SU879479A2 - Two-channel stroboscopic oscilloscope - Google Patents

Description

(54) TWO-CHANNEL STROBOSCOPIC OSCILLOGRAPH

I

The invention relates to electrical measuring technique and can be used to continuously reproduce the shape of several wideband signals and determine their parameters.

According to the main auth. No. 817594 is known for a two-channel stroboscopic oscilloscope that contains a gating comparison block in each channel, the signal input of which is connected to the signal bus, the compensation input is connected to the output of the channel compensation unit, and the output is connected to the first output of the channel compensation unit and the information input of the channel shift register, the output of which is connected to the input of the channel decoder, the output connected to the first input of the channel trigger, the gates of the comparison units being connected to the first output of the automatic shift unit and the generator strobe pulses, and compensation inputs with the first and second signal inputs

Claims (1)

switch, the control input of which is connected to the first output of the control unit, and the output is connected to the vertical path input of the electron-beam indicator, the horizontal deflection path input of which is connected to the output of the sweep voltage shaping unit and the control input of the auto-shift unit and strobe pulse generation, and modulation input 10 with the output of the beam quenching unit, the start input of which is connected to the output of the element I, the input of the control unit and the reset inputs of the flip-flops, and the reset input to the reset input of the forc block voltage sweep and the fifth output of the control unit, the fourth output of which is connected to the control input of the voltage sweep voltage shaping unit, the third and second outputs - with the trigger setup input, the outputs of which are connected with the first and second inputs of the element I, the signal input connected to the second output of the auto shift unit and the generation of strobe pulses, clock inputs of the shift registers and the second inputs of the compensation blocks p. In order to expand the functional capabilities, a two-channel strobic oscilloscope containing, in each channel, a switchable block, whose signal input is connected to the bus, the signal of the compensation input is connected to the output of the channel compensation unit, and the output is to the first output of the compensation unit the channel and the information input of the channel shift register, and whose output is connected to the input of the channel decoder of the channel connected to the first input of the channel trigger, the gates of the comparison blocks being connected to the first output This unit includes the auto-shift and strobe generation, and the compensation inputs with the first and second signal inputs of the switch, the control input of which is connected to the first output of the control unit, and the output to the input of the vertical deflection path of the electron-beam indicator, whose input of the horizontal deflection path associated with the output of the voltage sweep voltage shaping unit and the control input of the auto-shift unit and the strobe pulse generation, and the modulation input with the output of the beam quencher unit, the start of which is connected to the output The input And, the input of the control unit, and the reset inputs of the triggers, and the reset input — with the reset input, the sweep voltage shaping unit and the fifth output of the control unit, the fourth output of which is connected to the control input of the sweep voltage shaping unit, the third and second outputs - to the installation inputs of the triggers, the outputs of which are connected to the first and second inputs of the control element I, the signal input connected to the second output of the auto shift and strobe pulses generation, clock inputs of the shift registers and the second inputs b compensation, equipped with two comparators, a multiplexer, two valves, an EXCLUSIVE OR element, a synchronization unit, a pulse frequency multiplier, a source of adjustable reference voltages, a reversible counter, a display unit, and a cumulative counter, the first inputs of the comparators are connected to the output of the shaping unit sweep, the second inputs to the outputs of the source of adjustable reference voltages, and the output to the first and second inputs of the EXCLUSIVE OR element, the output connected to the third beam quenching unit and the first input of the synchronization unit, the second input of which is connected to the fifth output of the control unit, the first output to the second inputs of the first and second valves, and the second output to the reset inputs of the reversible and storage counters, the outputs of which are connected to the first and second inputs the display unit, the third input associated with the third output of the automatic shift and strobe pulse generation unit and the first input of the frequency multiplier is sloler, pickup pulses, the second input of which is connected to the output of the first valve, and the output - with a counting input of a cumulative counter, the counting input of a reversible counter is connected to the output of the second valve, the first input of which is connected to the second output of the automatic shift and pulse generation unit, and the third input - to the multiplexer output, the first input of which is connected to the output of the gated comparison unit of the first the channel, the second input is with the output of the gated comparison unit of the second channel, and the control input is with the first output of the control unit, with the first input of the first valve connected to the output of element I. Structural - The electrical circuit of the device is shown in the drawing. The device consists of two identical measuring channels 1, 2, each of which includes a gated comparison unit 3, a compensation unit 4, a shift register 5, a decoder 6 and a trigger 7, a switch 8, an electron-beam indicator 9, an auto-shift unit 10 and generation the strobe pulses of the I1 voltage shaping unit, the beam quencher unit 12, the control unit 13 for the element 14, the first and second comparators 15, 16, the multiplexer 17, the first .- valve 18, the element EXCLUSIVE; CLI 19, synchronization unit 20, second valve 21 multiplier 22 pulse frequency, adjustable reference voltage source 23, reversible counter 2, display unit 25 and accumulative counter 26, the device operates as follows. The signals under study are fed to the signal inputs of gated blocks 3. Synchronizing signals in-phase with the signals under study are fed to the synchronization input of block 10 The phase shift of the pulses relative to the synchronization signals is determined by a slowly varying sweep voltage coming from the output of block 11 to the control input of block 10 and the input path of the horizontal deviation of the indicator 9. From the first output of the block 10, the pulses go to the inputs of the gating of blocks 3, which forms with the block 4 of the same channel feedback loop. From the second output of block 10 to the second input of each block 4, clock pulses are received, delayed relative to the station, by pulses by an amount determined by the delay introduced by block 3. These pulses change the voltage at the output of each block 4 by a predetermined value (adjustment dose) The sign of change corresponds to the direction of operation of block 3 at the time of arrival of the pulses, which is determined by the sign of the difference between the instantaneous value of the signal under study and the voltage at the output of block 4. After several pulses of block 10, the output voltage The unit 4 of each channel with an accuracy up to the dose of regulation becomes equal to the instantaneous value of the signal under study in the gating phase. Until compensation, unit 3 switches in one direction, alternating after switching directions. The compensation time in each channel is fixed by the decoder 6, at the output of which, when the switching of block 3 alternates, a signal appears that arrives at the first input of trigger 7. When the sum of the signals under investigation is displayed, both channels are set to the trigger inputs of block 13 the signal that permits the trigger to switch to one state according to the signal from the output of the decoder 6. After switching the triggers 7, the next pulse from the second output of block 10 passes through element 14 and to inputs 96 of block 13, block 12 and to the second triggers 7, moving them to the zero state of the pulse decay. At the output of block 12, a pulse appears that unlocks the tube of the indicator 9, to the input of the vertical deviation path of which comes from the output of switch 8 the sum of the output voltages of blocks 4 is the sum of the output voltages of the channels. The clock pulses passing through block 13 are applied to the control input of block 11, causing a change in its output voltage, which causes a further phase shift of the gating. The study cycle is repeated. Upon receipt of a predetermined number of clock pulses, block 13 de-energizes the reset pulses of blocks 11 and 12. When indicating the output voltage of one channel, trigger 7 of an unused channel from block 13, the unit is turned on and the switch 8 connects to the input the path of the vertical deviation of the indicator 9 output of the block 4 compensation channel involved. When indicating the output voltages of both channels, the switch 8 alternately connects the outputs of blocks 4 to the input of the vertical deviation path of the indicator 9. When the indication is displayed at a low sweep speed, the block 13 supplies the control input of the block 11 with clocks. The output signal of the block 11 is also fed to the comparators 15 and 16, which compare it with the reference voltages of the source 23, changing the latter, you can set the starting and ending point of the selected area on the signal image. At the output of the EXCLUSIVE OR 19 element, pulses are formed that correspond to the selected section, which highlight the image of the signal, arriving at the third input of block 12, Block 20, depending on the measurement period, selects some of the pulses, and also generates counter-setting signals on their front and counter 26 to its original state, after which they begin to calculate the pulses arriving at their inputs through open gates 21 and 18. Counter 24 counts the algebraic sum of the number of operations and 7 failures. of the displayed block 3 of the indicated channel, the output signal of which is fed to the valve 21 through the multiplexer 17. The measurement discreteness here is equal to the control dose given to the input, and the error is determined by the inequality of the control doses in block 4 (in particular, if block 4 is completed as series-connected reversing counter and digital-to-analogue converter (1CP); then the measurement error is minimal). At the end of each pulse of block 20, the counter 24 accumulates a number corresponding to the difference of the instantaneous values of the signal in the allotted area in units of dose control, which is indicated by block 25. By selecting the value of the dose given to the input equal to, for example, 1 mV, readout directly in millivolts. Counter 26 counts the number of strokes of shift of pulses over the sweep range, which corresponds to the duration of the selected area. To obtain a time reference in absolute units with the smallest possible discreteness, pulses at the input of counter 26 are received through multiplier 22, the multiplication factor of which, as well as the position of the decimal point in block 25, is determined by the sweep range set by the controller in block 10. Measurement error the time interval in this case is determined only by the nonlinearity of the shift of the pulses and does not depend on the speed and range of the sweep. The use in block 13 of the clock frequency divider and the second frequency divider connected to its output with a capacitance that determines the number of sweep points allows, along with slowing down the sweep speed, to provide a start-stop mode for unit II. The unit 13 also includes an operation mode switch, by means of which the division factor of the clock divider is set, a signal is triggered at the installation inputs of the second frequency divider and the corners of the trigger outputs of the control unit controlling the switch 8 are determined. The device allows to display only the most probable values of the studied signals, which reduces the noise level. The maximum scanning speed of the beam of the cathode ray tube of the indicator 9 is determined by the shape and level of the total noise of the signal under study and the comparator, as well as the phase dispersion of the pulses of the block 10, since increasing the noise level reduces the likelihood of register code 5 required for the decoder to get 6 and the subsequent submission to the element 14 of the next clock pulse. The device makes it possible to indicate the signals under study and measure the amplitude and temporal ratios that characterize them in remote areas, which is achieved with an accuracy practically determined by the signal's time scale conversion path. When the passband is at least 2 GHz and the urn mjTMOB, reduced to the input and not exceeding 80 µV, the indication of time intervals and amplitude ratios with a 1% resolution is provided. Claims of the invention Two-channel stroboscopic oscillograph according to the author. No. 817594, characterized in that, in order to expand the functionality, it is equipped with two comparators, a multiplexer, two valves, an EXCLUSIVE element OR a synchronization unit, a pulse frequency multiplier, a source of adjustable reference voltages, a reversible counter, an indication unit and a cumulative counter, the first inputs of the com.parators are connected to the output of the sweep voltage shaping unit, the second inputs to the outputs of the source of adjustable reference voltages, and the output to the first and second inputs EXCLUSIVE OR, the output connected to the third input of the beam-quenching unit and the first input of the synchronization unit, the second input of which is connected to the fifth output of the control unit, the first output to the second inputs of the first and BToporq valves, and the second output to the reset inputs of the reverse and cumulative counters, the outputs of which are connected to the first and second inputs of the display unit, the third input connected to the third output of the avSdvig unit and strobe pulse generation by the first input of the frequency multiplier pulses, the second input the output is connected to the output of the first inlet, and the output is connected to the counting input of the counting counter, the counting counter of the reversible counter is connected to the output of the second valve, the first one is connected to the second output of the auto-shift and strobe pulse generation, and the third input is connected to the output of the multiplexer, the first input of which 9 . ten . connected to the output of the strobe of the first channel comparing unit, the second input is connected to the output of the second channel gated comparison unit, and the control input is connected to the first output of the control unit, the first input of the first valve connected to the output of the element I. Information sources received into account in the examination of.,., -, USSR certificate rllln). 3/28 1979 (about