DE3322681A1 - Method and device for remotely controlling regenerative repeaters in a group of unmanned multi-channel digital pulse-code-modulation systems - 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

METHOD AND DEVICE FOR REMOTE CONTROL OF REGENERA

GATES IN A GROUP OF UNUSUAL MULTI-CHANNEL DIGITAL PULSE CODE MODULATION SYSTEMS The invention relates to a method and a device for remote control of regenerators in a group of unattended, i.e. automatic working, multi-channel digital PCM (pulse code modulation) systems that are used in the Communication engineering and in systems for data transmission are known is a method for remote control and localization of damaged regenerators in unattended regeneration points, where from the end station A in the direction to the other end station B a localizing digit signal is transmitted that represents a periodic series of impulses. The repetition frequency of its envelope is different for each individual unattended regeneration point. When a certain regenerator in direction A-B is not damaged, it registers this transmitted signal and through a filter in the unattended regeneration point a relay switched on. After the interruption of the localizing signal remains the relay is actuated and via its second contact and an adapted quadrupole if the signal is fed to the input of another regenerator in direction B-A, from the output of which this signal returns to the control station. Its presence or absence allows an assessment of the status of the checked bilateral Regenerators. After the check, the remote feed is activated for a moment interrupted and the relay opens its contacts (Bitschew G. - Multichannel numeric systems, 1980).

There is also a method for remote control and localization of damaged ones unattended regeneration points or relay stations and the ones provided in them Regenerators known that with the help of an additional pair of conductors in the connecting cable is realized. This procedure usually allows several in one direction (up to six) regenerators can be controlled in one unattended point. For testing a given unattended regeneration point with several End station A transmits a localizing signal to disposable regenerators. The regeneration point has a band filter that is common to all disposable regenerators on.

The outputs of the individual regenerators are to the input of this filter out and separated by high resistance. The localization signal points here a low-frequency component and plays the role of an evaluation signal. For this purpose a line code with a special algorithm is used, whereby the The localizing signal is formed by a group of three pulses (triad). The periodicity with which the triads are introduced in the localizing signal, determines the frequency necessary for the control of the condition and the localization of the respective regeneration point is used. The density of the triads will both from their number and from the numerical errors in the path and in the regenerator hiked. The level of its DC component or the amplitude level of the signal with a frequency fH brings the information about the condition of the regenerators to the main terminal A (see Bitschew G. - Nehrkanalige Digit Systems, 1980, pages 161 to 164).

The main disadvantage of both methods is the need to that the transmission is interrupted during the control. For groups with multi-channel digital PCM systems, the number of controls is very large and corresponds to the number of line routes multiplied by the number of regenerators. In addition, the regenerators cannot be tested for the error coefficient.

A device for remote control of regenerators is also known without interrupting the transmission, the transmission point A is a series connection from a block for the delivery of zero intervals, an AND gate, its second Input is connected to a generator for generating the test message, and a Contains union block whose second input is connected to the input of the block for the delivery of zero intervals is connected. For each regeneration point are a series connection of an additional block for the delivery of the test message, an analyzer, a memory, an encoder for error detection, a summator and an additional block for merging the digit signal from the output the regenerator and the test message provided. The second exit of the additional Blocks for the delivery of the test message is with the inputs of the regenerator and connected to the analyzer. To the common inputs of the analyzer and the additional A signal is sent from the output of the regenerator to the union block (s.

SU-PS 777 842).

The main disadvantage of this device is that it is only for the remote monitoring of a disposable regenerator from each regeneration point is used. In addition, in order to test n line routes, 2 "n tests must be carried out, because the number of single regenerators is twice as large as the number of paths.

The object of the invention is to provide a method and a device for automatic remote control of Regenerators in a group of multi-channel digital PCT systems without interrupting the transmission, which enables simultaneous control of all regenerators in the way.

This task is accomplished through a method of remotely controlling regenerators solved in a group of unattended multi-channel PCM systems, with the localizing Code combinations are used for processing in the main end station for determining the priority of the transmitted information and the dynamic indication can be entered. From the main terminus will be continuous, simultaneous and automatic n multi-channel line routes in both transmission directions with m unattended Regeneration points controlled, with the number one in the main terminal station any unstable or damaged regenerator and the number of the corresponding one Regeneration point in which this regenerator is located. The information from each regenerator is first given as to the degree of failure checked and, if a specified degree of error is exceeded, for a faulty one or damaged regenerator it is saved and afterwards in the absence of one priority message passing through from another regeneration point with the address information of the faulty or damaged regenerator of the Main end station, going through each regeneration point is regenerated.

The device according to the invention for carrying out the method contains an additional pair of conductors between the unattended regeneration points and the main end station with a block for determining the priority of the entered Information, the output of which is connected to the input of a dynamic indicator is. The successor output of a shift register is with the output connected to a synchronizer, the first input of which is via a decision block, who decides whether the output information of the recipient is an interference or is a useful signal, is connected to the output of a receiver whose input is connected to the additional pair of conductors of the previous regeneration point. The output of a multi-input NOR gate is with the first Input of a NAND gate connected, the second input of which is connected to the output of a Frequency divider is connected. The output of the NAND gate is with the reset input of the shift register, its parallel order outputs with the inputs of the multi-input NOR gate. The clock input of the shift register, the second input of the synchronizer and the input of the Frequency dividers are connected to the output of the clock pulse generator. The exit of the frequency divider is connected to the clock input of a counter. The first, the third to the p-th parallel input of the shift register are with the parallel ones Outputs of a constant value memory in which the number of the regeneration point corresponding code combination is written. The second, the (p + 1) -th until the qth parallel input of the shift register are with the corresponding parallel outputs of a register whose parallel inputs are common with the parallel control inputs of an analog multiplexer to the parallel outputs of the meter are connected.

The outputs of the Regeneratoi-en are with the parallel inputs of the analog multiplexer, whose output is connected to the inputs of a block for determining the error coefficient greater than 10-6 "and one Blocks for the determination of the error coefficient "greater than 10 3" is connected to the Output is connected to the highest order input of the register. The exit of the block for determining the error coefficient is greater than 10 6 "with the reset input of the register. The output of the shift register is connected to the input of a Connected to the transmitter, its output with the additional pair of conductors on the following unattended Regeneration point is connected.

The invention is based on the embodiment shown in the drawings explained in more detail. 1 shows a block diagram of a device for remote control of regenerators in a group of unattended multi-channel PCM systems and FIG. 2 shows a partial block diagram when using a clock generator and individual Sender and receiver.

The device contains an additional pair of conductors 1 between the unattended, i.e. automatically, working regeneration points 5 and the main end station 2, in which a block 3 for determining the priority of the information entered is connected to the input of a dynamic indicator 4. The next entrance of a Shift register 8 is connected to the output of a synchronizer 17, whose first input via a decision block 19, which deals with the classification of the output signal of the receiver 18 decides as useful or interference signal, with the output of a receiver 18 is connected, the input of which is connected to the additional pair of conductors 1 of the previous one unattended regeneration point 5 is connected. The outcome of one with several Inputs provided NOR gate 21 is the first input of a NAND gate 22 connected, while its second input to the output of a frequency divider 11 is connected. The outcome of the NAND gate 22 is with the reset input of the shift register 8, whose parallel order outputs with the inputs of the NOR gate 21 are connected. The clock input of the shift register 8, the second The input of the synchronizer 17 and the input of the frequency divider 11 are connected to the Output of a clock pulse generator 16 connected. The output of the frequency divider 11 is connected to the clock input of a counter 12. The parallel inputs 81 83 to 8 of the sliding window 8 are with p the parallel outputs of a constant value memory 9, the code combination corresponding to the number of the respective regeneration point contains, connected. The parallel inputs 82, 8p + 1 to 8 of the shift register q 8 are connected to corresponding parallel outputs of a register 7, whose parallel inputs together with the parallel control inputs of an analog multiplexer 10 are connected to parallel outputs of the counter 12.

The parallel input A of the shift register 8 is connected to the output of a pressure transducer D1, while the parallel input B of the shift register 8 is connected to the output of a moisture transmitter D2. The parallel entrance C of the shift register 8 is connected to the output of a transmitter for opening the cover D3 connected.

The outputs of the regenerators 61 to 62n are with the parallel ones Inputs of the analog multiplexer 10 connected, the output of which is connected to the inputs a block 13 for determining the error coefficient "greater than 10 6" and one Block 14 is connected to determine the error coefficient greater than 10 3 ", the output of which is connected to the input of the highest order i1 of the register 7 is. The output of block 13 to determine the error coefficient is greater than 10 D 1l is connected to the reset input of register 7. The output of the shift register 8 is connected to the input of a transmitter 20, its outcome with the additional pair of conductors 1 at the next unattended regeneration point 5 or is connected to the main terminal 2.

The device of FIG. 2 uses a clock generator in the Main end station 2 arranged quartz generator 25, which is connected to the shift register 8, the synchronizer 17 and the frequency divider 11 via a transmitter 23 and a receiver 26 is connected. The transmitters 23 and the receivers 26 of the following regeneration points 5 are connected in series by a pair of conductors 24.

The device of Fig. 1 has the following mode of operation: The pair of conductors 1 transmits the information from all unattended regeneration points 5 to Main end station 2. The signals from the outputs of all regenerators 61 to 62n in each regeneration point 5 are fed to the inputs of the multiplexer 10. The clock pulses received from the clock frequency divider 11 clock the counter 12, the controls the multiplexer 10 by certain code combinations; at its exit Signals that are fed to the inputs of the multiplexer 10 appear periodically.

The signal at the output of the multiplexer 10 is the block 13 for determination of the error coefficient greater than 10 6 "and the block 14 for determining the Error coefficients "greater than 10 3" are supplied. When receiving a signal from the outputs of block 13 will record the code combination for the number of the faulty or damaged regenerator 6 from the counter 12 in the orders 72 to 7f of the register 7 carried out. The signal from the output of block 14 to Determining the error coefficient greater than 10 "11 is used as the most significant bit recorded in register 7. A signal goes from the output of the clock generator 16 Clock input of the shift register sters 8 and the synchronizer 17 a. After a signal from the previous regeneration point 5 through the conductor pair 1 has been transmitted and accepted by the receiver 18, it becomes the synchronizer 17 and synchronized with the local clock frequency from the clock pulse generator 16. From the output of the synchronizer 17, the signal is the next input of the register 8 supplied, of the highest order of which the information is input to the transmitter 20 so that it is then transmitted via the ladder 1 to the following regeneration point 5 will. All orders of the register 8 are connected to the inputs of the NOR gate 21, a signal of the logic circuit from its output in the absence of continuous information 22 is transmitted. The other input of the logic circuit 22 is a signal from Frequency divider 11 is supplied. The signal from the output of the logic circuit 22 allows the recording of information in register 8.

In order 81 a one "is recorded, indicating the presence signaled signal information that is supplied to the main terminal 2 via the route will. The information for the number of the regeneration point is in orders 83 to 8 5 recorded, which is transmitted from the constant value memory 9. In the orders 82 and 8 to 8q the information from register 7 is recorded p + 1, while in the orders A, B, C the information from air pressure transducers D1 in the regeneration point 5, from moisture sensors D2 and lid position sensors D3 of the regeneration point 5 is recorded. Through the transmitter 20, the information is sent to the next regeneration point 5 supplied. From the last regeneration point 5, the information about the recipient 18 of the main terminal 2 to block 3 for determining the priority of the incoming Information transmitted, processed by it and the dynamic indicator 4 which displays the number of each regenerator 6 of all regeneration ration points between the two end stations with an error coefficient greater than 10 3 "(1 or "greater than and any regeneration point 5 showing a change in air pressure, Has the presence of moisture or opening the lid, realized.

In this way, the surgeon knows the condition at all times of each regenerator 6 and each regeneration point 5 in the way. The control is automatic without interrupting the transmission for all regenerators at the same time carried out in the regeneration points in the path.

The device of FIG. 2 uses the clock frequency of the crystal generator 25, which is fed to the clock frequency receiver 26 through the conductor pair 24. from its output is the clock frequency to the input of the synchronizer 17, the clock input of the shift register 8, the frequency divider 11 and the clock frequency transmitter 23 are supplied. From the output of the clock frequency transmitter 23, the clock frequency is transmitted via the pair of conductors .24 fed to the following regeneration point 5.

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Claims (1)

PROCEDURE AND EQUIPMENT FOR REMOTE CONTROL OF REGENERA DOORS IN A GROUP OF UNUSED MULTI-CHANNEL DIGITAL PULSE CODE MODULATION SYSTEMS A method for the remote control of regenerators in a group of unattended, i.e. automatically working, multi-channel pulse code modulation systems, at. localizing code combinations are used which are used for processing in the main end station for determining the priority of the transmitted information and can be entered for the dynamic indication e t that from the main terminal (2) continuously, simultaneously and automatically an n-number of multi-channel line paths in both transmission directions with one m-number of unattended regeneration points (5) can be checked, with the Main end station (2) the number of each unstable or damaged c-n Regenerator (6) and the number of the corresponding unattended regeneration point (5), in which this regenerator (6) is located, is displayed, with the information from each regenerator (6) first on the degree of failure is checked, and when a predetermined degree of error is exceeded for a faulty one or damaged regenerator (6) is stored, after which in the absence of a continuous Priority information from another unattended regeneration point (5) this Information together with the address information of the faulty or damaged Regenerators (6) of the main end station (2) is transmitted, whereby it is continuous is regenerated by each unattended regeneration point (5). Device for performing the method according to claim 1, the an additional pair of conductors between the unattended regeneration points and the main end station with a block for determining the priority of the transmitted Information whose output is connected to the input of a dynamic indicator is, contains, thereby g e -k e.n n z e i c h n e t that the following input of a shift register (8) is connected to the output of a synchronizer (17), the first input of which connected to the output of a receiver (18) via a decision block (19) is whose input with the additional pair of conductors (1) with the previous unattended Regeneration point (5) is connected, the output being one with several inputs provided NOR gate (21) is connected to the first input of a NAND gate (22) is, while the second input of the NAND gate (22) to the output of a frequency divider (11) is connected, the output of the NAND gate (22) with the reset input of the shift register (8) is connected, the parallel order outputs with the The inputs of the multi-input NOR gate (21) are connected, while the clock input of the shift register (8), the second input of the synchronizer (17) and the input of the frequency divider (11) at the output of the clock pulse generator (16) are connected, the output of the frequency divider (11) with the clock input of the counter t12) is connected, while the first, the third to the p-th parallel input (81, 83 to 8 B of the shift register (8) with the parallep len outputs of a constant value memory (9), which contains the number of the respective The corresponding code combination contains the regeneration point, the second, the (p + 1) -th to the q-th parallel inputs (82, 8 to 8q) of the shift register (8) with the corresponding parallel outputs of the register (7) off its parallel Inputs together with the parallel control inputs of an analog multiplexer (10) are connected to the parallel outputs of the counter (12), the outputs of the regenerators (61 to 62n) with the parallel inputs of the analog multiplexer (10) are connected, the output of which is connected to the inputs of block (13) for the determination the error coefficient "greater than 10 6 91 and the block (14) for the determination of the error coefficient "greater than 10 3", the output of which is connected to the The highest order input (71) of the register (7) is connected, while the output of the block (13) for the determination of the error coefficient 11 greater than 10 6 with the reset input of the register (7) is connected, the output of the shift register (8) is connected to the input of the transmitter t20), the output of which is connected to the additional Conductor pair (1) connected to the following unattended regeneration point (5) is. 3. Device according to claim 2, characterized in that g e k e n n -z e i c h n e t that the clock frequency generator (16) for each unattended regeneration point (5) exists individually. 4. Device according to claim 2, characterized g e k e n n -z e i c h n e t that the clock frequency generator is a crystal generator (25), which is located in the main terminal (2) and with the ski register (8) the synchronizer 5 (17) and the frequency divider (11) connected by transmitter (23) and receiver (26) is, the transmitter (23) and the receiver (26) of all unattended regeneration points (5) are connected in series by the conductor pair (24).