HU191856B - Method and device for remote checking regenerator units used in data transferring systems with expansion of number - Google Patents

Abstract

The invention relates to a method and device for remotely controlling regenerative repeaters in a group of unmanned, that is to say automatically operating multi-channel digital pulse-code-modulation systems which are used in communications engineering and in systems for data transmission. It is the object of the invention to create a method and a device for automatic remote control of regenerative repeaters in a group of multi-channel digital PCM systems without interruption of transmission, which provide for simultaneous control of all regenerative repeaters on the path. The method according to the invention for the remote control of regenerative repeaters and the device for carrying out the method use an additional pair of wires and corresponding locating code combinations which are processed in the main terminal station. Due to the system formed by the devices in the main terminal station and in the unmanned regeneration points, the main terminal station simultaneously controls a number n of multi-channel line paths in both directions of transmission with a number m of regeneration points without interruption of transmission, the numbers of unstable or damaged regenerative repeaters and the numbers of the corresponding regeneration points where these regenerative repeaters are located being indicated in the terminal station. In the main terminal station, the numbers of the regeneration points are also indicated which exhibit a pressure change, existence of moisture or opening of the cover. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a method for remote control of regenerator units used in automatic multichannel number-compression data transmission systems, and apparatus for implementing them in the field of telecommunication technology and data transmission systems.

A method of remotely controlling automatic regeneration points and localizing damaged regenerator units is known to emit digitizing signals from terminal A to another terminal B in the form of a periodic pulse sequence. The repetition frequency of their casing is different for each automatic regeneration point. If a specific regenerator is undamaged in direction A-B, 1 regenerates the output signal and activates a relay through the filter at the automatic regeneration point.

After the localization signal is interrupted, the relay remains energized and through its second pair of contacts and a matched four-pole, the signal is fed to another regenerator input B-A, from which output the signal returns to the control station. The presence or absence of a signal allows one to judge the correct condition of the controlled bilateral regenerator. After the check, the power supply is interrupted for a moment before the relay is released and its contacts are disconnected. Such a procedure is described by G. Bitschew, "Mehrkanalige Ziffemsysteme". 1980.

There is also known a method for remotely controlling automatic regeneration points and locating damaged auto regeneration points and the regenerator units therein, which may be implemented by means of an additional pair of connecting wires. This method can be found on pages 161 and 164 of the literature. The procedure generally allows one pair (up to six pairs) of regenerator units to be checked in a single direction at a single automatic regeneration point. A localization signal is output from terminal A to check for an optional regeneration point comprising two one-way regenerator units. The automatic regeneration point includes a bandpass filter that is common to all one-way regenerator units. The outputs of each regenerator unit are led to the inlet of the bandpass filter, while separated by high-value resistors. The localization signal has a small ohmic component which is an evaluation signal; serves as sulfur. For this purpose, a special algorithmic bar code is used, in which the localization signal is made up of a group of three pulses (triads). The periodicity with which the triads are mixed into the localization signal determines the frequency used to control the given auto-regeneration point and localize the condition. The density of triads is altered by the nature and amount of numerical errors on the road and in the regenerator unit. Information on the status of the regeneration units is provided by an amplitude of the DC component of the frequency signal characteristic of the host station to the host station A.

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The main shortcoming of these two procedures is that data transmission is interrupted for the duration of the check. In multichannel data compression systems, the number of checks is very large and is equal to the number of line paths multiplied by the number of regenerator units. A further disadvantage of the known methods is that the failure factor of the regenerator units cannot be determined.

Apparatus for remote control of regenerator units without interruption of data transmission is disclosed in Soviet Authorization Certificate 777,842, which has a zero interval unit and an AND gate at transmission point A, the second input of which is connected to a test generator, and a second circuit connected to the input of the zero interval output unit. Everything in the equipment

Ό some auto regeneration points have serially connected auxiliary units for output of the test result, as well as analyzers, storage units, error detection and totalization transmitters and a number on the regenerator output (auxiliary unit for generating the test result. The output of the regenerator is connected to the inputs of the regenerator and the analyzer.

The main disadvantage of the described apparatus is that it is capable of remotely controlling a single one-way regenerator unit of some automatic regeneration points. To check N lines, we need to perform a 2N test, since the number of one-way regenerator units is twice the number of line paths.

The object of the present invention can be defined by the need to provide a method and apparatus for remote monitoring of regenerator units used in automatic multi-channel number compression data transmission systems without interrupting data transmission during the control.

SUMMARY OF THE INVENTION The present invention is solved by a method for remotely controlling regenerator units used in automated multichannel data compression systems using localized code combinations to determine the priority of the transmitted information at the main terminal and for dynamic indication. This method has been further developed in accordance with the present invention by checking n multi-channel lines independently, continuously and simultaneously from a main station at m automatic regeneration points in both transmission directions, indicating the number of unreliable or failed regenerators at the main station and displaying an automatic regeneration point containing the regenerator by examining the regenerator information for error rate and storing the information when a given error margin is exceeded,

191 S56 transmits incomplete priority information passing through an additional auto regeneration point, together with the address information of the faulty regenerator, to the main station in which the priority information is regenerated through each automatic regeneration point.

The object is further solved by an apparatus implementing the method according to the invention, comprising an additional pair of wires between the automatic regeneration point and the main station, the latter having a unit for determining the priority of the transmitted information connected to a dynamic indicator input. This apparatus is further developed in accordance with the present invention by connecting a shift register shift input to a synchronization stage output, the first input of which is coupled to a tilt circuit output, the receiver input of an incremental pair of logic NOs of the previous auto regeneration point, and The first input of the ES gate, the second input of the latter, the frequency divider output of the latter, and the output of the non-AND gate are connected to the write enable input of the shift register, the parallel data outputs of the shift register are , while the output of the frequency divider is connected to the clock input of the counter and the parallel outputs of the reference stage of the input of the shift register, the shift register connected to the corresponding parallel outputs of the storage parallel input connected to the parallel control inputs of the analogue multiplexer parallel to the storage parallel input, the outputs of the regenerators being connected to the parallel inputs of the analog multiplexer whose output is connected to and the output of the shift register is connected to the transmitter input of the shift register and the output of the transmitter for the last auto-regeneration point in the queue through the additional pair of pairs to the master of the master.

According to a preferred embodiment of the device according to the invention, each automatic regeneration point is assigned a separate rate generator.

It is also advantageous according to the apparatus of the invention that the clock generator is a quartz generator located at the main station and communicating with the step register, synchronization stage and frequency divider via a transmitter and a receiver, each transmitter and receiver of the automatic regeneration point being connected in series .

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the drawing, which is a block diagram of some exemplary embodiments of the apparatus implementing the process. In the drawing it is

Figure 1 is a block diagram of a device for remote control of regenerator units used in automatic multi-channel data compression systems, and

Figure ¹⁰ is a second part of the block diagram of Figure 1. In the case shown impulse generator and application of separate transmitters and receivers.

The exemplary apparatus for carrying out the process of the present invention comprises an additional pair of vessels ¹⁵ between automatic regeneration points 5 and a main station 2, in which it is connected to the dynamic indicator input 4 of a unit 3 which determines the priority of injection. The shift input of the shift register 80 is connected to the output of a synchronization horse 17, the first input of which is coupled to the receiver output 18 via a decision circuit 19. The input of receiver 18 is connected to an additional pair of wires 1 of the previous automatic regeneration point 5. A plurality of inputs are connected to a logic NOT or 21 gate output of a ^25- pin logic with a first input of a logical NO AND 22 gate and a second input of the latter with a frequency divider 11 output. The outputs of gates NO and 22 are connected to the write enable input of shift register 80, and the parallel data outputs of shift register 80 are connected to the inputs of logical NO or gate 21. The clock inputs of the shift register 80 and the synchronization stage 17, as well as the input ^{35 of} the frequency divider 11, are connected to the output of a clock generator 16. The output of the frequency divider 11 is connected to the clock input of the counter 12. The shift register 80 is 83 83. . . 8P Parallel Input Connected to the ⁴⁰ outlets of 9 reference stages. The 80 step guard health 82, 8 _P 11. . . Its 8 _q parallel inputs70 are connected to the corresponding parallel outputs of a storage device whose 7 _X. . . Parallel ingress _f 7 10 analog multiplexer ⁴⁵ connected together in parallel ve zérlőbemeneteivel counter 12 are connected to the parallel outputs. The parallel input 8a of the shift register 80 is coupled ^{50 to the} output of the pressure transducer D1 and the parallel input 8r to the output of the moisture transducer D2. The parallel input 8c of the shift register 80 is connected to the output of the cover opening switch D3.

- 6 ₂ n regenerators are the outputs ⁵⁵ connected to the parallel inputs of the 10 analógmultiplexer whose output is connected to "greater than 10" * "error magnitude sensor 13 units and, jiagyobb than 10" ³ "error magnitude detector unit 14 inputs food, while the output of the unit 14 to 70 is connected to the highest level ⁶⁰ parallel inputs of the order ⁶⁰ . The output of the unit "sensing error greater than 10 ~ ⁶ " is connected to the write enable input of the container 70. One output of the shift register 80 is connected to transmitter input ⁶⁵ 20, the output of which is auxiliary 1

Through 191,856 pairs, it is connected to the next automatic regeneration point.

In the circuit diagram of Fig. 2, the exemplary apparatus has a stroke generator which is located in quartz generator 25 at main station 2 and communicates with step register 80, synchronization stage 17 and frequency divider 11 via transmitters 23 and receivers 26. The transmitters 23 and the receivers 26 of the following automatic regeneration points 5 are connected in series through 24 pairs of wires.

The operation of the apparatus shown in Figure 1 is as follows: The pair 1 transmits information from the automatic regeneration points 5 to the main station 2. All 6i connected to each automatic regeneration point 5. . . 6 The output signals of the _2n regenerator are fed to the 10 analog multiplexer inputs. The clock pulses from the frequency divider 11 control the counter 12, which controls the analog multiplexer 10 by specific code combinations, and at its output periodic signals are output to the analog multiplexer input 10. 10 analógmultiplexer signal appearing at the output is the "greater than 10" size error detection unit 13, as well as "greater than 10" ³ "size error detection unit 14 input. After receiving the signal from the output of the unit 13, the code combination generated by the counter 12, characterized by a defective or defective regenerator 6, is written to the memory 70 ₂ . . . 7f through parallel inlets. The output signal of the unit 14, which detects an error size greater than 10 ^-3, is stored in the storage 70 as its highest local bit. From the output of the stroke generator 16, the signal is transmitted to the stroke of the shift register 80 and the synchronization stage 17.

The signal of the previous automatic regeneration point 5, transmitted by the pair of wires 1, is transmitted to the receiver 18, from there to the synchronization stage 17 and synchronized with the local clock frequency of the clock generator 16. From the output of the synchronization stage 17, the signal is transmitted to the shift input of the shift register 80, from which its highest order, that is, its most localized compartment, is transmitted to the transmitter 20 so that it passes through the pair 1 to the next automatic regeneration point. All the slots of the shift register 80 are connected to the inputs of the multi-input gate NO or 21, the output of which is fed to the gate NO 22 in the event of a lack of through information. The other input of the gates NO and 22 receives the frequency divider signal 11. The output signal of gates NO and 22 allows entry of shift register 80. A logical "1" is applied to the parallel input 8i of the shift register 80, which indicates the presence of signal information passing through the main station 2. The shift register 80 ₃ . . . Parallel input 8 _P provides information specific to the automatic regeneration point 5 provided by reference stage 9. The shift register 80 is ₂ and. . . ^ parallel input food 80 stored information will be, while the 8 _a, 8 b, 8q parallel input forward to the prevailing air pressure warning automatic five regenerating point Di pressure transmitter, the existing therein moisture indicator _D2 humidity transducer and the opening of an automatic five regenerating point cover signal _D3 lid opening switch information then these signals are transmitted through transmitter 20 to the next automatic regeneration point 5. From the last auto regeneration point 5, information is received through receiver 18 of main station 2 to a prioritizing unit 3 which processes the information and transmits it to dynamic indicator 4 which displays the number of each regenerator 6 of all automatic regeneration points 5 between the two main stations 2 _; having an error size greater than 10 ~ ³ '

IE- shows the number of each regenerator 6 and each automatic regeneration point 5 at which there is a change in air pressure, humidity, or in which the box lid has been opened.

In this way, the operator is aware at any moment of the state of each regenerator 6 and of each automatic regeneration point 5 associated with the line. The check is performed automatically without interrupting the simultaneous transmission to all 6 regenerators of the automatic regene25 dots.

The frequency of the apparatus illustrated schematically in FIG. 23 taxes. From the output of the next automatic regeneration point 5 through the pair of wires 24, the beat frequency is transmitted to the subsequent automatic regeneration point 5.

Claims (4)

A method for remotely controlling regenerator units used in automatic multi-channel, number-compression data transmission systems, using localized code combinations to determine the priority of information transmitted at the host and dynamic indication, characterized in that it transmits multiple, independently, continuously from one host (2) direction is checked at m automatic regeneration points (5), whereby at the main station (2) the number of ⁵⁵ regenerative regeneration points (5) containing unreliable or defective regenerators (6) and displaying the contents of the regenerator (6) ), the information is scanned for error size, and when the specified error threshold is exceeded, the information is stored, and incomplete priority information passing from an additional automatic regeneration horse (5) is and with the regenerator (6) address information (2) is transmitted to the main station, which as priorities (5) passing through each automatic regeneration stage regeneration refluxed at ^65. -41,191 Apparatus for implementing the method of claim 1, comprising an additional pair of auto-regeneration points and a main station having a priority determining unit for transmitted information, wherein the output of the priority unit is coupled to a dynamic indicator input, characterized by a step input of a step register (80). connected to an output of a synchronization stage (17), the first input of which is connected to the output (18) of a receiving circuit (19), the input of the receiver (18) is connected to an additional pair (1) of the previous automatic regeneration point (5); Output (21) is connected to the first input of logic NON-AND gate (22), second latter input to frequency divider (11) output and output of logical NON-AND gate (22) to the write enable input of shift register (80), parallel to shift register (80) data outputs of the logical NO- OR are connected to the inputs (21) of the gate and connected to the clock input of the shift register, the second input of the synchronization stage (17) and the frequency divider (11) to the output of the clock generator (16) and the output of frequency divider (11) (80) are connected to the parallel outputs of the reference stage (9) with parallel input (8 _X , 8 _{3 to} 8 _p ), and the shift register (80) is stored with additional parallel input (8 ₂ , 8 _{P + 1} · 8 _q ). ) with parallel outputs 856 2 interconnected with parallel inputs (7 ₂ ,. 7 _f ) connected to the parallel outputs of the analog multiplexer (10) to the parallel outputs of the counter (12) and the outputs of the regenerators (6 _X ... 6 _2n ) to the analog multiplexer (10) are connected to the parallel inputs, the output of which is connected to "greater than 10 ^-6" error magnitude detecting unit (13) as well as "greater than 10 ^-3" error magnitude ér10 detector have unit (14) to the input of and the unit output (14) of the container (7) is connected to the parallel localization of the highest local value data compartment (Ί _ι ), while the output of the unit (13) is connected to the enable input 15 of the storage (70) and the output of the shift register (§0) to the input (20) The output of (20) is connected to the receiver (18) of the main station (2) through the last pair of wires (1) for the last automatic regeneration point (5) in the queue. 20 Device according to Claim 2, characterized in that each automatic regeneration point (5) is assigned a separate cycle generator (16). Apparatus according to claim 2 therein 25 characterized in that the clock generator (161) is a quartz generator (25) located on the main station (2) and with a step register (80), a synchronization stage (17) and a frequency divider (11) via transmitter (23) and receiver (26). The transducers (23) and receivers (26) of all automatic regeneration points (5) are connected in series through an additional pair (24) of wires.