SU1620953A1 - Device for measuring the ration of pulse repetition frequency - Google Patents

Abstract

The invention relates to a pulse technique and can be used to measure the frequency of following statistical sequences of pulses. The purpose of the invention is to improve the accuracy of measuring the ratio of the frequency of the pulse sequences. A device for measuring the frequency ratio of pulse sequences contains input buses 1-5, elements OR 8.9, code-controlled dividers U, 11 frequencies, switches 12.13 and trigger 14. A trigger 15 is entered into the device to achieve the set goal. 1 Il.

Description

The invention relates to a pulse technique and can be used to measure the repetition frequencies of statistical sequences of pulses.

The purpose of the invention is to improve the accuracy of measuring the ratio of the frequencies of pulse sequences.

The drawing shows a block diagram of a device for measuring the ratio of the frequencies of pulse sequences.

A device for measuring the ratio of the frequencies of pulse sequences contains input buses 1-5, the first and second reversible counters 6 and 7, the first and second OR elements 8 and 9, the first and second second code-controlled frequency dividers 10 and 11, the first and second switches 12 and 13, the first and second triggers 14 and 15, and the input bus 1 is connected to the counting input of the code-controlled frequency divider 10, the information input of which is connected to the output of the switch 12, the first and second information inputs of which are connected respectively to the input buses 3 and 4, input control switch 12 is connected to the output of the trigger 14, the input of which is connected to the output of the code-controlled frequency divider 10 and the subtracting input of the reverse counter 7, the direct transfer output of which is connected to the first input of the OR element 9 and the summing input of the reverse counter 6, the outputs of the direct and reverse transfer of which are connected respectively, with the first and second inputs of the OR element 8, the output of which is connected to the recording synchronization input of the reverse counter 6, the information input of which is connected to the information output m reverse counter 6, the subtracting input of which is connected to the reverse transfer output of the reverse counter 7 and the second input of the OR element 9, the output of which is connected to the recording synchronization input of the reverse counter 7, the information input of which is connected to the information output of the reverse counter 7, the summing input of which is connected to the output of the code-controlled frequency divider 11, the counting input of which is connected to the input bus 2, the information input of the code-controlled frequency divider 11 is connected to the output of the switch 13, the first the information input of which is connected to the input bus 5, the second information input of the switch 13 is connected to the information output of the reverse counter 6 and the output of the device, the input of the trigger 15 is connected to the output of the frequency divider 11, and the output of the trigger 15 is connected to the control input of the switch 13.

The device operates as follows.

The pulse train of the dividend with a frequency fi through the input bus 2 goes to the counting input of the code-controlled frequency divider 11, and the pulse train of the divider with a frequency of 1 g 10 passes through the input bus 1 to the counting input of the frequency divider 10. Codes of numbers A, B, and C are applied to input buses 3-5, respectively.

To the information inputs of frequency dividers 10 and 11 through switches 12 and 13, respectively, depending on the state of the triggers 14 and 15, which operate in the T-trigger mode, i.e. trigger with a counting input 20, the code of number A or the code of number B (to the information input of the frequency divider 10) and the code of number C or the code of number U, which is the output information of the device (to the information input of the frequency divider 11), are connected. As a result, at the output of the frequency divider 10, pulse sequences with a frequency of f2 / A or f2 / B are formed depending on the state of the trigger 14, and at the output of the frequency divider 11h30, sequences of pulses with a frequency of f 1 / C or fi / Y are formed depending on the state of the trigger 15. The indicated pulse sequences are fed to the subtracting and summing35 inputs of the reverse counter 7, and the pulse sequences with frequencies f2 / A and f2 / B are received to the subtracting input of the counter 7, and the next el40 NOSTA pulses with frequencies fi / C and fi / Y.

Pulse sequences with frequencies f2 / A and f2 / B control the state of trigger 14, and a sequence with frequencies fι / С and f 1 / Y controls trigger 15.

In the steady-state measurement mode, i.e., in the mode in which the average values of the frequencies fi and f2 remain unchanged, the number of pulses in the pulse sequence arriving at the summing input of counter 7 is equal to the number of pulses in the pulse sequence arriving at the subtracting input of counter 7 . one pulse to the subtracting input of the counter 7, 55 when the information input of the frequency divider 10, the code numbers A fed is fed through a time interval rA equal to ^{w =} Va · and one pulse to the subtracting input of the counter 7 when the information input Delhi ator 10 the frequency of the code fed in, passes through tv interval of time equal to (2)

Thus, two pulses for the time interval t ₂ equal to the subtracting input of the counter 7 are received

T2 = td + tv = f ₂ / A

One pulse to the summing input of counter 7, when a code of number C is supplied to the information input of the frequency divider 11, after a time interval tc equal to ^{Tc =} d7s', one pulse goes to the summing input of counter 7, when the code of number Y is applied to the information input of the frequency divider 11 comes through a period of time that equal to

Thus, two pulses for the time interval Tu equal to ^{= (6)} arrive at the summing input of the counter 7

Since the device operates in a steady-state measurement mode, the number of pulses in the pulse sequence arriving at the summing input of the counter 7 for a certain time interval is equal to the number of pulses in the pulse sequence arriving at the subtracting input of the counter 7 for the same time interval. But according to equations (3) and (6), two pulses arrive at the subtractive input of counter 7 in a time t ₂ , two pulses arrive at the summing input of the same counter 7 in a time Τι. Therefore, the equality

P = m ₂ (7) or according to (3) and (6)

A + B_C + Υ f2 fi ’from here

Y-b (A ₊ B) -C. (IN)

Thus, in the steady-state measurement mode, the code of the number Y associated with the frequencies H and f _{2 by} expression (8) is fixed at the output of the device.

With deterministic values of the frequencies fi and f _{2, the} state of the counter 7 changes only within one pulse. Fluctuations in the state of counter 7 within a single pulse is caused by the presence of a phase shift between the frequencies (f 1 / С + fi / Y) and (f ₂ / A + f ₂ / B). Usually, the capacity of the reverse 15 counters is set to at least ten pulses, which due to the design of integrated circuits manufactured by the industry. Therefore, fluctuations in the state of the counter 7 within a single pulse do not cause the appearance of signals at its outputs of forward and backward skew and the state of the first reversible counter 6 remains unchanged. The code of the number at the information output of the counter 6 remains unchanged. However, due to statistical fluctuations in the frequencies fi and f _{2, the} fluctuations in the state of the counter 7 go beyond the front of one pulse. Therefore, the Omake capacity of the counter 7 is chosen so that the code of the number Q (x), which determines the state of the counter 7 in the steady-state measurement mode, ensures that the condition OQ (tX Omake) is fulfilled. There are no pulses at the summing and subtracting inputs of the counter 6 and the output code of the counter number Y 6 remains unchanged.

When changing the average value of the frequencies fi and f ₂ or the average value of one of 40 of them, i.e. when the device is in transition mode, one of the counting inputs of the counter 7 receives more pulses than the other. The state of the counter 7 begins to change either in the direction of increasing, 45 or in the direction of decreasing the accumulated pulses until a pulse appears at the output of the forward or reverse transfer. This pulse through the second logical element OR 9 is fed to the synchronization input syn50 of the counter 7 record and the leading edge records the Q (t) code received at its information inputs from its information outputs along the trailing edge of the input pulse, and the limit state of the counter 7, which corresponds to the code of the number Q = 0 or O = 0 max, remains until the direction of accumulation of pulses in counter 7 changes. It follows from the foregoing that after counter 7 reaches one of the limiting states, each pulse is high frequency, uncompensated by a low-frequency pulse, is repeated at the corresponding transfer output, goes to the corresponding summing or subtracting input of the counter 6 and changes the code Y at the information outputs of the last and at the information input of the frequency divider 11 (through the second information input of the switch 13). Changing the code Y at the information input of the frequency divider 11 leads to a change in the time interval and, for which two pulses are received at the summing input of the counter 7, so that the imbalance between the time intervals pitg. caused by a change in the frequencies fi and f2 or one of them, decreased. This process is repeated until equality (7) is restored, after which the steady-state measurement mode sets in.

Described is valid if <(A + B) -C <K _ma 's, (9) where kmax - 6 meter capacity.

Obviously, provided:

· (A + B) - C> K _M ax f2 there is an overflow of the counter 6 and a pulse appears at its direct transfer output, which through the first logical element OR 8 is fed to the synchronization input of the counter 6 and records the code of the number of Kmax coming in to its information inputs from its own information outputs. In this case, the change in the code of the Kmax number is blocked at the information outputs of the counter 6 along the trailing edge of this pulse. Thus, after the Y value of Kmax is reached, a further increase in Y corresponds to the maximum number of Kmax specified by the code on the information inputs of counter 6. Similarly, the transition of counter 6 through zero is blocked under the condition il (A + B) -C <1, <2 information outputs of the counter 6 is fixed code zero. .

Thus, the proposed device for measuring the ratio of the frequencies of pulse sequences in comparison with known devices has improved accuracy for a wide range of measured frequency ratios.

Claims (1)

Claim A device for measuring the ratio of the frequencies of pulse sequences containing five input buses, the first and second reversible counters, the first and second OR elements, the first and second code-controlled frequency dividers, the first and second switches and the first trigger, the first input bus being connected to the counting input of the first code-controlled frequency divider, the information input of which is connected to the output of the first switch, the first and second information inputs of which are connected respectively to the third and fourth input bus ami, the control input of the first switch is connected to the output of the first trigger, the input of which is connected to the output of the first code-controlled frequency divider and the subtracting input of the second reverse counter, the direct transfer output of which is connected to the first input of the second OR element and the summing input of the first reverse counter, the outputs of the forward and reverse the transfer of which is connected respectively to the first and second inputs of the first OR element, the output of which is connected to the recording synchronization input of the first reverse counter, the information input of which is connected to the information output of the first reversible counter, the subtracting input of which is connected to the reverse transfer output of the second reversible counter and the second input of the second OR element, the output of which is connected to the recording synchronization input of the second reversible counter, the information input of which is connected to the information output of the second reversible counter whose summing input is connected to the output of the second code-controlled frequency divider, the counting input of which is connected to the second one bus, the information input of the second code-controlled frequency divider is connected to the output of the second emitter, the first information input of which is connected to the fifth input bus, the second information input of the second switch is connected to the information output of the first reversible counter and the device output, which is different from the purpose of increasing accuracy, and he introduced a second trigger, and the input of the second trigger is connected to the output of the second frequency divider, and the output of the second trigger is connected to the control input of the second switch.