SU773514A1 - Apparatus for measuring radio-pulse frequency carrier - Google Patents

Description

The invention relates to measuring technique and can be used to measure the frequency of filling of radio pulses. j

A device is known for measuring the carrier frequency of pulsed signals, constructed according to the principle of statistical summation of the number of high-frequency oscillations of radio pulses on a given time interval [1}.

The disadvantage of this device is the low accuracy of determining the carrier frequency of the radio pulses.

The closest in technical. The essence of the present invention is a device containing a video indicator, a generator of a reference frequency .., counters., time selectors, a cycle adder, an indicator [2]. jq

The disadvantage of this device is the low accuracy of determining the carrier frequency of radio pulses.

The purpose of the invention is to improve the accuracy of measuring the carrier frequency of the radio-25 pulses.

This goal is achieved by the fact that in the device for measuring the carrier frequency of radio pulses containing a reference oscillator connected in series, a first time selector and a time shaper, a pulse shaper connected in series, a second time selector, a measured frequency counter and an indicator, a video detector input. which is connected to the input of the pulse shaper, a trigger whose input zero is combined with the blocking input of the pulse shaper and is connected to the output of the video detector, and the output of the trigger is connected to. the second control inputs of the temporary selectors, · an OR element is introduced, the first input is connected to the trigger output, the second input is combined with the recording input of the time interval shaper and connected to the output of the second time selector, the output of the OR element. connected to the installation input of the shaper time interval, and the installation input of the trigger unit is connected to the output of the pulse shaper.

In this case, the time interval shaper is made in the form of a reference pulse counter, a combinational adder and a memory element, the recording input of which is connected to the recording input of the time interval shaper, the counting input of the reference pulse counter is connected to the input of the time interval shaper, the installation input of which is connected to the installation input zero counter reference pulses, the inputs of which are connected to the first inputs of the Raman adder, the outputs of the Raman adder are connected to information inputs odes of the memory element, the outputs of which are connected to the second inputs of the Raman adder, and the output of the Raman adder is connected to the output of the shaper of the time interval.

The essence of the proposed invention is that the measurement time interval is composed of intervals whose duration is a multiple of the pulse repetition period of the measured frequency ^ For this, the beginning of each control video pulse, the duration of which is a random variable, is synchronized by the first RF pulse, and the end of the control video, pulse between the last RF pulse And the trailing edge of the video pulse in the formation of the time interval is not involved. The fractional part of the video pulse, which is a random · tea value, changes from O to Tr and is discarded. As a result, the time interval is formed from intervals that are multiples of the period of the pulses of the measured frequency T _o , and the error in the formation of the time interval does not accumulate, therefore, the measurement accuracy, despite the fact that the measurement interval is composite, is equal to the accuracy of the frequency meters with continuous counting over the selected measurement interval.

In FIG. 1 shows a blueprint of the proposed device; in FIG. 2 are diagrams illustrating the operation of the device.

A device for measuring the carrier frequency of radio pulses contains a reference generator 1, a first time selector 2, a shaper 3 time interval., A shaper 4 pulses, a second time selector 5, a counter b of the measured frequency, indicator 7, video detector 8, trigger 9, element. OR 10.

The shaper of the time interval 3 includes a reference pulse counter 11, a combinational adder 12, a memory element 13.

In FIG. 2 shows the following diagrams: input signal 14, pulses 15 at the output of video detector 8, pulses 16 at the output of the driver * 4, signal 17 at the output of trigger 9, pulses 18 at the output of temporary selector 2, pulses 19 at the input of counter 6, signal 20 at shaper output 3.

A device for measuring the carrier frequency operates as follows.

At the initial moment, the device is set to zero (the installation circuits are not shown in the diagram). Then, the input signal 14 is supplied to the video detector 8, which selects the envelope of the radio pulse (plot 15, dashed line) and generates control video pulses 15 (solid line) when the envelope exceeds a predetermined threshold level V _o . The pulse shaper 4 at the time of the action of the control pulses 15 generates short positive pulses 16 from the sinusoidal signal 14, and the intervals between the leading edge of pulse 15 and the first high-frequency pulse 16 and between the last high-frequency pulse 16 and the trailing edge of pulse 15 are random values of r can vary from 0 up to T _s The control pulses 15 have a random duration. Improving the accuracy of frequency measurement is achieved by the formation of control pulses (plot 20, shaded), the duration of which is a multiple of the repetition period of the input pulses 16. For this, the initial (between the leading edge of the signal 15 and the first pulse, plot 16) and final (between the last pulse 16 and the trailing edge of the pulse 15) sections of the pulse 15 from the output of the video detector 8.

To exclude the initial portion of pulse 15, trigger 9 is set to a single state by each first high-frequency pulse 16. The trigger 9 is reset by the trailing edge of pulse 15. Thus, control pulses 17 are generated, the leading edge of which is synchronized by the first measuring RF pulse 16.

During the action of the pulse 17 to the input of the counter 6 receives the measuring pulses 19, which differ from the pulses 16 in that. due to the inertia of trigger 9, the first pulse does not pass to the output of the selector

5. At the same time, the input of the counter 11 of the reference pulses, which is part of the shaper of the time interval 3, through the time selector 2 receives pulses 18 from the output of the reference generator 1. The operation of the temporary selectors 2 and 5 is blocked simultaneously.

A feature of the proposed device is the formation of a measurement time interval by summing codes of the number of reference pulses. For convenience of indication, the formation of the time interval is performed by a multiple integer digit of a decimal number, therefore counter 11 is made in the form of a decade counter5 counter, and the combination adder 12 is selected as decimal. In the interval between the leading edge of the pulse 17 and the first pulse 19 at the input of the counter 11 receives a number of reference pulses 18.

The binary-decimal code of the counted reference pulses is supplied continuously from the counter 11 to the first inputs of the combinational adder 12, however, it is written to the memory element 13 and, therefore, to the second inputs of the combinational adder 12 when the measured pulse 19 arrives. After this. '' pulse 19, delayed by the element OR 10 due to inertia, the reference pulse counter 11 is set to zero.

In the second and subsequent intervals between pulses 19, a similar calculation of the number of reference pulses is carried out and the code of this number is summed with the code of the number recorded on the second inputs of the combinational adder 12 in previous intervals. The exception of the final portion of the pulses 15 is as follows.

In the interval between the last pulse 19 and the trailing edge of the control pulse 17, the counter 11 calculates a certain number of reference pulses 18, however, the sum of this number with the number recorded on the second inputs of the adder 12 is not recorded in the memory element 13, since the counter has a trailing edge 17 11 reference pulses sets! Various purposes in the receiving-analyzing equipment.

Thus, the introduction into the device for measuring the carrier frequency of the radio pulses of the element OR and complete. The formation of a time interval shaper in the form of a reference pulse counter, a combinational adder, and a memory element * made it possible to form a time interval from control pulses, the duration of which is a multiple of the measured repetition period, and thereby increase the measurement accuracy due to the stable distance between the measured pulses at the initial and final moments of the video pulse .

The measurement error of the carrier frequency of the radio pulses in the proposed device does not exceed the measurement error of the frequency of continuous pulse sequences with a conventional 20 frequency meter at the same time intervals.

Claims (2)

1. Author's certificate of the USSR 468848, cl. G 01 R 23/10, 2. USSR author's certificate  432409, cl. G 01 R 23/10, 07.02,72. fH ABOUT Phi-g. / fsi 7f