SU413610A1 - - Google Patents

Description

one

The invention can be used in telecommunications, in particular in the equipment for the transmission of discrete signals.

A device for allocating a clock frequency is known, which contains a rectifying circuit that is necessary to restore the envelope of the received pulse train. The rectifier circuit is connected to an oscillatory circuit at which the clock frequency is allocated.

Under the optimal excitation condition, sinusoidal oscillations with the greatest amplitude and minimal phase fluctuation are generated on the oscillating circuit, if exciting pulses are applied to it, the duration of which is equal to half the period, and the time intervals between individual pulses are multiples of the natural oscillation period, each excitation occurs in one and same phase. However, due to the fact that the signal undergoes distortions in the process of transmission, in a known device, pulses having fluctuations in duration and phase are transmitted to the Ko. bend circuit. In addition, the oscillatory signal received by g interference. This worsens the conditions for the excitation of the oscillatory circuit and causes a decrease in the non-immunity, which leads to a decrease in the voltage amplitude and an increase in the phase fluctuations of the selected clock frequency.

The aim of the invention is to reduce the 1st phase fluctuations of the clock frequency fluctuations and increase reliability.

For this, in the proposed device, the output of the rectifier circuit is connected to the input of the additionally introduced matching circuit, the other input of which is connected to the output of the oscillating circuit through a series of additional inputted to the delay line and driver, and the output of the coincidence circuit is connected to the input of the oscillating circuit.

The drawing shows a block diagram of the described device.

Rectifier 1, made, for example, according to the bridge circuit, is connected to the first input of the matching circuit 2, connected to the oscillatory system 3, which is, for example, an LC circuit followed by a delay line 4 connected to the input of the imager 5. The output of the imager 5 is connected to the second input of a matching circuit 2.

The device works as follows.

The received pulses are fed from the input to the rectifier 1, from the output of which the received unipolar pulses are fed to the first input of the matching circuit 2. To the second input of the matching circuit 2 before arriving at

The output device of the received pulses is applied a constant bias voltage, which is a signal of resolution. From the output of the coincidence circuit 2, the first pulse acts on the oscillatory system 3, tuned to the clock frequency, exciting sinusoidal oscillations in it. Selected oscillations of the clock frequency are fed to the output. The oscillations of the clock frequency are transmitted through the delay line 4 to the shaper 5, where 3 rectangular pulses with a duration of half a cycle are formed. To simplify the description of the operation of the device, we assume that the delay time of delay line 4 is zero. In this case, the coincidence circuit 2 is transferred alternately to the prohibit and release state in accordance with the signal from the output of the imaging unit 5 to the second input of the coincidence circuit 2. The delay line 4 is switched on to ensure the synphasis of the signals arriving at the first and second inputs of the coincidence circuit 2. Thus Thus, the coincidence circuit 2 is unlocked by the resolution signal at the clock moments for a time equal to half the cycle and transmits pulses of half a cycle duration to the oscillatory system.

Almost always there is a small discrepancy between the natural frequency of the oscillatory system 3 and the frequency of the received pulses. This leads to the fact that the rectangular signal of the resolution is fed to the second input of the coincidence circuit 2 not exactly in time with the received pulses, and is somewhat shifted to one of the edges of the received unipolar pulses.

The fluctuation of the phase of the received pulses is much greater than the fluctuation of the phase of the rectangular pulses of the gating signal, since it is known that the coefficient of phase permeability, i.e., the ratio of the fluctuation of the phase at the output and input of the oscillatory system is much less than one. In this case, the position of the pulse fronts at the input of the oscillating system is mainly caused by fluctuations of the phase of the received unipolar pulses.

If the natural frequency of the oscillatory system is lower than the frequency of the received pulses, then the rectangular impulses of the resolution signal are shifted to the falling edge of the received single-pole pulses. In this case, the pulses at the input of the oscillatory system. We have a fluctuation of the phase of the falling edges, due to the fluctuations of the phase of the rectified pulses rectified in a certain area.

Thus, pulses are supplied to the input of the oscillatory system, the duration of which is approximately equal to half a beat, and the fluctuation of the phase of their fronts is reduced compared with the fluctuation of the phase of the fronts of received pulses. In addition, the effect of interference on the oscillatory system in the intervals between the rectangular pulses of the resolution signal is prohibited.

As a result, fluctuations in the phase of the oscillation of the clock frequency are reduced and the noise immunity of the clock extractor is increased, which corresponds to the goal.

Subject from b ete and and

A clock selection device comprising a rectifier circuit and a oscillating circuit, characterized in that, in order to reduce the phase fluctuations of the clock frequency fluctuations and increase reliability, the output of the rectifier circuit is connected to the input of an additionally introduced coincidence circuit, another input connected to the output of the oscillating circuit through a serial chain of additionally introduced delay line and driver circuits, and the output of the coincidence circuit is connected to the input of the co-hegebal contour.

B (od

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