SU318903A1 - ALL-UNION F1W! 1at- ^ attssbB? -; - Google Patents

Description

DEVICE FOR DETERMINING TEMPORARY SHIFT

The invention relates to the field of electrical measuring devices.

It is known device auth. St. No. 284702 for automatic determination of the time shift between the second pulses of a quartz clock and time signals.

The disadvantage of this device is that the accuracy in determining the time shift between the second pulses of a quartz clock and the time signals, which is a consequence of the measurements of the envelope of the time signals, is not high enough.

The aim of the invention is to improve the accuracy of the automatic determination of the time shift between the second pulses of a quartz watch and the accurate time signals, carried out due to the transition to measurements of the carrier of accurate time signals.

This goal is achieved by the fact that the proposed device is equipped with a torque sensor corresponding to the zero phase of one of the periods of the carrier frequency of the time signal of which the input is connected to the output of the receiver; the time interval meter, one input of which is connected to the output of the zero phase carrier moment sensor, the second input is connected to the output of the master quartz watch, and the output of the meter is connected to one of the inputs of the computing device.

device; in fig. 2 is a block diagram of a torque sensor.

The output of the receiver / is connected simultaneously to the inputs of the sensor 2 of the moment of the zero phase of the carrier of the time signal of the sensor and the sensor 3 of the moment of the constancy of the slope, to one input of the meter 4 voltage and to one input of the meter 5 of the slope. The output of sensor 2 is connected to one of the inputs of the meter 6 time intervals, the second input of which is connected to the output of the quartz clock 7. The output of the sensor 3 of the moment of constant slope is connected to the second inputs of the meter 4 and the meter 5 and to one input of the meter 8 time intervals, the second input which is connected to the output of the quartz master clock 7. The sensor outputs 2, the voltage meter 4, the slope meter 5, the 6 time intervals meter and the 8 time intervals meter are connected to the corresponding computational inputs troystva 9.

The zero-phase moment sensor of a carrier consists of a series-connected generator of 10 pulses, tied to zero phases of the periods of the carrier signal of the exact time, and a recirculator //. The recirculator contains an adder 12 pulse signals, one input of which is connected to the output of the generator 10; delay line 13, the input of which is connected to the output of the adder 12, pulse shaper 14, the input of which is connected to the output of the delay line 13, and the output connected to the second input of the adder 12; a threshold device 15, the input of which is connected to the output of the adder 12, and the output is the output of the recirculator 11 (i.e., the output of the zero phase carrier moment sensor).

The pulse generator 10, tied to the zero phases of the periods of the time signal carrier, and the threshold device 15 are made in the form of Schmitt triggers.

Pulse adder 12 is a video amplifier with resistive-capacitive dividers at both inputs.

The radio signal of the exact time, the leading edge of which is linear, is fed to the receiver input U and from the output of its intermediate frequency amplifier is fed to the input of sensor 2, and from the detector output of the receiver / is fed to the input of the sensor of the momentum constant of the voltage and on one of the inputs of the slope meter.

The zero-phase moment sensor of the carrier gives out a pulse signal to the pulse, causing Hbuu to zero-phase of one of the periods of the carrier frequency of the radio pulse arriving at its input. The pulse signal, s, the output of the sensor 2 is fed to one input of the meter 6 of the time interval, the second input of which receives a second pulse from the master quartz watch 7.

The meter 6 outputs at the output in the form of a potential code the value of the time shift between the pulse signals arriving at its inputs. The measured value of the time interval is fed from the output of the meter 6 to the first input of the computing device 9.

As is known, the front of the signal envelope at the output of receiver 1 has a linear portion. At the moment when the voltage at the output of the receiver 1 reaches this section, the sensor 3 generates a pulse signal at the output. The pulse signal from the output of the sensor 3 is supplied to the second input of the meter 4, to the second input of the meter 5 and to one input of the meter 5.

Voltage meter 4 outputs, in the output in the form of a potential code, the value of the signal voltage at its first input at the moment the pulse arrives at the second input. The measured value of the voltage of the signal is supplied from the output of the meter 4 to the second input of the computing device 9.

The meter 8 outputs at the output in the form of a potential code the value of the time shift between the pulse signal from the sensor 3, arriving at one of its inputs, and the second pulse from the master quartz clock 7, arriving at the second input. The measured value of the time interval is supplied from the output of the meter 8 of the time interval to the fourth input of the computing device 9.

the data arriving at its inputs calculates the magnitude of the shift in the instant of the start of the signal of the exact time relative to the second pulse of the local standard.

The zero phase carrier moment sensor operates as follows. The radio pulse signal of the exact time from the output of the receiver’s intermediate frequency amplifier / is fed to the input of the pulse generator, at the output

which is formed by a sequence of pulses, the moments of occurrence of which coincide with the zero phases of the periods of the carrier frequency of the signal at its input. The pulse sequence from the output of the generator 10 enters the input of the recirculator //, eliminating the false alarms of the pulse generator.

Recirculator 11 (Fig. 2) works as follows. The first pulse of the sequence from the output of the generator 10 is fed to one input of the adder 12, without changing, passes to its output and is fed to the input of the delay line 13. Line 13 delays the pulses arriving at its input by the magnitude of their repetition period. The first pulse of the sequence from the output of the delay line 13 is fed to the input of the former 14, which sharpens the fronts (shape improvement) of the input pulse.

From the output of the former 14, the first pulse of the sequence arrives at the second input of the adder 12, where it is added to the second pulse of the sequence. The resulting (total) pulse from the output of the adder passes through the delay line again and the driver 14 arrives at the input of the adder, where it is added to the third pulse of the sequence. This process is repeated until the amplitude of the folded pulses and the output of the adder 12 exceeds the threshold of the threshold device 15. When triggered, the threshold device generates a pulse signal at the output, the leading edge of which is tied to the zero phase of one of the periods of the radio pulse at the input Sensor 2 moment Zero phase carrier.

Subject invention

Device for determining the time shift by aut. St. No. 284702, characterized in that, in order to increase the accuracy of automatically detecting the time shift between the second quartz clock signals and the accurate time signals, it is equipped with a torque sensor corresponding to the zero phase of one of the periods of the carrier frequency of the exact time signal whose input is connected to the receiver output; a time interval meter, one input of which is connected to the output of the zero phase carrier moment sensor, the second input is connected to the output of the master quartz watch, and the output of the meter is connected to one of