SU445132A1 - Multi-frequency generator - Google Patents

Description

. This invention relates to the field of automation.

A multi-frequency oscillator is known, which contains a clock current generator, one output of which is connected to the inputs of the derv-oh and second coincidence circuits, and the second output to the inputs of the third and fourth coincidence circuits, control keys and counting trigger, whose input is connected to the output of the first counter, connected to the output of the third coincidence circuit, and a reset input to the output of the first coincidence circuit.

In order to increase the number of frequency signals in a given frequency band, a trigger is entered into the device, a decoder and a second counter, the outputs of which through the decoder and control keys are connected to one trigger input, the second input of which is connected to the common connection point of the output of the first counter to the counting trigger, odi

the output is connected to the second inputs of the first and fourth matching circuits, and the second output to the second inputs of the second and third matching circuits, with the output of the second matching circuit connected to the reset input of the second counter, and the output of the fourth matching circuit to the counting input of the second counter.

The drawing shows the block diagram of the proposed multi-frequency generator.

The generator contains a clock generator I, a switching unit 2, consisting of four liters: an optical circuit 3-6 matches and a trigger 7, a first pulse counter 8, a trigger 9 with a counting input, a delay block 10 that includes a second pulse counter II and a decoder 12, and. control keys 13, 14 and 15, the number of which corresponds to the number of frequency signals, i The generator works as follows 3, If the keys 13,14 and 15 are open and trigger 7 is in that position when its output (indicated by a dot) A preparatory signal arrives at the input of logic circuits 3 and 5 (for example, the output of these coincidence circuits is a sequence of pulses whose frequency corresponds to the frequency of an uninterrupted clock generator I. This generator can be performed according to the symmetric multiviral circuit The oscillator and the outputs 16 and 1 are the outputs from the different arms of the multivibrator. The pulse sequence from the output of logic circuit 5 is sent to the reset circuit of the first counter 8 and sets it to its original state. In turn, the pulse sequence from the output of logic circuit S enters the counting input of the second counter II. Counter II counts the number of incoming pulses, then overflows, resets and starts to read again. The decoder 12 is connected to the outputs of counter II, which transforms the code combinations, s from the counter bits to the position code. The keys 13, 14 and 15 of the control can be connected to certain outputs of the decoder 12 in any order. If at some point in time key 13 closed, then when counter II counted a certain number of pulses at the output of decoder 12 connected to key 13, a pulse appears corresponding to I. This pulse passes through key 13 and enters circuit 18 trigger 7. Trigger 7 changes its state, whereby logic circuits 3 and 5 close, and logic circuits 4 and 6 open. The pulses from the clock generator I pass through logic circuit 4 into the reset circuit of counter II and through logic circuit b to the counting input of the second counter 8. The latter counts a certain strictly fixed number of pulses m, then from one of its outputs in circuit 19 a pulse arrives corresponding to I, to the counting input of trigger 9 and to the second input of trigger 7. Both flip-flops change their state. At the output 20 of the trigger 9, a voltage appears corresponding to the beginning of the pulse In the communication channel. In turn, trigger 7 opens logic circuits 3.5 and closes schemes 4.6. As before, counter 8 is reset, and counter II starts counting pulses from clock I. When a certain number of pulses, l, is reached, output of decoder 12 is transmitted through closed key 13 through circuit 18 to trigger input 7 by pulse I. Trigger 7 turns off Logical circuits 3.5 and opens logic circuits 4.6. Counter II is reset, and counter 8 starts counting the clock pulses of generator I. When counting ii pulses, a pulse corresponding to I appears at its output, and then triggers 7 and 9 change their state. Counter 8 is reset, and counter II starts counting the next KU pulses. When the state of the trigger 9 changes, the transmission of the pulse to the communication channel is completed. The pulse burden t and is determined by the total number of pulses recorded by the first and second counters 8.11 and arriving with a period tg of operation of the clock generator I, i.e. i 1 - i tg (p. + 1) After counter II calculates its n pulses, and 8 m pulses with a counter, trigger 9 changes its state again and the next pulse starts to be transmitted to the communication channel. In a multi-frequency generator, the pause time is equal to the pulse time, so the frequency of the pulses generated on the communication channel is determined by the expression / -0.5 ng (The generation of pulses of the multi-frequency generator continues for the duration of the closed key 13. If the new key is closed after this (for example 14), then the number of impulses fixed by the counter, for example, K, before the appearance of the signal I in circuit 18 is different from and .. Then from the generator output comes a sequence of pulses with frequency / equal to S C.ijr Each key in the generator corresponds to generating pulses. 11 re day of invention. A multi-frequency generator containing a clock generator, one output of which is connected to the inputs of the first and second matching circuits, and the second output - to the input of the third and fourth matching circuits, control keys and a counting trigger, whose input is connected with the output of the first counter, the counting input of which is connected to the output of the third coincidence circuit, and the reset input — to the output of the first coincidence circuit, characterized in that in order to increase the number of frequency signals in a given frequency band, it has a trigger, a decoder and a second counter, the outputs of which through the decoder and control keys are connected to one input of said trigger, the second input of which is connected to the common connection point of the output of the first counter to the input of the counting trigger, one output is connected to the second inputs of the first, and even-; the matching matching circuit, and the second output to the second inputs of the second and third matching circuits, the output of the second matching circuit being connected to the reset input of the second counter, and the output of the fourth circuit; match - with the counting input of the second counter.