels of the comparators is selected taking into account the provision of a given accuracy when measuring the time intervals of the studied signals.

When the sawtooth voltage reaches the voltage of the first reference level of the block of level comparators 11, the corresponding comparator of the block of level comparators 11 is activated, the comparation pulse of which is supplied through the mode switch 13 and the OR element 16 to the input of the address counter 15. A code of the next duration is set at the output of the counter sweep, which is fed to the input of sweep generator 5 and random access memory 7. The ramp speed at the output of the generator changes (decreases) ra sweep. When the sawtooth voltage reaches the voltage of the second reference level of the block of level 11 comparators, the corresponding comparator is activated, the comparation pulse of which sets the next ramp up speed in turn. This process of forming a sweep with a change in the steps of the slew rate continues until all the comparators of the level 11 comparator block operate and, when the sawtooth voltage reaches the voltage of the upper reference level of the comparator, the calibration comparator block 12 triggers the upper level comparator, the pulse from which goes to control unit 6. The control unit 6 blocks, for the duration of the discharge, the time of the driving capacitor of the sweep generator 5, the synchronization unit 1 and the sweep generator 5. Pr The charge time of the drive capacitor is shortened and its discharge begins. After the end of the discharge, the time of the drive capacitor, when the voltage level at the output of the sweep generator 5 is set to zero, the lower level comparator of the calibration comparator unit 12 is triggered, the pulse from the output of which goes to the control unit 6, which unlocks the sweep generator 5. The sweep generator 5 is ready for the next start.

5 The sweep voltage formed in the sweep generator 5 with a stepwise decrease in the slew rate increases to the horizontal input of the broadband ADC based on a high-frequency CRT with electric readout as a sweep of the recording, to the vertical input of which the signal under investigation arrives. The signal under test in the ADC is recorded and converted into a digital code. Or5 The coordinates of the signal under investigation in digital code are sent to a linear converter. In the linear Converter through the control unit 6 also receives the scan code records from the counter scan 15,

0 with the help of which it was recorded in the ADC, the investigated and the signal. As a linear converter can be used microcomputers. In this case, the microcomputer using a simple program recorded

5 to the ROM, the microcomputer converts the signal under study, recorded in the non-linear non-linear time memory of the microcomputer, and transmits it in such an ideally to the display unit 19, where it is displayed on the screen.

0 Then the microcomputer after transmitting information about the signal under investigation to the display device, in accordance with the control program laid down in it, generates a reset signal, which, through

5, the control unit resets the inventive device. The device is ready for the next launch. Since the trigger pulse passes the synchronization block and the e-trigger block in 50-80 nsec in the sweep generators, it is possible to estimate the duration of the signal under study by control unit 6. If, for example, the duration of the signal under study is more than 50 nsec, then there is no need to set the initial scan duration of 5 nsec, but you can immediately set 50 nsec. Therefore, depending on the duration of the signal under study, the control unit 6 sets the pulses that arrive through the And 14 element to the input of the address counter 15, the initial (initial) scan duration. If the signal under investigation is short in duration, then there is no need to include all the scan durations included in the inventive device in series. After the end of the test signal, the control unit 6 blocks the block of level 11 comparators and, thus, stops further switching of the sweep speeds.

The scan generator operates as follows. The sweep speed code is supplied to the address inputs of the programmed matrix of currents 23 and the programmed matrix of ranges 24, the outputs of which, as a result of this, come from the corresponding cell matrices, the code for setting the charge current, the time of the driving capacitor and the time code of the driving capacitor, which are previously recorded in cells of the corresponding matrices. The code for setting the charge current, the time of the drive capacitor is supplied to the inputs of the high bits of the DAC 25, which is converted to the voltage that is supplied to the input of the current generator 20. The generator 20 generates a constant charge current of the time of the drive capacitors, the value of which is proportional to voltage at its entrance. The code of the time of the master capacitor is supplied to the range switch 26, which connects the corresponding time of the master capacitor of the capacitor block 21 to the current generator 20. As a result, the time of the master capacitor connected to the output of the current generator 20 by the constant current of the current generator 20 is temporarily a linearly increasing sweep voltage is generated by the driving capacitor, which is fed through the output unit 22 to the output of the sweep generator. Typically, in sweep generators, a timing capacitor provides three to five sweep ranges at one time (charge currents switch each time sweep speed is switched). Therefore, the number of capacitors is three to five times less than the sweep ranges. So that during the formation of a sawtooth voltage with different slew rates, there are no gaps at the transition points of the slew rate from one speed to the next, the time-setting capacitors in the initial state by the range switch 26 are connected to voltage sources of the same magnitude by the command of block 6 the voltage levels of the trip level comparators and, thus, the time of the drive capacitors are already pre-charged to the desired levels. In addition, when connecting the next time of the master capacitor to the current generator 20

the previous capacitor is not disconnected. In the time calibration mode, the driving capacitors in the initial position are connected by the range switch 26 to the zero bus (case).

The sweep generator 5 is locked at the discharge time of the driving capacitor in the current generator 20. by stopping the supply of charge current to the driving capacitor. Into the cells

programmable matrix of currents 23 pre-recorded current codes for all ranges of durations of sawtooth voltage so that the low-order bits of the DAC 25, which

codes are supplied from random access memory 7 or from the code switch 10 of the inventive device according to paragraph 1, it was possible to compensate for the departure of the sawtooth voltage by

the nominal times of the driver circuit of the sawtooth voltage.

Formation of an inventive recording scan voltage device for an analog-to-digital converter with

stepwise change in slew rate with subsequent restoration of the linearity of the time axis of the analog-to-digital converter allows you to produce an analog-to-digital converter

registration of single, rarely repeated signals of a previously unknown duration, as well as periodic signals with a constant and variable duration. The claimed device

can also be used as a generator to generate pulses of complex shape in accordance with a predetermined law of change in its shape.

Compared to the prototype, which

it is impossible to use in time-scale converters for the study of single and rare repeating signals, the proposed device provides registration by scale-time converters of single and rare repeating signals of unknown duration and periodic signals.

Claims (2)

1. A device for generating a scan voltage for a time-scale converter, comprising a synchronization unit, a comparison unit, and a scale hemepair, characterized in that, in order to provide automatic setting of the recording scan speed when registering single, rare and periodic studied signals from previously unknown durations, it is equipped with an autostart unit, a sweep generator, a mode control unit, random access memory, a master oscillator, a counter under triples, a code switch, a block of level comparators, a block of calibration comparators, a mode switch, an AND element, an address counter, an OR element, an analog-to-digital converter, a linear converter and a display unit, the input of the synchronization block being the input of the device, the first output of the synchronizing block is connected with the first input of the autostart unit, the second output is connected by two-way communication with the first input of the mode control unit, the second input of which is connected to the output of the address counter, with the first input scan engine, with the first input of the scale generator and through random access memory - with the first input of the code switch, the third input of the mode control unit is connected to the first output of the And element, through the comparison unit - with the output of the scale generator, with the first input of the tuning counter, s the second input of the code switch and the first input of random access memory, the fourth input of the mode control unit is connected to the output of the calibration comparator unit, through the And element - with the first input of the mode switch unit, with the first input of the comparison unit, with the second input of the scale generator and with the second input of the master oscillator, the output of which is connected via the adjustment counter and code switch to the second input of the random access memory and the second input of the scan generator, the third input of which is connected to the second input of the autostart unit, and the fourth the input of the sweep generator is connected to the first output of the mode control unit, the second output of which is connected to the first input of the address counter, the third output is connected to the first input of the OR element, the fourth output through the switch modes and the element AND LI is connected to the second input of the address counter, the fifth the output of the mode control unit is connected to the second input of the autostart unit, the sixth output of the mode control unit is connected to the fifth input of the sweep generator, the seventh output of the control unit modes is connected by a two-way communication line with the first input of the converter and the second input of the comparison unit and the eighth output of the control unit is connected to the first input of the level comparator block, the output which is connected to the third input of the mode switch, and the second input is connected to the input of the calibration comparator unit and the first output of the scan generator, the second output of which is connected via an analog-to-digital converter to the input of the display unit, which is the output of the device. 2. The device pop. 1, characterized in that the scan generator comprising a current generator, a capacitor block and an output block is provided with a current matrix, a range matrix, a digital-to-analog converter and a range switch, wherein the input of the range matrix is connected to the input of the current matrix and is the first input of the scan generator , the input of the digital-to-analog converter is the second input of the sweep generator, the first input of the current generator is the third input of the sweep generator, the input of the range switcher is the fourth input of the sweep generator, the second input of the current generator is the fifth input of the sweep generator, the first output the output block is the first output of the sweep generator, the second output of the output block is the second output of the sweep generator, and the input of the output block is connected to the output of the capacitor block. the input of which is connected to the output of the range switch, the input of which is connected to the output of the range matrix, and the input of the current generator is connected to the output of the digital-analog converter, the input of which connected to the output of the current matrix. I I 10 faoj // 12 Figure 1