SU1137438A1 - Timing signalling system for dispersed objects (its versions) - Google Patents

Abstract

1. A clock-signaling system for distributed objects containing a primary clock connected via a communication channel to a secondary clock, the primary clock consisting of a master oscillator with a divider connected to the counter block, a transmission block, and the secondary clock consisting of from the receiving unit, the decoder, the indicator, and in order to increase operational accuracy and enhance the functionality by ensuring the transfer of complex information, the primary clock is equipped with a control unit connected to the remote signaling unit, connected between the transmission unit and the counter unit, the output of which is connected to the synchronous input of the control unit, and the secondary clock is provided with a regenerator, an error analyzer, a synchronizer, and a call recorder connected in series with the reception unit, This high-frequency output of the synchronizer is connected to the second inputs of the reception unit and the regenerator unit, and the low-frequency output is connected to the second inputs of the indicator, recorder, alarm device, and one output The selector of the call is connected to the third input of the indicator and to the first input of the traffic signal, the input of the call selector is connected to the first output of the decoder, the input of which is connected to the error analyzer, and the second output is connected to the first input of the indicator. CO, -vl j ;: from 00

Description

7.7

2, a dispersed object clock-signaling system comprising the primary clock connected via the communication channel to the secondary clock, the primary clock consisting of a master oscillator with a divider connected to the counter block, the transmission block, and the secondary clock consisting of the receiving unit, the decoder, the indicator, is distinguished by the fact that, in order to increase operational accuracy and enhance the functionality by ensuring the transfer of complex information, the primary clock is equipped with a control unit, connected with a remote signaling unit connected between the transmission unit and the block

a counter, the output of which is connected to the synchronous input of the control unit, and the secondary clock is equipped with a regenerator, start-stop trigger, command selector and equalizer whose output is connected to the first indicator input, and the input is connected to the input of the reception unit connected to serially connected start-stop trigger, decoder ,, selector of commands, indicator, while the second output of the decoder is connected to the second input of the start-stop trigger, to the first input of which the first input of the regenerator connected to the second input is connected to the decoder, and the output - with the second input of the command selector and the third input of the indicator.

The invention relates to autonomous single-time systems and can be used to indicate accurate time signals on dispersed objects: devices, workplaces, in residential areas, in technological process control systems, for example, at remote telecommunication, transport, energy, etc. The closest in technical essence to the present invention is a clock-signaling system for dispersed objects, containing primary watches connected via a communication channel with secondary clocks, while the primary clocks consist of a master oscillator with a divider connected to a block of a transmission unit and the secondary clock consists of a decoder receiving unit and an indicator ll. The disadvantages of this system are low reliability, in particular, in the presence of interference in the communication channels, insufficient use of the VYAZ channels, as well as limited service types, since in addition to time signals, no additional data is transmitted from the center to remote objects. The purpose of the invention is to improve the operational accuracy and the expansion of functions. national capabilities through the provision of integrated information. The goal is achieved by the fact that in a clock-signaling system for dispersed objects containing a primary clock connected through a communication channel to a secondary clock, the primary clock consists of a master oscillator with a divider connected to a block of counters, a transmission unit, and the secondary clock consists of a receiving unit, a decoder, an indicator, the primary clock is equipped with a control unit associated with a remote signaling unit connected between the transmission unit and the counter unit, the output of which is connected to the synchronous input the control unit, and the secondary clock are fitted in series with the receiving unit by a regenerator, an error analyzer, a synchronizer, and a call selector, a signaling device connected to the recorder, while the high-frequency output of the synchronizer is connected to the second inputs of the receiving unit and the regenerator, and the low-frequency one to the second inputs of the indicator, recorder, alarm device, with one output of the call selector connected to the third input of the indicator and to the first input of the alarm device, and the input of the call selector is connected to the first the output of the decoder, the input of which is connected to the error analyzer, and the second output is connected to the first input of the indicator. When using a radio network, a second variant of the clock-signaling system for dispersed objects, containing a primary clock, connected by a communication channel with a secondary clock, is used, and the primary clock consists of a master oscillator with a divider connected with a block of counters The transmission unit and the secondary clock consist of a reception unit, a decoder, an indicator, in which the primary clock is provided with a control unit associated with a remote signaling unit, connected between the transmission unit and the counter unit, which is connected to the synchronous input of the control unit, and the secondary clock is equipped with a regenerator, a start-stop trigger, cejieKTOpoM commands and a corrector, the output of which is connected to the first indicator input, and the input is connected to the input of the reception unit connected to the serially connected start-stop r; the rigger, the decoder, the selector of the command, the indicator, while the second output of the decoder is connected to the second input of the start-stop trigger, to the first input of which is connected the first input of the regenerator connected by the second input to the decoder, and the output of th selector input of commands and third input indicator. It should be noted that the second variant of the device is advantageous when the radioactivity objects are covered by a radio network; you can do without communication channels in the system. Consolidation of the radio-broadcasting network with the signals of the partitioning and calling (excludes broadcasting in the overtonal frequency range. Figure 1 shows the first variant of the system block diagram; figure 2 shows the second variant of the system block diagram. The system consists of primary clocks containing the generator 1 with a divider, a block of 2 meters, a block of 3 remote signaling, a block of 4 controls, a block of 5 transmitters and connected via communication channel 6 with secondary clocks containing block 7 of receiving 8 pe8 generator 8, analyzer 9 about: front side, decoder 10, indicator II, registrar 12, village the call torus 13, the annunciator 14, the synchronizer 15. The system (according to the second variant / as part of the secondary clock also contains the start-stop trigger 16, the command selector 17, the equalizer 18. The clock-signaling system for distributed objects in the first variant) works as follows. It operates according to the principle of remote indication of indicators of primary clocks, and the signals of a single time are transmitted to the indicators every minute in the form of binary combinations of the noise-tolerant telegraph code (1440 minutes are transmitted every day signals. With a standard wiring speed of 50 Water, 450 ms is required to transmit time signals. every minute. The rest of the time is used for signaling and calling. The signals of the common time are received from the generator 1 with a divider into the block 2 of the counters, where the binary code combinations of the telegraph code are formed, corresponding to the second, minute and hour pulses. Block 2 is implemented as a matrix diode encoder with output triggers from which serial telegraph signals are taken. These time signals are entered every second into the remote signaling unit 3, where start codes (negative and stop (positive) signals are added to each code combination, as well as tele-signaling and calling subscriber code pulses generated in the control unit 4 manually (from the keyboard or automatically (by means of a programmable microprocessor included in block 4.) The sequence of entering the commands of the program of block 4 is determined by the signals from the sync output of the block 2 of the counters. Tele alarm signals are inputted units for signals of a single time and are sent to all subscribers of the clock system for notification (Alarm, Start, Stop, and other previously known commands transmitted by conditional telegraph code combinations. Call signals addressed to individual subscribers of the system are transmitted by two consecutive code combinations, the first which means the number of the subscriber, and the second - the calling command (/ to make a phone call, perform known actions, etc.). At a standard wiring speed of 50 Waters per minute, to 2QO paging code combinations. The television signaling unit 3 is executed in the form of a shift register, the time signal and the television signaling signals coming from the unit 4 pass through. The stationary current signals from the output of unit 3 are sent to the transmission unit 5, which is implemented as a frequency or amplitude signal. Pultover of a standard voice wiring system. Further, the voice signals are received via channels 6 of voice-frequency telegraphy to remote objects of partitioning and telephony, where they are demodulated by receivers of voice-frequency 7. From the output of reception unit 7, telegraph signals are sent to the start-stop regenerator 8, which eliminates temporal distortions and retransmits them through the error analyzer 9 to the decoder 10. The regenerator is implemented as a gating selector (scheme and) and a start-stop frequency divider of the pulses coming from the synchronizer 15 (multivibrator controlled by the signals of a single time, the Error Error 9 allows you to select error-free signals according to the criterion of periodicity by means of a time relay and code signs of signals through The parity check. Analyzer 9 is implemented in the form of a shift register with fixed taps and passes only error-free signals to the decoder 0. Diode matrix decoder 10 provides; separation of code combinations of one time and remote signaling is I. The pairs come to the indicator 1. And the second ones - to the call selector 13. This selector contains the key corresponding to the number of this receiver (Diode matrix) and And, which selects signals with this address. Therefore, from the output of the selector: 13 calls — the call signals come in: and the indicator 31 (LED or electric display 5 only when they are addressed to this reception, 86, i.e., the code combination corresponds to the key of the called subscriber device. At the same time, the code combinations come from the second output of the call selector tele-alarm to the signaling device 14, which decrypts commands addressed to this receiver (diode decoder with a command recording signal generator). From the output of the signaling device 14, command signals The recorder, teletypewriter, light panel, etc., which the storage of the received command is stored by the recorder 12 until the subscriber (operator) clears the readings, registers the alarm.In an emergency, if the analyzer 9 detects a series of errors, an alarm is generated puts the receiver into autonomous synchronization mode. In this mode, the synchronizer 15 controls the operation of the receiver for the time of the crash, and the synchronizer 15 is adjusted in this case or manually from the receiver fication or other system object from the radio precise time (input Correction}). The emergency transition to autonomous synchronization is fixed by the indicator 1I, the recorder 12 and the signaling device 14. When implementing the system, the indicator blocks 1 and the signaling device 14 are moved to the work places of the object and connected to one common subscriber unit. The clock-signaling system for dispersed objects (according to the second variant, works as follows. The receiving unit 7 is connected to the radio broadcasting network in which the time signals and calling commands are transmitted (for example, in the frequency range 200-210 kHz) and a binary signal detector, which is fed both to the input of the regenerator 8 and to the input of the start-stop trigger 16. The regenerator 8 is executed in the form of a gating selector (I circuit), with the strobe pulses being removed from all taps of the decoder 10. The decoder is triggered by a start / stop trigger 16 which translates into a starting position with a signal from receiving unit 7, and into stop position with a pulse from the last output of the decoder 10, which is also the selector of the subscriber. For this, certain KOMNryTHpyioTCH register taps to the input of the command selector 17 (each the subscriber has his own combination of taps in accordance with his personal number); this eliminates the possibility of receiving other people's ringing signals (a register of 10 taps provides 1024 different code combinations for numbering subscribers) ). The command selector 1 7 is triggered when its number is detected by a signal from the register-decoder 4 and analyzes the output signals of the regenerator 8, which carry information about the time and commands. Time signals periodically affect the digital indicator 11, showing four digits {hours and minutes. However, when the call signals are received, under the influence of the signal from the output of the command selector 17, the time indication stops and only the number indicating the command number remains on. Depending on the execution of the command selector (shift register, diode descrambler or memory register), the command signal can be received either in real time or at the request of the subscriber, which is convenient for outgoing subscribers (input Command request). A corrector 18 is connected between the input of the secondary clock and the digital indicator 11, which allocates the clock time signals transmitted over the radio broadcasting network and resets the digital indicator. The system allows using its variants to increase the efficiency of using communication channels in the clock system by condensing them with tele alarm and call signals; to improve the quality of servicing the objects of privatization by expanding the types of services in a single set of equipment without additional remote signaling and calling devices; increase interference: stability of broadcasting signals of a single time due to start-stop regeneration and noise-resistant coding of telegraph signals, duplication of sync signals in emergency operation mode.

Claims (1)

1. A clock-alarm system for dispersed objects, comprising a primary clock connected through a communication channel with a secondary clock, the primary clock consisting of a master oscillator with a divider connected to the meter block, a transmission unit, and the secondary clock consists of a receiving unit, a decoder , indicator, featuring me with that; which, in order to increase operational accuracy and expand functionality The telesignalization, the subscriber’s way of ensuring the transfer of complex information, the primary clock is equipped with a control unit associated with the telealarm unit connected between the transmission unit and the counter unit, the output of which is connected to the sync input of the control unit, and the secondary clock is equipped with a regenerator, analyzer connected in series to the reception unit errors, synchronizer, as well as a call selector, signaling device associated with the registrar, while the high-frequency output of the synchronizer is connected to the second the inputs of the reception unit and the regenerator, and the low-frequency one to the second inputs of the indicator, registrar, and signaling device, and one output of the call selector is connected to the third input of the indicator and to the first input of the signaling device, the input of the call selector is connected * * to the first output of the decoder, the input of which is connected to an error analyzer, and the second output is connected to the first input of the indicator.