SU930146A1 - Device for digital measuring of pulse train frequency - Google Patents

Description

(S) DEVICE OF DIGITAL MEASUREMENT OF FREQUENCY OF FOLLOWING PULSES

I

This invention relates to radio measurements.

A device for digital pulse frequency measurement is known, comprising a converter, a quadrature oscillator, a master sampling signal generator, a discrete Fourier transform computing unit, a quad, an interpolator, a detection unit, a memory unit, a combination unit, an optimal resolution unit 1.

A disadvantage of this device is its complexity.

The closest in technical essence to the invention is a device containing a pulse shaper connected to the input bus, a time selector, the control input of which is connected to the shaper of the reference time interval, a counter with an indicator, the counter input connected to the time selector output -.

However, the known device does not have sufficient speed.

The purpose of the invention is to increase speed.

Claims (2)

The goal is achieved by the fact that the device containing the input pulse shaper, whose input is connected to the input bus and whose output is connected to the first input of the time selector, the second input of which is connected to the output of the time interval shaper, and a meter with an indicator, has a controlled frequency multiplier. , the period-code converter and the control signal shaper, the first input of which is connected to the output of the driver of output pulses, the second input is connected to the first input of the converter of the period code The output of the time selector and the information input of the controlled frequency multiplier, the output of which is connected to the input of the counter with the indicator, and the control input are connected to the first output of the control signal generator, the second output of which is connected to the second input of the period-code converter, the outputs of which are connected to the rest the inputs of the driver of the control signals, the inputs of the driver of the time intervals being connected to the other outputs of the driver of the control signals. The drawing shows a structural electrical circuit of the proposed device. The device contains a shaper 1 input pulses, a time selector 2, a controlled frequency multiplier, a counter 4 with an indicator, a period-code converter 5, a shaper of 6 time slots, a shaper of control signals 7 The measured signal is fed to the input bus 8. The shaper of 6 time slots consists from the trigger 9, the counter 10 and the element 11, and the driver 7 of the control signals comprises a generator 12 of the reference interval, a block 13 of the elements I, blocks 1 and 15 of the valves, a block 16 for setting the code, a parallel adder 17, and Tel 18, AND gates 19, 20, flip-flops 21 and 22, delay element 23 and an OR operation unit 2. enclose principle is as follows. In the initial state, the counter is zero, the selector 2 is closed, the converter 5 is ready for measuring the period code (duration). The measured signal is fed to the input of the imager from the output of which short pulses with a frequency F are sent to the selector 2 and the imaging unit 7. The imaging unit 7 begins the measurement process with a corresponding trigger signal, which can be generated either from the imaging unit 7 itself or from outside it. After the start signal arrives, the same pulse from the output of the formate 1 arrives at the shaper 7, the shaper 6 starts operation at the time of 0.1 Tj, tilting the selector 2. At the same time, a signal comes from the shaper 7 to the multiplier em multiplies the input pulses by 10. In addition, a generator of the reference period (for example, 1 μs) arrives at the period-code converter and it generates a period code for the interval between the first pulse arriving at its second input from the output Lecturer 2. The resulting code is immediately transmitted to shaper 7, where it is smartly 10 and the number of pulses N received at the input of diving 7 from the output of selector 2, the same number of N-, pulses from the output of selector 2, passed through multiplier 3, writes the number 10 to N into the counter. At the end of the first time interval, the imaging unit 7 generates the corresponding duration of the second time interval at its outputs, transmits this code to the imaging unit 6 time intervals, changes the multiplication factor from 10 to 1. After At that moment, the coming closest pulse from the output of imaging unit 1 is fed to the imaging unit of 6 time intervals, beginning the formation of the second time interval. Time. The selector 2 opens for the time of this secondary time interval and passes to its output and then through multiplier 3 to the counter input the number of pulses corresponding to the last significant digit of the frequency measurement result. To prepare the formers 6 and 7 to the initial position, there is a start signal, under the action of which the trigger 22 is set to the zero position at which there is no signal at its output, block 1A opens, resulting in block 16 through block 1 and block 13 to the setup inputs the TO counter enters the initial code, which provides in the counter 10 a conversion factor equal to the ratio N 1., where T is the period of the signals of the generator 12. In other words, the counter 10 under the influence of the signal is placed in such a position that after neither its counting input Ng pulses, the output of the counter turns on the signal. And, finally, the start signal zeroes the register (not shown) of the adder 17 and through element 2C enters the single input of the trigger 21 and converts it to the single state, opening element 19 The first we pulse from the driver 18 (corresponding to the end of the pulse of the driver 1) passes through element 19, first, it returns trigger 21 to the zero state, in which element 19 is closed, secondly, it enters the counting input of trigger 22, first his waters in a single state, open t element 20 itself and applying to the control input of the multiplier a signal for setting the multiplication factor equal to 10; thirdly, the signal from the output of element 19 enters the single input of the trigger 9, brings it to the unit state, opening the time selector for generator 1 pulses and an element 11 for the pulses of the generator 12. The counter 10 begins to fill, and from the output of the time selector pulses of the measured frequency begin to flow. By the time of arrival of the first pulse from the time selector to the code outputs of the converter 5, the period-code code will already be a code of the number TX, so this code will be summed up by each pulse from the time selector with its arrival in the adder. Naturally, after the arrival of the afterbirth. it from the counting pulses, the output of the time selector in the sum of the torus 17 will be recorded code of the code T on the number Ncvt pulses from the output of the time selector. Between the arrival at the output of the temporal pulse selector with the number the arrival at its input of the next pulse from the generator 1, the counter 10 overflows and at its output comes a signal arriving at the zero input of trigger 9, translating it into the zero state and the locking time selector and item 11. I In addition, the output is a count. Chica 10 passes through element 20 and after a delay in element 23 enters the control input of block 15 and the single trigger input 21. Block 15 opens and the code from adder 17 through elements 15 and 13 enters counter 10. If the result of the summation is written to the adder in the self-completing binary-decimal code, as a result of code rewriting in the counter 10, an additional code of the number equal to the difference between the code of the interval TC and the code of the interval 10-VNC4 appears, b6. those. the time interval shaper is ready to form at its output a pulse of duration Tf ,. The arrival of the signal at the single input of the trigger 21 leads to its transition to the single state, unlocking the element 19, passing the closest pulse from the driver 18, shifting the trigger 21, locking the element 19, bringing the trigger 22 to the zero state (which ensures the multiplier of the multiplier, equal to 1), flip trigger 9, single state, i.e. ensuring the formation of a temporary interT d. During this shaft interval, the number of units of the resulting measurement is counted. At the end of this interval at the output of the counter 10. A signal arrives at the zero input of the trigger 9 and at the input of the element 20. The trigger 9 goes to the zero state, locking the time selector and the element 1G. Element 20 is locked at the time of arrival of this pulse, so that the drivers 6 and 7 stop their operation at this point. DETAILED DESCRIPTION OF THE INVENTION A device for digital measurement of the pulse frequency, containing the input pulse puller, the input of which is connected to the input bus, and the output is connected to the first input of the time selector, the second input of which is connected to the output of the time generator, and the counter with the indicator and reading with. By the fact that in order to increase the speed of the control, a controllable frequency multiplier, a period-code converter and a control signal generator, the first input of which is connected to the output of the input pulse generator, are entered into it, the second input is connected to the first input of the period-code converter, the output of the time selector and the information input of a controlled frequency multiplier, the output of which is connected to the input of a meter with an indicator, and the control input is connected to the first output of the control signal generator, the second output of which is It is connected to the WTO input of the converter period1 code, the outputs of which are connected to the other inputs of the control signal generator, and 1 inputs of the time interval generator are connected to the other outputs of the control signal generator. 6 Sources of information taken into account in the examination 1. USSR author's certificate ff, cl. G 01 R 23/00, 28.11.77. 2. Mirsky. Electronic measurements. M., Energie, 1975, p. 200o