SU411464A1 - - Google Patents

Description

The proposed discrete frequency subtractor can be used in information-measuring and computing equipment, in automation and remote control devices, in particular, to obtain a pulse sequence whose average frequency is equal to the current difference of two frequencies with or without the sign of the difference of these frequencies.

A discrete frequency subtractor with a two-channel conversion system is known, comprising an interleaved impulse elimination unit and a closely spaced impulse elimination unit consisting of drivers, anti-coincidence circuits, and coincidence circuits.

However, in the known device, the elimination of a pair of closely spaced pulses is achieved by locking the channels, as a result, the frequency range and speed of the device is limited.

In order to expand the frequency range in the proposed subtractor, the output of the first generator of the node for eliminating closely spaced pulses in each channel is connected to the input of the anti-matching circuit of the same channel and to the input of the anti-matching circuit of the other channel, the outputs of the anti-matching circuits are connected to the inputs of the second drivers and to the inputs of the matching circuits, whose second inputs are connected

with the outputs of the second drivers, and the outputs of the coincidence circuits are connected to the inputs of the node eliminating alternating pulses. The drawing shows the proposed discrete subtractor.

The subtractor contains drivers 1 and 2, anti-matching schemes 3 and 4, drivers 5 and 6, matching schemes 7 and 8, trigger 9 with separate inputs, matching circuits 10 and 11, trigger 12 with separate inputs and an assembly circuit 13.

The inputs of the subtractor are the inputs of drivers 1 and 2. The output of driver 1 is connected to the enable input of the anti-coincidence circuit 3 and to the prohibitory input of the anti-match circuit 4. The output of the driver 2 is connected to the enable input of the anti-match circuit 3 and the output of the anti-match circuit 3 connected to the input of the imaging unit 5 and the input of the coincidence circuit 7. The output of the anti-coincidence circuit 4 is connected to the input of the imaging unit 6 and the input of the coincidence circuit 8. The output of the coincidence circuit 7 is connected to the single input trigger and 9 and the input of the coincidence circuit 10. The output of the coincidence circuit 8 is connected to the zero input of the trigger 9 and the input of the coincidence circuit 11. The output of the coincidence circuit 10 is connected to the single input

trigger 12 and the input of the assembly circuit 13. Exit

the coincidence circuit 11 is connected to the zero input of the trigger 12 and the input of the circuit of the assembly 13.

The outputs of the subtractor are the outputs of the coincidence circuits 10 and 11, which are the outputs of the frequency difference / | and 2; the output of the coincidence circuit 10 — when; the output of the coincidence circuit 11 — with the single and zero outputs of the trigger 12, which are, respectively, the direct and inverse outputs of the sign of the difference between the frequencies of the first and second channels; the output of the assembly circuit 13, which is the output of the frequency difference without a sign.

The operation of the discrete frequency subtractor is carried out as follows.

The input signals are fed to the inputs of the formers 1 and 2, which produce square pulses of the same duration. If the pulses of the formers coincide in time, then the impulse of the second channel arrives at the prohibiting input of the anti-matching scheme 3 simultaneously with the clamping input of the anti-assignment scheme of the anti-adapter 3 of the impulse of the first channel and prohibits its passage through the first channel.

Similarly, the impulse of the first channel with the help of the anti-coincidence circuit, 4 prohibits the impulse to pass through the second channel.

If two incompletely matched pulses come to the inputs of the anti-coincidence circuits 3 and 4, their matched parts will be forbidden, and the remaining segments of the pulses start the shapers 5 and 6, which produce square pulses of the same duration as the pulses of the shapers 1 and 2. The coincidence circuits 7 and 8, triggered by the falling edge of the pulses arriving at their inputs, do not transmit shortened pulses, i.e., a pair of incompletely matched pulses is eliminated.

If the channels receive unmatched pulses in time, they are passed through the anti-matching schemes 3 and 4, the drivers 5 and 6 are started, confirmed by the matching schemes 8 and 7, and passed to the inputs of the pulse sequencing node. At the same time, the impulse that arrives at the first channel overturns trigger 9, which opens the circuit

coincidence 10 and closes the coincidence circuit 11. If the next pulse on this channel comes earlier than the pulse on the second channel (this happens if the frequency of the first channel is higher than the frequency of the second channel), then it will pass through the open coincidence circuit 10 and knock off the trigger 12 , which indicates that the frequency of the first channel is higher than the frequency of the second channel.

10 If, however, between the two successive pulses of the first channel, one pulse of the second channel passes, then it overturns the trigger 9, closes the coincidence circuit 10 and opens the coincidence circuit 11, and the second pulse does not pass through the first channel.

All of the above is similar for the case when the frequency of the second channel is higher than the frequency of the first drop, only differential frequency pulses occur at the output of the matching circuit 10, and a signal indicating which frequency is greater appears on the other arm of the trigger 12.

By means of an assembly circuit 13, the difference frequency outputs of both channels are combined.

Subject invention

A discrete frequency subtractor with a two-channel conversion system, the contents of an interleaved impulse elimination unit and a close-impulse elimination unit, consisting of drivers, anti-coincidence circuits, and coincidence circuits, in order to expand frequency range, the output of the first generator of the node for elimination of closely spaced pulses in each channel is connected to the input of the anti-adapter circuit of this

The channel 0 and the input of the anti-adapter circuit of another channel, the outputs of the anti-match schemes are connected per channel to the inputs of the second drivers and to the inputs of the coincidence circuits, the second inputs of which are connected to the outputs of the second drivers, and the outputs of the matching circuits are connected to the inputs of the alternate pulse unit.