RU2194369C2 - Hardware set for automatic telephone exchange of emergency and fire alarm system - Google Patents

Abstract

FIELD: centralized property and fire control over dispersed objects via telephone communication lines. SUBSTANCE: technical result of invention lies in insertion of re-start unit into active multiplexers and active concentrators of automatic telephone exchange which ensures restoration of operational information from energy-independent storage or over communication lines with centralized control desk. This approach increases operational reliability of emergency and fire alarm system. Possibility of supernumerary operation of active multiplexers and active concentrator is excluded thanks to constant control over correct sequence of implementation of programs in active multiplexers and active concentrators via re-start unit. Same hardware set provides for reduced time for restoration of serviceability of units. EFFECT: reduced time for restoration of serviceability of hardware units. 3 dwg

Description

 The invention relates to security and fire alarms and can be used in devices of centralized property and fire protection of dispersed objects through busy telephone lines.

 A known set of PBX hardware alarm system "Cyclone" (TU 25 - 08.430-80, TU 25-08.431-80, TU25-08.432-80 Security Technique 1/94), containing a group of concentrators connected in parallel with the corresponding dedicated communication line with the remote control centralized monitoring (CMS), with all the concentrators in the group additionally interconnected in parallel with the control bus.

 The insufficient reliability of the specified set of PBX equipment of the security and fire alarm systems is associated with a large number of false alarms due to a decrease in the level of the continuous frequency signal transmitted from the guarded object when the telephone line parameters deteriorate.

 A known set of equipment for automatic telephone exchanges of the Comet - K security and fire alarm system (II1.220.003.TU Security Technique 1/94), consisting of a linear block with a group of high-pass filters and broadcast devices.

 The disadvantages of this scheme are the small number of protected objects, low functional reliability due to the lack of redundancy of critical units, and insufficient emissivity.

 The closest in technical essence to the proposed one is a set of automatic telephone exchange equipment for a security alarm system (RF Patent 2110094, consisting of a multiplexer containing a restart direction unit and two active multiplexers, each of which contains a switched power supply, a local area network controller, a microcomputer, three communication units, input device, download confirmation indicator, restart block and groups of active hubs, each of which contains a switched power supply, local area network controller, microcomputer, unit with ligature, which contains a block of serial input / output controllers, a block of transceivers and a block of high-pass filters.

 A well-known equipment set of automatic telephone exchanges of a fire alarm system works as follows.

 In the initial state, after turning on the power of any of the central monitoring stations (CMS), the initial menu for operation is displayed on the display of each workplace on duty (RMD).

 After turning on the power on both active multiplexers of the set of PBX equipment and successfully conducted internal diagnostics, they switch to a survey on the availability of the storage medium in their input device. The active multiplexer (AM) that has detected the storage medium in its input device considers itself to be the leading one, reads information from the storage medium into its RAM. If the reading was successful, then AM turns on its download confirmation indicator, which visually designates it as the leader. After that, he sequentially enters into communication with the file control device (FUU) of each monitoring station, receives from them the unique addresses of subscribers of the PBX local area network, and through the latter transfers the full copy of his RAM to the second AM, which identified itself as a slave due to the lack of information carrier in his input device and went into hot standby mode. From this moment, the changes made by the program in the RAM of the master AM are automatically made through the local exchange of PBXs in the slave AM, and the difference between them is that active AM starts a cyclic poll and receives information messages from active hubs through the local network of the PBX (AK ), a AM hot spare synchronously receives information. If the master AM stops polling subscribers, then the slave AM through the restart direction block makes a forced restart of the master AM, putting it in slave mode, and it switches to master mode, copies its RAM to the second AM and starts polling network subscribers at the addresses that were previously transferred to him from the lead AM. If at the time of repair of the slave AM, a data failure occurred on the master AM, then the situation is solved as follows. At each monitoring station related to a failed set of PBX equipment, through the input / output device, all the necessary information for this set of PBX equipment is displayed on an information carrier. Information carriers from each monitoring station should be delivered to the appropriate set of automatic telephone exchange equipment from the group, which are then sequentially inserted into the input device (most often the input device from the magnetic disk) of one of the included AM failed set of automatic telephone exchange equipment, which reads it into its RAM and determines behaving. The presenter AM analyzes the results of the test diagnostics transmitted from the group of active concentrators. If they are successful, then through the local area network of the PBX, it loads into the AK information necessary for its normal operation with the connected object blocks. If the results of the test diagnostics are unsatisfactory, then through the restart direction block, the AM connected to it sends a forced restart signal to the failed AK, and reports what happened to the monitoring station, after which the above cycle repeats. If the AK failed to start working after several restarts, a message is sent to the standby monitoring station about the failure of this AK and AM starts to call it much less frequently than to the other subscribers of the PBX local area network. Similarly to the above, a restart is made of previously operating AK and AM hot reserves, in which a failure was detected or communication with them was lost. Both file management devices (FUU) cyclically polls the status of the AMs connected to them. The information received from AM is copied to the FUU of the hot reserve and, if necessary, is displayed on the screens of the monitors of both FUU.

The disadvantage of this system is the low reliability due to:
the use of portable information carriers and rotating parts in devices for inputting this information from a medium into AM;
the lack of control of the correct sequence of execution of program algorithms in AM and AK, and since in the analogue the monitoring of AM and AK operability is carried out only by the presence of communication with the latter in the local network, then if there are errors in programs or malfunctions in the electrical parts of AM and AK leading AM will not notice a looping of the work of the slave AM or AK programs in areas that provide local network communications, as well as the termination of important or basic functions in the operation of AM or AK - reception and transmission to the monitoring station are alarming Posts with objects of protection; in addition, there may be a loss of operational information in AK and AM received from object blocks at the time of restart of the AK or slave AM, which is forcibly initiated from the master AM;
lack of control over the availability of primary and backup power in AM and AK.

 The aim of the invention is to increase the reliability of the set of PBX equipment.

 This goal is achieved by the fact that the set of PBX equipment consists of two active multiplexers, each of which contains a switched power supply, a local area network controller, a microcomputer, three communication units and groups of active hubs, each of which contains a switched power supply, a local area network controller , a microcomputer, a communication unit that contains a block of serial input / output controllers, a block of transceivers, a block of high-pass filters and a restart block, each active hub contains a block of rest the one whose inputs are connected to the outputs of the controlled power supply, the output with the input of the microcomputer, and the group of inputs / outputs - with the corresponding group of inputs / outputs of the microcomputer, and the inputs of the restart unit in each active multiplexer are connected to the outputs of the corresponding controlled power supply, and the group of inputs / outputs - with the corresponding group of inputs / outputs of the microcomputer.

 In addition, the restart unit is made in the form of a memory address decoder (memory), read-only memory (ROM), non-volatile memory (ENZU), external device address (WM) decoder, element I, control register, switch block, state register, node ENZU battery control, binary counter, reset pulse blocker, reset pulse shaper, signal conditioning unit, indication unit, unauthorized access sensor, pulse generator, buffer element, the first group of outputs connected to a WU address decoder, the first output of which is connected to the first input of the binary counter, the second input of which is connected to the input of the reset pulse blocker, the third input is connected to the output of the pulse generator, the output of the binary counter is connected to the sixth input of the status register and the input of the reset pulse generator, output which is connected to the input of the buffer element, the second group of outputs of which is connected to the address decoder of the memory, the first output of which is connected to the first input of the ROM, the group of outputs of which is connected to the second group of inputs / outputs of the buffer element, the second output of the memory address decoder is connected to the first input of the AND element, the output of which is connected to the input of the ENZU, the group of inputs / outputs of which is connected to the second group of inputs / outputs of the buffer element, the output of the ENZU is connected to the first input of the control unit ENZU batteries, the output of which is connected to the first input of the status register, and the second input is connected to the first output of the control register, the second output of which is connected to the second input of the And element, the third output is connected to the second input of the ROM, input d is connected to the second output of the WU address decoder, the third output of which is connected to the second input of the status register, the group of inputs of which is connected to the group of outputs of the switch block, and the first group of outputs of which is connected to the second group of inputs / outputs of the buffer element, the third input to the output of the sensor unauthorized access, the second group of outputs is connected to the group of inputs of the display unit, the group of outputs of which is connected to external and internal indicators, the first and second inputs of which are connected respectively venno the first and second signal generating unit outputs, as the third and fourth outputs are connected respectively with the fourth and fifth inputs of the status register.

The interaction of individual blocks and nodes of the proposed system is presented schematically:
figure 1 - functional diagram of the multiplexer;
figure 2 is a functional diagram of the hub;
figure 3 is a functional diagram of a restart block.

 The multiplexer (figure 1) contains active multiplexers 1 (AM), each of which contains a local area network controller 2, a switched power supply 3, a restart unit 4, a microcomputer 5, communication units 6.

 The hub (Fig. 2) contains a group of active hubs 7, each of which consists of a switched power supply unit 8, a local area network controller 9, a microcomputer 10, a communication unit 11, which contains a block of serial input / output controllers 12, a block of transceivers 13, high-pass filter unit 14 and restart unit 15.

 The restart unit (Fig. 3) contains the address decoder of the memory 16, ROM 17, non-volatile memory (ENZU) 18, the address decoder of the memory 19, element I 20, control register 21, status register 22, switch block 23, signal generation block 24, node battery monitoring ENZU 25, binary counter 26, reset pulse blocker 27, reset pulse shaper 28, pulse generator 29, display unit 30, tamper sensor 31, and buffer element 32.

 The device operates as follows.

 In the initial state, after turning on the power of any monitoring station, the displays for the monitoring station and each workstation of the console display the initial menu for the standby mode, and the monitoring stations switch to the cyclic mode of polling the current state of the corresponding AMs via the corresponding communication lines between the monitoring station and AM.

 After turning on the power, AM 1 and AK 7 are supplied with voltage and MEM 5 and 10 of each AM and AK make the necessary programming and diagnostics of their internal nodes, and the reset pulse blocker 27 of the restart unit 4 and 15 in each AM 1 and AK 7 generates a signal in binary counter 26, which blocks the signal from the pulse generator 29 to the counter 26 and prevents the counter 26 from generating a restart signal through the reset pulse generator 28 and the buffer element 32 to the corresponding MEM 5 and 10 for the time after which the MEM 5 and 10 of each AM 1 and AK 7 will perform the necessary preparatory operations and proceed with the implementation of the main program.

 After successfully conducting microcomputers 5 and 10 of each AM 1 and AK 7 internal diagnostics of their nodes, microcomputers 5 and 10 through the buffer element 32, the decoder WU 19 and the status register 22 reads the contents of its own number from the switch block 23, then writes in accordance with its own number in control register 21 through the second group of inputs / outputs of the buffer element 32, the constant of the offset address of the ROM and then through the address decoder of the memory 16 selects a ROM that contains a program of operation, respectively, AM or AK and through the buffer element Ent 32 reads from ROM 17 a program in RAM MEWM 5 and 10, and after checking its reliability with a control signature, it starts to execute this program. At control points of the program, reset commands are installed through the decoder WU 19 of the binary counter 26. If the program is executed correctly, the binary counter 26 does not have time to generate a signal to form a restart in MEVM 5 and 10 and other electrical circuits of the corresponding AM and AK. Through the decoder VU 19 and the control register 22 to the ENZU 18 briefly connects the battery monitoring unit ENZU 25, the state of which through the status register 22 is read in MEM 5 and 10, respectively. Then, according to the program, the MEWM again reads through the status register 22 the contents of the NSD sensor 31, the signals of the presence of the main and backup voltage from the signal conditioning unit 24 on the AM and PC, respectively. The signals for indicating the presence of the main and backup voltage from the signal conditioning unit 24 are received through the block indication 30 on the outer part of the housing, respectively, AM and AK for visual inspection. Through the state register 22 MEWM 5 and 10 reads the sign from the binary counter 26, by which it can determine to execute the corresponding program whether it is in the state after restart or in the state after turning on the supply voltage. If the corresponding AM or AK determines that it is in a state after turning on the supply voltage, then through the VU 19 decoder to the control register 21, a sign of permission to access the write cycle in the ENZU 18 is set, and information is allowed to be recorded through the memory decoder 16 and the element And 20 in the ENZU 18 with MEWM 5 and 10 through the buffer element 32. Software testing of the ENZU 18 is performed, after which the ENZU 18 is cleared. All the test results and the state register 22 after analysis are transmitted to the appropriate FUU of the corresponding monitoring station. If the test results and the status register status are successful, then the MEW of the corresponding AM or AK through the status register 22 turns on the corresponding indication. AK through the local area network of the PBX requests the leading AM about loading AK information necessary for operational work. The AM leader checks the integrity of his ENZU, and if the information for this AK is reliable, it transmits it to the requesting AK, and AK, having accepted the information, puts it in its RAM and duplicates it with control in the ENZU, only after that it transmits confirmation of receipt of information to AM . If the information in AM turned out to be unreliable, then the master AM requests information for the AK in the slave AM through the local area network controller 2, having received reliable information for the AK, the master AM writes it to its RAM and reserves it with control in the ENZU, after which it confirms to the slave AM about the reliable reception of information, overloads the received information in the requesting AK. If the information for this AK was not reliable in the slave AM, the master AM requests information for this AK from the corresponding monitoring station. Having received the necessary information, the master AM writes it to his RAM and ENZU, then transfers the information to the slave AM, which writes it to his RAM and ENZU, after which the master AM downloads this information to the requesting AK, where it is backed up to his ENZU, and placed in RAM AK for operational work. AK, in accordance with the information received, polls the corresponding subscriber sets, transmits the necessary information to them and receives the answers that it writes to RAM and reserves it in its ENZU. Then the AK transmits it after analysis upon request to the master AM, which places the information received from the AK in its RAM and ENZU, and duplicates it in the slave AM and then sends this information to the corresponding monitoring station.

 If during the operation of the corresponding AM or AK a deviation occurred in the algorithm for executing the corresponding program or its freezing, then the MEM 5 and 10 AM or AK will not reset the binary counter 26 in the restart unit 4 and 15 in time and it will be reset via the reset pulse generator 28 and the buffer element 32 will send a reset signal to this MEM and the electrical circuits of this AM or AK. The corresponding AM or AK performs the necessary programming and diagnostics of its internal nodes, and the reset pulse blocker 27 of the restart unit 4 and 15 in each AM and AK generates a signal in binary counter 26, which blocks the signal from pulse generator 29 to binary counter 26 and prohibits it generating a restart signal through the reset pulse shaper 28 and the buffer element 32 to the corresponding MEM 5 and 10 for the time after which the MEM 5 and 10 of each AM and AK perform the necessary preparatory operations and begin olneniyu main program. After successfully conducting the MEWM of each AM and AK internal diagnostics of its nodes, the MEWM through the buffer element 32, the address decoder WU 19, through the status register 22 reads the contents of its own number from the switch block 23. Then, in accordance with its own number, writes it to the control register 21 through the second group inputs / outputs of the buffer element 32 constant offset address of the ROM, and then through the address decoder memory 16 selects a ROM that contains a functioning program, respectively, AM or AK. Then, through the buffer element 32, it reads from the ROM 17 the program in the RAM of the computer and, after checking its reliability against the control signature, starts to execute this program. In the control points of the program, restart enable commands are installed. Through the address decoder WU 19 and the control register 21 to the ENZU 18 briefly connects the battery monitoring unit ENZU 25, the state of which is read through the status register 22 in the MEWM. Then, according to the program, MEWM again reads through the status register 22, the contents of the NSD sensor 31 and the presence on the AM and AK of the main and backup supply voltage from the signal conditioning unit 24. Signals to indicate the presence of the main and backup supply voltage from the signal conditioning unit 24 are received through the display unit 30 on the indicators respectively AM and AK for visual control. Through the state register 22, the MECM reads the sign from the binary counter 26, by which it determines that it is in the state after restart, after which the MECM checks the accuracy of the information in its ENZU. If the test was successful, then the MEWM loads this information into its RAM and proceeds to the corresponding program. If the contents of the ENZU are unreliable, then the MEWM tests its ENZU and, according to the test results, generates a message about the failure of the ENZU or, if the ENZU is working properly, clears it and loads reliable information on request from the outside from the corresponding AM, AK or monitoring station, as described above.

The proposed device:
- does not use an input device (as a rule, with rotating mechanical units) as the main input of information, which is the main cause of AM frequent malfunctions, excludes (as the main) information transfer from the monitoring station to AM by magnetic storage media, which are susceptible to information loss due to aging and mechanical defects, and requires considerable time for recording information on media, transferring media from the monitoring station group to the appropriate set of PBX equipment and entering information from the media into AM;
- eliminates the possibility of freelance work of AM and AK by constantly monitoring through the restart block the correct sequence of program execution in AM and AK and turning on a local restart in AM or AK to restore their regular functioning in cases of violations in the sequence of program execution in the latter;
- reduces the time to restore the working capacity, information and control programs of AM and AK after software freezes and hardware failures due to the restoration of information in AM and AK from its own ENZU or via communication lines in automatic mode without human intervention;
- It makes it possible to promptly display information on the current monitoring station about the current state of the main and backup power sources in the system units, as well as unauthorized access to them, which allows you to quickly take appropriate measures.

Claims (1)

 The restart block of the hardware kit of the automated telephone exchange of the fire alarm system is made in the form of a memory address decoder, ROM, non-volatile memory device, external device address decoder, AND element, control register, switch block, status register, battery monitoring node of non-volatile memory device, binary counter, reset pulse blocker, reset pulse shaper, signal conditioning unit, indication unit, sensors and unauthorized access, a pulse generator, a buffer element, the first group of outputs of which is connected to the address decoder of external devices, the first output of which is connected to the first input of the binary counter, the second input of which is connected to the input of the reset pulse blocker, the third input is with the output of the pulse generator, output binary counter connected to the sixth input of the status register and the input of the reset pulse shaper, the output of which is connected to the input of the buffer element, the second group of outputs of which are connected connected to a memory address decoder, the first output of which is connected to the first input of the ROM, the group of outputs of which is connected to the second group of inputs / outputs of the buffer element, the second output of the memory address decoder is connected to the first input of the AND element, the output of which is connected to the input of non-volatile memory the group of inputs / outputs of which is connected to the second group of inputs / outputs of the buffer element, the output of the non-volatile storage device is connected to the first input of the nodes and monitoring the battery of a non-volatile memory device, the output of which is connected to the first input of the status register, and the second input is connected to the first output of the control register, the second output of which is connected to the second input of the And element, the third output is connected to the second input of the ROM, the input is connected to the second output of the decoder addresses of external devices, the third output of which is connected to the second input of the status register, the group of inputs of which is connected to the group of outputs of the switch block, and the first group of outputs is connected to by a group of inputs / outputs of the buffer element, the third input - with the output of an unauthorized access sensor, the second group of outputs connected to the group of inputs of the display unit, the group of outputs of which are connected to external and internal indicators, the first and second inputs of which are connected respectively to the first and second outputs of the unit signal generation.

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