SU773513A1 - Radio-pulse fill frequency meter - Google Patents

Description

one

: The invention relates to a measuring technique and can be used in devices for measuring the filling frequency of pulse-modulated oscillations.

A device is known for measuring the frequency of filling of radio pulses l.

The disadvantages of this device are the considerable measurement error of the filling frequency, due to the lack of synchronization of the end of a single-shot pulse with the end of the measured frequency period and the setting of the single-vibrator pulse duration, based on the minimum possible duration of incoming radio pulses .

It is also known a device for measuring the frequency of filling of radio pulses, comprising a pulse shaper 20, a measured frequency counter, a descrambler, a strobe shaper, a pack counter, a reference frequency generator, a time selector, a reference frequency counter and an arithmetic numerator (processor) 2.

However, the device is characterized by a significant error in the frequency measurement, which is due to the formation of the measured-temporal

A terrains on the basis of a fixed number of periods programmed in the decoder, regardless of the change in the duration and frequency of filling the radio pulses and taking measurements at a non-optimal input frequency when the filling frequency changes (radio pulses ..

The aim of the invention is to improve the accuracy of the filling frequency measurement and expand the functionality of the meter, which is to provide a measurement of the filling frequency in any part of the radio pulse.

Claims (1)

The goal is achieved by the fact that in the present meter the filling of radio pulses contains 1 1st pulse shaper, decoder, strobe shaper, time selector, reference frequency generator, pack count, reference frequency counter and processor, the first output of the pulse shaper is connected to the first decryptor input, the first the output of which is connected to the first entrance of the gate driver, and the second output is connected to. the entrance to the gate driver, the output of which is connected to the first. the input of the temporary selector, the second; the input of the reference oscillator connected to the output, the third input of the time selector is connected to the output of the pack counter, the output of the time selector is connected to the input of the reference frequency counter, the output of which is connected to the first processor input, a mixer and synthesizer are entered, the input of which is connected to the first processor output, and the output is connected to the heterodyne input of the mixer, the output of which is connected to the input of the pulse former, the second output of which is connected to the input of the patch counter and to the second input of the processor, the third input to expensively connected to the third output of the decoder, and the second output of the processor is connected to the second input of the decoder. Fig, 1 shows a structural diagram of the meter; FIG. 2, voltage supports, Meter (FIG. 1). Contains mixer 1, synthesizer 2, impulse generator 3; decoder 4, shaper 5 builda, time selector b, rieHepaTop 7 reference frequency, counter 8 packs, counter 9, reference frequency, processor 10, Synthesizer 2 consists of a tunable one. LC-generator, counter, .. converter code to nf, varicap. With a wide range of overlapping frequencies in the synthesizer, a set of several tuners can be used. The decoder 4 consists of a measured frequency counter and two identical dividers with a variable division factor. The meter works as follows. Before starting the measurement, the codes from the first and second outputs of the processor 10 are set respectively the initial value of the frequency fnoAcr generated by synthesizer 2, starting from the prior frequency range, and the initial value of the number of periods of the measured frequency n in the decoder 4 by setting the necessary divider division factors, based on the minimum the possible duration and frequency of filling the radio pulses and the selected frequency of the stand. The radio pulse of the measured frequency is connected to the input of the mixer 1. At its output, the filling frequency is rad: p1 pulses will become equal to fj, p balds radio pulses, and (FIG.) Are fed to the pulse shaper 3, which are formed in such a way that bursts of pulses Uj (the period of the pulses following in the pack T), on the second run, the pulses and corresponding back fronts of the radio pulses (or delayed relative to them by any value of t, less than the time interval between the radio pulses), First pack of pulses Ed. by doing the input of the solders of the decoder 4, causes the appearance at the output of the pulse divider U corresponding to 1G (its first packet pulse, the output of the pulse divider and corresponding in time to the n-th pulse of the packet. The pulses Od and Uj arrive at the inputs of the gate generator 5, as a result what at its output is a pulse U with duration gr pr. This pulse controls the time selector 6 so that its output passes oscillations of the generator 7 Ug only during the time interval. The number of oscillations of the reference generator is recorded by the counter 9, e end of the first packet (t, e, after the end of the first from the beginning of the measurement of the radio pulse) from the second output of the pulse generator 3, the second input of the processor 10 receives a pulse U, allowing recording of information on the number of periods of filling the radio pulse from the decoder measured frequency counter 4, Thus, after the termination of the first radio pulse, after some brem determined by the value of t; from the second input of the pulse generator in the receiving register of processor 10, the code of the number of periods of filling of the input radio pulse U in the counter 9 of the reference frequency will be recorded, which characterizes the duration of the TSTR strobe signal, Upon receipt of the second, third and t, e, the radio pulse of the scheduling process repeats. To stop the oscillation of the oscillator from the generator, the pulses from the second driver of the pulse generator U are sent to the counter of 8 packs. At the moment of reversal from the counter output of 8 packs to the third input of the time selector, the inhibitory level not transmitting the signal of the reference generator to the counter 9 is received: The information accumulated in the counter 9 goes to the processor 10 to calculate the completion frequency f. The calculation is made according to the formula, p TTfT where K is the number of bursts of pulses; N is the total number of periods of the reference generator, measured by the counter 9 ;. tp is the period of the reference oscillator signal. Estimation of the pulse duration is produced according to the formula where r is the number of periods of the radio pulse filling (can be averaged-1 value) recorded in the processor 10 s of the decoder 4 after the end of the first pulse pulse The processor 10 determines the value of the frequency of the stand at which the absolute frequency measurement error filling is minimal or does not exceed the permissible value. The absolute measurement error of the frequency of filling is minimal when the value is determined by the formula r pr-src, where Dn is the number of periods of the frequency of filling of the radio pulse, without using. This is due to the instability of the duration of the radio pulses, the signal magnitude and noise at the input of the pulse generator, the dead zone of the pulse former, and the shape of the radio pulse envelope. In accordance with the obtained value of lp, control codes from the first output to the synthesizer 2 and from the second output to the dividers of the decoder 4 are generated and issued, under which the frequency of the synthesizer 2 becomes equal to the wholesale dividers of the decoder 4 impulses for their characteristics (only the number of periods equal to pn is excluded). Then, in accordance with the described operation principle of the meter, the frequency of the radio pulse is measured again o f x. The measurement result differs from the frequency of the input rp,. Signalsh on the known value of the frequency of the stand. Therefore, f f f POArt.opt. The invention of a pulse frequency meter containing a pulse shaper, a decoder, a strobe driver, a time selector, a reference frequency generator, a pack counter, a reference frequency counter and a processor, the first output of the pulse shaper is connected to the first input of the decoder, the first output of which is connected to the first input the gate driver, and the second output is connected to the second gate driver input, the output of which is connected, to the first input of the time selector, the second input of which is soy dinene with the output of the reference generator, the third input of the time selector is connected to the output of the pack counter, the output of the time selector is connected to the input of the reference frequency counter, the output of which is connected to the first processor input, which is characterized by the fact that, in order to improve the accuracy of measurement and functionality, , a mixer and a synthesizer are entered into it, the input of which is connected to the first output of the processor, and .. the output is connected to the heterodyne input of the mixer, the output of which is connected to the input of the pulse former, W swarm output of which is connected to the input packets and a second count input of the processor, a third input coupled to a third output of the decoder and a second output processor is connected to the second input of the decoder. Sources of information taken into account in the examination 1, USSR Copyright Certificate 468848, cl. G 01 R 2.3 / 10, 1972, .2, USSR Copyright Certificate 599228, cl. G 01 R 23/02, 1976, / V. eleven Uh vi etc 1 .j n I