SU932640A1 - Device for discriminating clock frequency - Google Patents

Description

(5) DEVICE FOR CURRENT FREQUENCY

one

The resolution relates to a communication technique and can be used in communication systems with pulse code modulation as clock extractors and signal multipliers.

A clock frequency device is known that contains a prohibition block connected in series, an OR element, a narrow-band filter, a pulse shaper, and a delay unit to whose input the output of the OR element is connected, and the output of the delay unit connected to the information input of the prohibition block 1.

However, the known device has low noise immunity and low accuracy.

The purpose of the invention is to improve noise immunity and accuracy.

Claims (1)

This goal is achieved by the fact that a blocking unit, an OR element, a narrowband filter, a pulse shaper, and a delay unit, whose input is connected to the output of the OR element, and the output of the delay unit, are connected to a clock-frequency device containing a clock unit, the first element And, the first trigger and the controlled valve, as well as the pulse counter and the second element And and the second trigger, which are connected in series, are introduced in series, the second input of which is connected the output of the pulse counter, while the first and second additional outputs of the delay unit are connected respectively to the first input of the first element AND and the second input of the first trigger, the output of which is connected to the first prohibitory input of the prohibition unit, to the second prohibitory input of which and the second input of the first element I is connected to the output the second trigger, and the output of the control valve 1 is connected to the third prohibitory input of the prohibition unit 39, the second input of the OR element, the first input of the second AND element, and the installation input account snip pulse to the count input connected kotorrgo prohibition unit output and the output of the delay unit is connected to the second input of the second element I. In FIG. 1 shows a structural electrical circuit of the device; FIG. 2 - timing charts of the device. The clock selection device contains a prohibition block 1, an OR element 2, a narrowband filter 3, a pulse shaper k, a delay block 5, the first element AND 6, the first trigger 7, a controlled valve 8, the second element AND 9 the second trigger 10, a counter 11 pulses. The device works as follows. In the initial state, the controlled valve 8 is open, the pulse counter 11 is in an arbitrary state of the SRI, and the second trigger 10 is in the zero state, blocking the prohibition block 1 on the second prohibitory input and holding the first element in the closed state. The delay time of the delay unit 5 is chosen to be a multiple of the pulse repetition period of PCM signals in the communication channel. In the circuit, an OR 2 element — a delay unit 5 and a prohibition unit 1 — the first input of the OR element 2 is not present in the pulse circulation (Fig. 2c1). The first PCM input pulse (Fig. 20), having passed through the open controlled valve 8, sets the pulse counter 11 to the zero state, passes through the element OR 2 (Fig. 2d), the narrowband filter 3 and the driver to the device output. In addition, after a time equal to the duration of the individual PCM pulse, the pulse from the communication channel appears at the first additional output of the delay unit 5 and arrives at the first AND 6 element, which is blocked at the second input by the output signal of the second trigger 10 After time T - 2JT from the moment the device arrives at the device input, the incoming pulse appears at the second additional output of the delay unit 5 and confirms the initial state of the first trigger 7 (Fig. 2-6), here T is the PCM pulse period in the channel .zi communication, and - - the relative nestabilnocY oscillators (system transceivers). Exactly through time T, the incoming pulse appears at the output of the delay unit 5 and arrives at the information input of the prohibition block 1 and at the first input of the second element AND 9 If at this moment the next input pulse is present at the output of the controlled valve 8, then the pulse from the output of the block 5 the delay passes through the second element And 9 and switches the second trigger 10 (Fig. 21), removes the prohibition from the second prohibiting output of the prohibition block 1 and unlocks the first element And 6 through the second input. This (previously received) pulse does not pass to the first input of the OR 2 element, since the third prohibiting input of the prohibition unit 1 contains an input pulse from the output of the controlled valve 8. But then the pulse from the output of the controlled valve 8 passes through the OR 2 element to the first additional the output of the delay unit 5 and through the unlocked first element AND 6 switches the first trigger 7, blocking the control valve 8 through the control input and the prohibition block 1 on the first inhibit input. Thus, if an interference pulse passes between the first and second PCM pulses at the device input, it is erased in block 1 of the prohibition by the first switching of the first trigger 7- After time T - t from the moment of switching the first three | Hera 7 pulse appears at the second additional output of block 5 delay and returns the first trigger 7 to its initial state, removes the lock from the control input of the controlled valve 8 and from the first inhibit input of the prohibition block 1, and after 22gT this pulse is at the output of block 5 delay. If at this moment zero is transmitted in the PCM signal, i.e. there is no pulse at the output of the controlled valve 8, then the pulse from the output of the delay unit 5 through the prohibition block 1 open at all inputs passes to the first input of the element. OR 2 and the counting input of the counter 11 pulses. This pulse circulates in the circuit, switching the first trigger 7 on each period, until the next PCM-signal input pulse or the counter 11 pulses is filled in phase at the next clock cycle at the output of the controlled valve 8 through 59. Moreover, due to the switchings of the first trigger 7. The passage to the input of the said circuit of random impulse noise in this mode is practically excluded. Pulse counter 11 has a capacity that is a multiple of the maximum possible zero series in the PCM signal. By filling it (Fig. 2d), the second trigger 10 is switched to the initial state, which blocks through the second inputs, the prohibition block 1 and the first element 6, due to which the circulation of the pulse in the circuit is stopped and the device returns to the initial state. after a pause, the input pulse passes through the open controlled valve 8, sets the pulse counter 11 to the zero state and the process repeats as described above. Due to the circulation of the input pulse in the circuit, the OR 2 - block 5 delay unit m is the first input of the element OR 2 at the output of the driver L in the receiving mode, a regular sequence of pulses takes place, i.e. the clock frequency of the VIKM signal. If the first pulse that came from the communication channel, the delay unit 5 passed does not coincide in phase on the second element AND 9 with the next input pulse, the second trigger 10 does not switch, the prohibition block 1 remains blocked with the second prohibitory input and the device remains in the initial state. Thus, unblocking from the second prohibiting input block 1, and consequently, the occurrence of pulse circulation in the circuit and switching the device to the receive mode, can occur only when the PCM synchronization signal arrives at its input. If the device receives two pulse interferences following each other with an interval exactly equal to T, then due to the presence of the first trigger 7 and the controlled valve 8, the circulation of the interference in the circuit will be stopped by the pulse counter 1 after its filling and the device returns to its original state. Thus, the proposed device provides increased noise immunity by eliminating the occurrence of random impulse noise in the receive mode, and also ensures high accuracy in the device entering the receive mode. The invention provides a clock-frequency allocation device comprising a series-connected prohibition unit, an OR element, a narrow-band filter, a pulse shaper, and a delay unit, to the input of which the output of the OR element is connected, and the output of the delay unit is connected to the information input of the prohibition unit, characterized in , in order to improve noise immunity and accuracy, the first element I, the first trigger and the controlled valve, as well as the pulse counter, are sequentially connected into it and are connected in series The second element And and the second trigger, the second input of which is connected to the output of the pulse counter, the first and second additional outputs of the delay unit are connected respectively to the first input of the first element And and the second input of the first trigger, the output of which is connected to the first prohibitory input of the prohibition block, to the second prohibitory input of which and the second input of the first element I the output of the second trigger is connected, and the output of the control in: the impeller is connected to the third prohibitory input of the prohibition unit, the second input is of the OR element, the first input of the second element AND and the installation input of the pulse counter, to the counting input of which the output of the prohibition unit is connected, and the output of the delay unit connected to the second input of the second element I. Sources of information taken into account during the examination 1. USSR author's certificate ff , cl. H About L 7/02, 1975 (prototype) J