RU57480U1 - EMERGENCY SITUATION MONITORING SYSTEM - Google Patents

Abstract

The invention relates to computer technology, in particular, to an automated information system for monitoring emergency situations. The technical result is to increase the speed of the emergency monitoring system by implementing procedures for automatically identifying the state of monitoring objects at the time of receipt of data on controlled parameters. The technical result is achieved in that the system comprises a module for generating time intervals for monitoring monitoring objects, a counter, a module for switching channels for interrogating the state of monitoring objects, a module for identifying cycles for interrogating monitoring objects, a module for selecting time intervals for monitoring, a module for selecting parameters of monitoring objects, a module for selecting a reference address of objects monitoring in the server database, two registers, a module for receiving data from monitoring objects and a module for identifying data from monitored objects Oring.

Description

The utility model relates to the field of computer technology, in particular, to an emergency monitoring system.

The current situation, associated with an increase in technological hazards, as well as terrorist manifestations, puts forward additional requirements for ensuring the safe operation of high-risk facilities for the environment.

The key point in ensuring the security of high-security facilities is information systems for monitoring controlled facilities. A promising direction for solving such problems is the introduction of control subsystems in these systems, which will make it possible to make operational decisions in case of a threat, as well as to accumulate and use information about persons representing a threat in the central repositories of territorial information systems.

Known systems that could be used to solve the problem (1, 2).

The first of the known systems contains data reception and storage units connected to control and data processing units, search and selection units connected to data storage and display units, the synchronizing inputs of which are connected to the outputs of the control unit (1).

A significant drawback of this system is the impossibility of solving the problem of updating the data for monitoring the state of objects stored in the server database, while simultaneously solving the problem of issuing monitoring results in real time.

Another system is known that contains data processing modules, the information inputs of which are connected to the data reception and control units, and the outputs are connected to the first group of memory modules, the central processor, the inputs of which are connected to the outputs of the memory modules of the first group and data processing modules, and the outputs are connected with the inputs of the memory modules of the second group and data display modules (2).

The last of the above technical solutions is closest to the described.

Its disadvantage lies in the low speed of the monitoring system, due to the fact that the state of high-risk facilities are monitored only after the state parameters of the monitored objects are written to the server database and then processed.

The purpose of the invention is to increase the speed of the emergency monitoring system by implementing procedures for automatically identifying the state of objects of control at the time of receipt of data on controlled parameters.

This goal is achieved by the fact that in a known system containing a module for generating time intervals for monitoring monitoring objects, the first clock input of which is the clock input of the system, and the first output is connected to the counter input, the channel switching module is used to interrogate the state of the monitoring objects, the information input of which is connected to the output counter, and the outputs are the outputs of the signals polling the state of the parameters of system objects, the first register, the information output of which is the first address output m of the system, the second register, the information output of which is the second address output of the system, and the module for receiving data from monitoring objects, the information and synchronizing inputs of which are information and synchronizing inputs of the system, and the output is the information output of the system, a module for identifying polling cycles of monitoring objects, information the input of which is connected to the output of the counter, the synchronizing input is connected to the first output of the module for generating time intervals for monitoring the object s control, one output is connected to the synchronizing input of the switching module of the channel for interrogating the state of the objects of monitoring, and the other is connected to the installation inputs of the counter and the module for generating time intervals for monitoring the objects of monitoring, the module for selecting time intervals for monitoring, one input of which is connected to the other output of the module for identifying polling cycles monitoring objects, another input is connected to the second output of the module for generating time intervals for monitoring monitoring objects, and the output is connected to the second by the clock input of the module for generating time intervals for monitoring monitoring objects, the module for selecting the reference address of monitoring objects in the server database, the first and

the second information outputs of which are connected to the information inputs of the first and second registers, respectively, the synchronizing inputs of which are connected to the synchronizing output of the module for selecting the reference address of monitoring objects in the server database, the module for selecting parameters of monitoring objects, the inputs of which are connected to the corresponding outputs of the module for switching channels of polling the status of objects control, one information output is connected to the information input of the module for selecting the reference address of objects monitor Inga is in the server database, and the synchronizing output is connected to the synchronizing input of the selection module of the reference address of the monitoring objects in the server database, and the identification module of the data of monitoring objects, one information input of which is connected to another information output of the module for selecting parameters of monitoring objects, another information input is connected to the output of the module for receiving data of monitoring objects, and the synchronizing input is connected to the synchronizing input of the system, while the first output of the module is identical The display of these monitoring objects is the first synchronizing output of the system, the second output is the second synchronizing output of the system, and the third output is connected to the installation inputs of the first and second registers.

The invention is illustrated by drawings, where Fig. 1 is a structural diagram of a system, Fig. 2 is a structural diagram of a module for generating time intervals for monitoring monitoring objects, Fig. 3 is a structural diagram of a switching module of channels for interrogating the state of monitoring objects, and Fig. 4 is a Fig. 5 is a block diagram of a module for selecting parameters of monitoring objects, Fig. 6 is a block diagram of a module for selecting parameters of monitoring objects, and Fig. 7 is a block diagram. urn reference module selection module

addresses of monitoring objects in the server database, Fig. 8 is a structural diagram of a module for identifying data of monitoring objects.

The system (Fig. 1) comprises a module 1 for generating time intervals for monitoring monitoring objects, a counter 2, a module 3 for switching channels for interrogating the state of monitoring objects, a module 4 for identifying cycles for interrogating monitoring objects, a module 5 for selecting time intervals for monitoring, a module 6 for selecting parameters for monitoring objects, module 7 for selecting the reference address of monitoring objects in the server database, the first 8 and second 9 registers, module 10 for receiving data from monitoring objects and module 11 for identifying data of monitoring objects.

Figure 1 also shows the information 21 system input, synchronizing the 22 system input and clocking the 23 system input, as well as outputs 24-26 of the polling signals of monitoring objects, the first 27 and second 28 address outputs of the system, information 29 system output, the first 30 and second 31 system clock outputs.

Module 1 (figure 2) of the formation of time intervals for monitoring monitoring objects contains a pulse generator 35, trigger 36, element 37 AND, element 38 OR. The drawing shows the synchronizing 22, 39 and installation 40 inputs, as well as the first 41 and second 42 outputs.

Module 3 (Fig. 3) of switching channels for interrogating the state of monitoring objects includes a decoder 45, elements 46-48 I. The drawing shows information 49 and synchronizing 50 inputs, as well as the outputs of interrogation signals for the status of monitoring objects.

Module 4 (Fig. 4) for identifying polling cycles of monitoring objects comprises a register 55, a comparator 56, and a delay element 57. The drawing shows the information and synchronization inputs of the module, as well as the first 60 and second 61 outputs.

Module 5 (figure 5) selection of monitoring time intervals contains a counter 65, register 66, comparator 67, trigger 68, element 69 AND,

delay element 70. The drawing shows the first 71 and second 72 inputs and outputs 73 of the module.

Module 6 (Fig.6) selection of parameters of monitoring objects contains a module 75 of memory, made in the form of read-only memory, register 76, element 77 OR, element 78 delay. The drawing shows synchronizing inputs 79-81, as well as information 82, 83 and synchronizing 84 outputs.

Module 7 (Fig.7) selection of the reference address of the monitoring objects in the server database contains a memory block 85 made in the form of read-only memory, a decoder 86, elements 87-89 AND, elements 90, 91 delays. The drawing shows information 92 and synchronizing 93 inputs, as well as information 94, 95 and synchronizing 96 outputs.

Module 10 (Fig. 1) for receiving data from monitoring objects is made in the form of a register having information 21 and synchronizing 23 inputs, as well as output 28.

The module 11 (Fig. 8) for identifying data of monitoring objects comprises a comparator 105, an OR element 106, delay elements 107,108. The drawing shows the first 109, second 110 information and synchronizing 111 inputs, as well as outputs 30, 31 and 114.

All nodes and elements of the system are made on standard potential-impulse elements. To simplify the drawing, the chains of the initial installation of the modules in the initial state are not shown in the drawing.

The system operates as follows.

To start the system, the input 23 of the module 1 receives a clock signal "Start", which passes the element 38 OR and is fed to the direct input of the trigger 38, setting it to a single state. As a result of this, at the single output of trigger 38, a high potential appears, which opens the element 37 And one by one

an input to another input of which pulses are constantly supplied with a given repetition period from the pulse generator 35.

As a result, pulses directly from the pulse generator 35 are issued to the output 41 of the module 1, and pulses of the generator 35 transmitted to the output of the element 37 I. are output to the output 42.

From output 42, a sequence of pulses with a given repetition period goes both to the counting input of counter 2 and to the clock input of block 4. Counter 2 counts the number of incoming pulses to its input and gives the code of the number of received pulses both to input 49 of module 3 and to input 58 of module 4.

The code of the number of pulses after each incoming pulse from the input 49 of module 3 is fed to the input of the decoder 45, which decrypts the received code and sequentially opens the elements 46-48 And after the next pulse arrives at the counter 2. At the inputs of the elements 46-48 And from the input 50 of the module 3 clock pulses arrive.

As a result of this, at the outputs 51-53 of module 3 and, respectively, at outputs 24-26, pulses of interrogating the state of the corresponding monitoring objects appear consecutively, which are sent to the polling of the state sensors of the monitored objects from the indicated outputs (not shown in the drawing).

In parallel with this process, the code of the number of pulses of the counter 2 through the input 58 is fed to one information input of the comparator 56 of block 4, the other information input of which is the code of the number of objects of control, which is constantly entered in the register 55. Each pulse received at the counting input of the counter 2 from the output 42 module 1 also enters the input 59 of module 4, where it is delayed by element 57 for the duration of the counter 2 operation and then arrives at the synchronizing input of the comparator 56.

By a synchronizing signal from input 59, comparator 56 compares the input codes and, if the number of pulses in counter 2 is less than the number of objects

in the register 55, then at the output 60 a clock pulse of polling is generated, which is input 50 of module 3.

The process of interrogation of the state of the objects of control continues until the comparator 56 does not fix the equality of the codes of the counter 2 and the register 55 by issuing a signal to the output 61 of the module 4, from where the specified signal is supplied to the installation input 40 of the module 1 and resets the trigger 36 to its original state, blocking, thereby, the passage of the pulses of the generator 35 through the element 37 I.

In addition, the same pulse is supplied to the input 72 of module 5, where it passes to the direct input of trigger 68 and sets it to a single state, in which the And element 69 opens, connecting the generator 35 of module 1 through output 41 and input 71 of module 5 to the counter input 65 counting the number of clock pulses.

The number of clock pulses fixed by the counter 65 by the comparator 67 is compared with the length of the pause period between polls of the state of the monitoring objects, which is constantly entered in the register 66. The comparison is carried out for each clock pulse, which, after a delay of 70 by the counter 65, is fed to the synchronizing input of the comparator 67 . As soon as the comparator 67 fixes the equality of the input codes, at its output 73 a clock pulse is generated to start the polling mode of the state of the monitoring objects, which firstly, it enters the installation input of trigger 68 and resets it to its original state, thereby blocking the arrival of pulses from input 71 to the input of counter 75. Secondly, it enters the installation input of counter 65 and resets it to its original state .

And, finally, thirdly, it enters the clock input 39 of module 1 and starts again the process of generating pulses of polling the state of objects of control described above.

In the process of interrogating the state of the monitoring objects, each of the interrogation pulses from the outputs 51-53 of block 3 also goes to the corresponding inputs 79-81 of module 6, where, firstly, it goes to the read input of the corresponding fixed memory cell of ROM 75, where the identifier of the corresponding object is stored control in the system server database and the values of the reference parameters of the controlled object.

The data structure of the write file of a fixed cell ROM is as follows:

THE CODE THE CODE ID of the object of control Attributes of the reference state parameters of an object

From the output of the ROM 75, the fixed-cell recording file is sent to the information input of the register 76.

Secondly, each of the polling pulses from the inputs 79-81 of module 6 through the OR element 77 is delayed by the element 78 for the time of reading the fixed memory cell of the ROM 75 and is supplied to the synchronizing input of the register 76, bringing it read information.

In addition, the same pulse from the output of the delay element 78 through the output 84 of the module 6 is supplied to the input 97 of the module 7.

From the output 82 of block 6, the identifier code of the control object through the input 92 of module 7 is input to the decoder 86, which decodes the identifier code and opens one of the elements 87-89 I corresponding to it.

In parallel with this process, the synchronizing pulse from the input 93 is delayed by the element 90 for the time the code is entered in the register 76 and the decryptor 86 is activated, and is fed to one of the inputs of the elements 87-89 I.

Given the fact that only one of the elements 87-89 I will be open at one input, then passing through the corresponding element I, the clock pulse arrives at the read input of a fixed memory cell of the permanent storage device 85, where the location coordinate code of the indicated monitoring object on the ground and the code are stored write addresses of the controlled parameters of the monitoring object in the system server database.

The structure of the data stored in a fixed memory cell of the ROM 85 has the following form:

THE CODE THE CODE Location coordinates of the monitoring object Record address of monitored parameters of the monitoring object

The location coordinate code of the monitoring object on the ground is read from the memory module 85 to the output 94 and then goes to the information input of the register 8, and the code of the recording address of the controlled parameters of the monitoring object is read to the output 95 and then goes to the information input of the register 9.

In parallel with the described process, the same read pulse is delayed by the delay element 91 while reading the contents of the fixed cell ROM 85 and then from the output 96 of the module 7 is fed to the synchronizing inputs of the registers 8 and 9, fixing the corresponding read codes in them.

The coordinate code of the location of the monitoring object on the ground from the output of register 8 is issued to the address output 27 of the system, and the code of the address of the recording of the controlled parameters of the monitoring object from the output of register 9 is output to the output 28 of the system.

After polling the state of the monitoring object, the numerical values of the monitored parameters of the object are fed to the input 21 of the system and then fed to the input of the module 10, where they are recorded by the synchronizing pulse of the data received at input 22.

From the output of module 10, the measured numerical values of the state parameters of the monitoring object are received at the input 110 of the module 11, to the other input 109 of which the output values of the module 6 receive the reference values of the same parameters. In addition, the synchronizing pulse from the input 22 of the system enters the input 111 of the block 11, where it is delayed by the element 107 for the time the data are entered into the module 11, and then it is issued to the synchronizing input of the comparator 105.

By a synchronizing signal, the comparator 105 compares the input codes and, if they have no differences, then a signal is generated at its output 112, which, firstly, is output to the system output 30 and then goes to the input of the first channel of the database server interrupt.

By this signal, the server goes to the subroutine for recording the contents of block 11 from the output 29 of the system at the address indicated on the output 28.

Secondly, the signal from the output 112 of the comparator 105 through the OR element 106 is delayed by the element 108 while recording the received values of the parameters of the monitoring object in the server database and from the output 114 of the module 11 is supplied to the installation inputs of the registers 8, 9, resetting them to their original state.

If the comparator 105 detects the deviation of the numerical indicators of the monitored parameters of the monitoring object from the normative, a signal is generated at its output 113. This signal, firstly, is immediately issued as an alarm to the workstation of the emergency duty officer, and secondly, it arrives to the input of the second channel of the server database interrupt.

By the same signal, the server switches to the routine for reading the readings of registers 8 and 9 and displaying the coordinates of the location of the monitoring object, the numerical values of the indicators of which do not correspond to the reference, on an electronic cartographic map of the area.

Upon completion of the alarm and display of this monitoring object, the pulse from output 113, the passed OR element 106 and delayed by element 108 for the duration of the alarm and display of this monitoring object, from output 114 goes to the setting inputs of registers 8 and 9.

Thus, the introduction of new nodes and blocks has significantly improved the speed of the emergency monitoring system by implementing procedures for automatically identifying the state of monitoring objects at the time of receipt of data on controlled parameters.

Sources of information taken into account when drawing up the description of the application:

1. US Patent No. 5136708 M.C. G 06 F 15/16, 1992

2. US Patent No. 5129083 M.C. G 06 F 12/00, 15/40, 1992 (prototype).

Claims (1)

An automated information system for monitoring emergency situations, containing a module for generating time intervals for monitoring monitoring objects, the first clock input of which is a clock input of the system, and the first output is connected to the counter input, a switching module for interrogating the state of monitoring objects, the information input of which is connected to the meter output, and the outputs are the outputs of the signals polling the state of the parameters of system objects, the first register, the information output of which is not system output address, a second register, the information output of which is the second address output of the system, and a module for receiving data from monitoring objects, the information and synchronizing inputs of which are information and synchronizing inputs of the system, and the output is the information output of the system, characterized in that the system contains a module identification of polling cycles of monitoring objects, the information input of which is connected to the output of the counter, the synchronizing input is connected to the first output of the form module monitoring time intervals for monitoring the monitoring objects, one output is connected to the synchronizing input of the switching module of the channel for interrogating the state of the monitoring objects, and the other is connected to the installation inputs of the counter and the module for generating time intervals for monitoring the monitoring objects, the module for selecting the monitoring time intervals, one input of which is connected to another output module for identification of cycles of interrogation of monitoring objects, another input is connected to the second output of the module for the formation of time intervals monitor nga of the monitoring objects, and the output is connected to the second clock input of the module for generating time intervals for monitoring the monitoring objects, the module for selecting the reference address of the monitoring objects in the server database, the first and second information outputs of which are connected to the information inputs of the first and second registers, respectively, whose synchronizing inputs are connected with the synchronizing output of the module for selecting the reference address of monitoring objects in the server database, the module for selecting parameters of monitoring objects the inputs of which are connected to the corresponding outputs of the switching module of the channel for interrogating the state of monitoring objects, one information output is connected to the information input of the selection module of the reference address of monitoring objects in the server database, and the synchronizing output is connected to the synchronizing input of the selection module of the reference address of monitoring objects in the server database , and a module for identifying data of monitoring objects, one information input of which is connected to another information output of the selection module parameters of monitoring objects, another information input is connected to the output of the module for receiving data of monitoring objects, and the synchronizing input is connected to the synchronizing input of the system, while the first output of the identification module of the data of monitoring objects is the first synchronizing output of the system, the second output is the second synchronizing output of the system, and the third the output is connected to the installation inputs of the first and second registers.