SU1760467A1 - Device for checking current pulses of microwave instruments - Google Patents

Abstract

The invention relates to a pulse technique and can be used in radio devices for training and dynamic testing of microwave pulse devices. A device for monitoring current pulses of microwave devices contains a pulse modulator 1, a pulse voltage transformer 2, a current measuring transformer 3, a resistor 4, an oscilloscope memory 5, a microwave device 6, a peak detector 7, the first 8 and the second 9 logic elements And the first 10 and a second 11 RS-switches, a resistive voltage divider 12, consisting of resistors 13 and 14, a switch 15, a comparator 16. an adjustable reference voltage source 17, the first 18 and second 19 pulse counters. 1 il. cl

Description

The invention relates to a pulse technique and can be used in radio devices intended for training and dynamic testing of microwave pulse devices, as well as in information transmission systems.

Apparatus for measuring the amplitude of current pulses of microwave M-type devices using an oscillographic measurement method are known, and as a converter of the amplitude of a current pulse into an amplitude of a voltage pulse, a pulse current transformer 1. The main disadvantage of these devices is the inability to isolate and quantify such current pulses. whose amplitude exceeds a certain set value.

The closest in technical terms to the invention is a device for monitoring current pulses, containing a pulse modulator, to the first and second outputs of which a primary winding of a pulse voltage transformer is connected, the secondary winding of which is grounded at one end and the primary winding of the measuring current transformer and the microwave device, the secondary winding of the measuring current transformer, shunted by a resistor, is grounded at one end and the other end through a coaxial the first cable is connected to the input of the oscilloscope 2.

The disadvantages of the known device are the impossibility of reliable selection and counting of the current pulses of the microwave device, the amplitude of which exceeds

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an updated value, and in the absence of the possibility of memorizing the shape of current pulses through a microwave device distorted by arcing in it.

The purpose of the invention is to increase the depth of the control.

The goal is achieved by the fact that a device for monitoring current pulses of a microwave device containing a pulse modulator, to the first and second outputs of which is connected the primary winding of a pulse voltage transformer, the secondary winding of which is connected to the common busbar by one output and through the primary winding of the measuring current transformer is connected to the first output of the microwave device, the second output of which is connected to the common bus, the secondary winding of the measuring current transformer - a resistor and one output are connected to a common bus, and another output is connected to the input channel of the vertical deviation of the storage oscilloscope, the peak detector, the resistive voltage divider, the switch, the comparator and the first pulse counter, as well as the adjustable reference voltage source are inputted second pulse counter, the first and second RS-triggers, the first and second logic elements And, the input of the peak detector is connected to the input of the vertical deflection of the storage oscillator Ogra, the output of the adjustable voltage source is connected to the second input of the comparator, the output of which is connected to the input of the second pulse counter and the R input of the first RS gripper, the 5 input of which is connected to the S input of the second RS trigger and the first output of the storage oscilloscope, and the R-input of the second RS-flip-flop is connected to the overflow output of the second pulse counter, the direct output of the first RS-flip-flop is connected to the first input of the second AND gate, the second input of which is connected to the second output of the storage oscilloscope yhod- to the erase input of external storage oscilloscope, the third output pulse modulator connected to the first input of the first AND gate, a second input coupled to a direct output of the second RS-flip-flop, and an output - to an input of the synchronization storage oscilloscope.

The drawing shows a block diagram of the proposed device.

The device contains a pulse modulator 1, a pulse voltage transformer 2, a current measuring transformer 3, a resistor 4, an oscilloscope memory 5, a microwave device 6, a peak detector 7. the first 8 and second 9 logic elements I,

the first 10 and second 11 RS triggers, a resistor voltage divider 12 with resistors 13 and 14, a switch 15, a comparator 16, an adjustable reference voltage source 17, the first 18 and a second

0 19 pulse counters. The first and second outputs of the pulse modulator 1 are connected to the primary winding of the pulse transformer 2, the secondary winding of which is connected to the common terminal of the device 6 UHF sequentially through the primary winding of the measuring transformer 3 to the common busbar. Secondary measuring winding

0 of the transformer 3. Current is shunted by a resistor 4 and one output is connected to the common bus, and the other is connected to the input of the channel of the vertical deflection of the storage oscilloscope 5 and to the input of the peak

5 of the detector 7. The third output of the modulator 1 is connected to the first input of the first logic element AND 8, the second input of which is connected to the forward output of the second RS-trigger 11, and the output to the synchronization input of the storage oscilloscope 5. The external erase terminal of the last is connected to the output of the second logic element And 9, the first input of which is connected to the second output of the storage oscilloscope 5, and

5 second input - to the forward output of the first RS-flip-flop 10. The S-inputs of the first 10 and second 11 RS-flip-flops are combined and connected to the first output of the oscilloscope 5. Between the output of the peak detector 7 and the common bus, a resistive divider 12 consisting of from series-connected resistors 13 and 14, with the resistor 13 being the first output, which is the input of the divider, and the second output, which is the output of the splitter, connected to the inputs of the switch 15, the output of which is connected to the first input of the comparator 16, the second input of which is connected to the output regulate forward reference source 17 na0 direct voltage. The output of the comparator 16 is connected to the inputs of the first 18 and second 19 pulse counters and at the same time to the R input of the first RS flip-flop 10, and the R input of the second RS flip-flop 11 is connected to the output of the second pulse counter 19.

As a storage oscilloscope 5 can be used any storage oscilloscope with afterglow. At its entrance of the channel of vertical deviation, controlled pulses are applied.

To this, to the synchronization input - external leading clock pulses, to the external erase input - external pulses to erase the recording. The first output of the storage oscilloscope 5 generates signals that appear at the time of contact closure of the manual erase button of the recording of the oscilloscope 5, and the second output contains signals that appear at the time of the reverse sweep of the beam.

As the second pulse counter 19, a scaling device can be used with an adjustable recalculation factor, n, where n 1, 2, 3 ...

The device works as follows.

The pulse modulator 1 at its third output generates a sequence of short clock pulses arriving at the first input of logic element 8. At the secondary winding of the transformer 2 relative to the common bus, the voltage pulses with a certain delay relative to the clock pulses, whose shape is close to rectangular and their duration and the frequency of the pulsator is set by the mode of operation of the modulator 1. These pulses through the primary winding of the measuring transformer 3 enter the power supply circuit of the microwave device 6 to its first conclusion. The current pulses in the power supply circuit of the device b microwave are transformed by transformer 3 into voltage pulses emitted by resistor L, which are fed to the channel of vertical deviation of the storage oscilloscope 5 and simultaneously to the input of the peak detector 7..

Before operation, it is necessary to tune the device to the nominal amplitude level of the current pulses. To do this, switch 15 is set to the position at which the first input of the comparator 16 receives the full output signal of the peak detector 7. The latter is made in such a way that the charge time of its storage element is much smaller, and the discharge time is much longer than the duration of the monitored pulses, but many less than the period of their repetition, peak detector 7 operates in pulse expansion mode. In this case, the amplitude of the output pulses of the peak detector 7 is equal to the amplitude of the pulses at the output of the secondary winding of the transformer 3 with an accuracy due to the detection error.

Such a construction of the detector is necessary to eliminate the formation of false counting pulses, when the controlled pulse has a complex, highly rugged shape of the vertex.

The second input of the comparator 16 receives the voltage from the output of the adjustable 5 source 17 of the reference voltage. By smoothly adjusting the magnitude of this voltage, a position is reached at which the comparator 16 is on the threshold of response, which can be judged by the state of the indicators of the first counter of 18 pulses. In this position, the device is tuned to the nominal amplitude of the monitored current pulses.

After tuning, the switch 15 is moved to the working position, with which the first input of the comparator 16 is pulsed from the output of the resistive divider 12, whose amplitude is reduced by a value corresponding to the set selection level. Then, the device is reset, for which, by pressing the reset button, the contents of counters 18 and 19 are cleared, and by pressing the manual erasing button, the squeeze oscilloscope 5 clears the screen of the previously recorded information. When the manual erase button is pressed, the S-inputs of the RS-flip-flops 10 and 11 are energized, setting both triggers to state 1.

0 In this case, the second inputs of the logic elements And 8 and 9 receive signals that unlock the synchronization and external erase inputs of the storage oscilloscope 5, and the latter is set to

5 standby sweep mode.

In the following, the device operates as follows. At the nominal amplitude of the monitored current pulses at the output of the comparator 16, the pulses are absent, the counters 18 and 19 remain in the initial (zero) state, and the state of the RS-flip-flops does not change, therefore the memory oscilloscope 5 records and immediately counts each monitored pulse.

5If the amplitude of the monitored pulses exceeds the set value due to the trigger threshold of the comparator 16, the number of exceedances is recorded in the first counter 18 pulses, designed to count and indicate the total number of current pulses distorted by sparks for the entire observation cycle (this cycle can be equal to workout time or dynamic

5 tests of the microwave device). With the arrival of the first excess pulse, the first RS-trigger is set to the state O by its R-input and blocks the operation of the second logic element AND 9, thereby prohibiting the deletion of the record made on

storage oscilloscope screen 5. Erasing is prohibited until the counter of 19 pulses overflows. When the indicated counter overflows, a signal is generated at its output, under the influence of which the second RS-flip-flop 11 is set to state O via its R-input and blocks the operation of the first logic element And 8, thereby prohibiting a new entry. As a result, the state O is in its R-input and blocks the operation of the first logical element I 8, thereby prohibiting a new entry. As a result, n current pulses were recorded on the screen of the storage oscilloscope 5, the amplitude of which exceeded the set value. After analyzing the recorded information, the recording cycle can be resumed by pressing the manual erase recording button, as a result of which the RS-triggers 10 and 11 are set to state 1, unlocking the synchronization inputs and external erasing of the storage oscilloscope 5.

The main mode of operation of the pulse counter 19 is when, in which only the first pulse from the group of the following sparking pulses is recorded on the oscilloscope screen. Sometimes, with a high intensity of sparks, it is necessary to observe the first few pulses of sparks. In this case, the pulse counter 19 is set to the position when. In this case, if the number of sparks in the group turns out to be less than n, one or more normal current pulses will be recorded, but since their shape and amplitude are known in advance, they will not affect the results of the analysis of the recording. It is impractical to set the value of n 5, since it makes it difficult to analyze the results of the recording.

The proposed device allows separating the selection function, the counting function, and the display function of the visual information, which allows eliminating information redundancy at high information intensity. This is one of its main advantages over the prototype, which captures on the oscilloscope screen all impulses, both normal and distorted, which makes it difficult, and sometimes makes it almost impossible to analyze the shape and count the number of sparks at high intensity. The proposed device may apply

To control pulses not only for anodic, but also for other types of modulation of microwave devices.

Claims (1)

Claims An apparatus for monitoring current pulses of microwave devices containing a pulse modulator, to the first and second outputs of which is connected the primary winding of a pulse voltage transformer, the secondary winding of which is connected to the common busbar by a single terminal and the second terminal sequentially through the primary winding of a measuring current transformer is connected to the first output of the microwave device, the second output of which is connected to the common bus, the secondary winding of the measuring current transformer is bounded by a resistor One pin is connected to the common bus, and the second pin is connected to the input channel of the vertical deflection of the storage oscilloscope, characterized in that, in order to increase the depth of control, a peak detector, a resistive voltage divider, a switch, a comparator and the first are entered into it. pulse counter, as well as an adjustable voltage source, the second pulse counter, the first and second RS-flip-flops, the first and second logic elements And, the input of the peak detector is connected to the input vertical deviation of the storage oscilloscope, the output of the adjustable voltage source is connected to the second input of the comparator, the output of which is connected to the input of the second pulse counter and the R input of the first RS trigger, the S input of which is connected to the S input of the second RS trigger and the first output of the storage oscilloscope, and the R-input of the second RS-flip-flop is connected to the overflow output of the second pulse counter, the direct output of the first RS-flip-flop is connected to the first input of the second logic element And, the second input of which is connected It is connected to the second output of the storage oscilloscope, and the output to the external erase input of the storage oscilloscope; the third output of the pulse modulator is connected to the first input of the first logical element I, the second input of which is connected to the direct output of the second RS-. trigger. and output-with the synchronization input of the storage oscilloscope. T f