SU558257A1 - Radio-clocks - Google Patents

Description

Connected to the installation inputs of the counter 4 times. The outputs of the time counter 4 are connected to the inputs of the indicators 5 and to the second inputs of the code comparison circuit 6. The code b comparison scheme can be executed, in example, in the form of bitwise adders modulo 2 ("exclusive OR"). The outputs of the circuit 6 are connected to the first inputs of the matching circuit 7, the second inputs of which are combined and connected to the output of the selector control signals (the signal of the end of the transmission of the time code transmission cycle), and the outputs of the circuits

7 assignments are connected to the analyzer inputs 8. The analyzer outputs are connected to the inputs of the combining circuit (OR circuit). The analyzer serves to analyze the frequency of the following mismatch of codes in each of the bits and can be performed, for example, as shown in FIG. 2, in the form of counters 10, the AND OR circuit, whose inputs are connected to the counter inputs, waiting for the multivibrator 12, whose input is connected to the output of the AND OR circuit, and the output to the input of the driver 13 for resetting the counters iU to its initial state.

The operation of the radio clock is considered for the following possible situations: normal operation in the steady state when there is no interference or a failure in the radio clock readings, in case of CO (failure is the abrupt random change of time under the action of any external or internal causes).

During operation, the time code from the output of the selector code signals of the receiver 1 through pre-explorer 2 is fed to the first inputs of the keys 3 of the code transfer and the code comparison scheme b. During normal operation, in the steady state mode, the time counter will always contain the same code as the output of the converter 2 codes and, since the incoming and the time codes in the time counter coincide at the time of the arrival of the cycle signal (i.e. as the code converter 2 is full and the cyclic signal comes to transmit the code), the outputs of the circuit b are compared with the codes, and accordingly, the outputs of the circuits 7 have no coincidence pulses. At the outputs of the analyzer

8 and the combination circuit 9, the pulses will also be absent, therefore the transmission of the code from the converter 2 to the counter 4 will not occur. This will continue until the time counter is closed, or a false signal at the output of converter 2 doesn’t but result from interference.

The second situation is possible - a failure in the readings caused by a random jump in the current time code at least in one of the bits of the time counter. The occurrence of the signal in this case, sig) 1al, at the time of the arrival of the cyclic signal, is transmitted from circuit 6 through circuit 7 to the inputs or at least to one input (if one bit fails)

analyzer 8 in the form of an impulse that starts through the circuit 11 OR the pending multivibrator 12 and arriving at the input of the counter 10 of the corresponding bit. The analyzer must issue a code transmission signal to correct the time readings only after, within a certain analysis time, the analyzer receives at least a certain predetermined value.

the number of pulses causing a signal at the output of counter 10 (for example, an overflow signal). Irie performing an analyzer according to the diagram of FIG. 2 analysis time is determined by the duration of the waiting pulse.

multivibrator 12, the leading edge of which serves to generate reset pulses of the analyzer counters 10. Iri radio clock failure frequency of the mismatch pulse is equal to the frequency

following the cyclic pulses, and one of the counters 10 of the analyzer during the analysis of the hectare should become overcrowded and give (through the unification scheme 9) a transmission resolution impulse to the keys 3, i.e.

compliance with conditions, where K. is the capacity of each counter 10, 7H is the duration of the code transmission cycle. When a code transfer pulse arrives at the keys 3, the code is rewritten from converter 2 to counter 4, i.e., the time is set to the correct time, and the radio clock continues to operate in the normal steady state mode.

described above. At the end of the analysis time, a pulse of resetting the counters 10 of the analyzer to the initial state is formed from the falling edge of the pulse of the waiting multivibrator 12.

If there is interference and, accordingly, errors in the converter 2 code, the radio clock operates as follows.

A viral - cyclic signal after the occurrence of interference will pass as a result of a mismatch of codes through circuit 7 to one of the analyzer inputs and start it (it will start pending multivibrator 12) and one of the counters 10 will calculate the first mismatch of codes. AT

the next cycle at the time of arrival of the cycle signal mismatch codes will be counted either by the same counter 10 as in the first cycle, or by some other counter 10 depending on the temporary position of the interference. In the following cycles, the number of mismatches will be counted in a similar way. In order for the number of mismatches to be counted by the same counter, it is necessary that

temporary position of interference in each cycle

during the analysis, it would be unchanged with respect to the pulses of the cycle and the code, i.e., that the interference impulse would occur exactly on the same code bit and would always cause a change in the state of this code bit to the opposite, i.e. . The probability of occurrence of interference, satisfying these requirements, is very small even with a relatively short analysis time (2-3) Hz.

Interference pulses that have a random temporal position from cycle to cycle will be counted by different counters 10 and after a time Ga the counters will return to their original position.

Thus, even if the level of interference is so high that in each cycle there are erroneous combinations of the received code, but the temporary position of the erroneous discharge is not constant from cycle to cycle, transmission of the erroneous combination from the converter to the time counter will not occur and the clock will continue to correct work.

The proposed radio clock circuit also protects against false cyclic or clock pulses, since the mismatch of codes at the time of the arrival of a false cyclic pulse or the passage of a false clock pulse does not cause the code to be transferred from the code converter to the time counter.

Claims (2)

1. The patent of Switzerland No. 525512, cl. G 04C 11/00, publ. 09/17/72. 2.Certificate of certificate No. 2133099/10, M. Cl.2 G 04C 11/00, 14.05.75. U3.Z