RU168272U1 - Integrated system for collecting and processing data of external environmental indicators for monitoring critical situations in the Arctic - Google Patents

Abstract

The utility model relates to computing, in particular to an integrated system for collecting and processing data from external environmental state detectors when monitoring critical situations in the Arctic. The technical result is to expand the functionality of the system by collecting and processing data from all external environmental state detectors while monitoring critical situations in the Arctic in real time. The technical result is achieved by the fact that the system comprises a module for receiving messages from geographically distributed external environmental state detectors, a module for selecting reference addresses of external environmental state detectors in the system server database, a memory module, first, second and third messages addressing modules of external environmental state detectors environment in the system server database, module for setting the total number of messages of external environmental state detectors to be processed in the system, mod To control the number of messages received by the system and the address signal integration module. 5 ill.

Description

The utility model relates to computing, in particular to an integrated system for collecting and processing data from external indicators of the state of the environment when monitoring critical situations in the Arctic.

In the Arctic, there are both climatic and natural, as well as man-made sources of emergency situations.

The main climatic and natural indicators of critical situations include permafrost degradation (thawing), landslides, landslides; snow avalanches; floods (spring, autumn), ice jams, ice movement; landscape fires (tundra, light forest); blizzards, storms; strong winds (hurricanes) and sleet.

Every year, in almost all parts of the Arctic region, there is a danger of landscape fires that has increased in recent decades due to more frequent accidents at oil pipelines, gas pipelines and at enterprises for the extraction, processing and storage of gas, oil and oil products. Spring-summer floods, accompanied by ice jams on the rivers of the Arctic region, cause great damage to the population and the economy.

A serious potential threat to natural systems and human security in the Arctic is global warming, which in the polar regions is almost 10 times stronger than the global average. According to scientists in the Arctic, the most severe climatic changes are occurring - it may become 3-7 degrees warmer in the next 100 years.

Potential dangers of radiation pollution in the Arctic zone may arise due to the flooding of radioactive waste in the Barents and Kara Seas in the 50-60s of the last century, nuclear weapons testing in Novaya Zemlya, and the operation of the Kola and Bilibino NPPs.

On average, up to 100 emergencies of a man-made and natural-man-made nature occur annually in the Arctic zone of Russia.

The main objective of the emergency monitoring and forecasting system is to provide information support for making managerial decisions to prevent emergencies, to alert the governing bodies, forces and means of functional and territorial subsystems to respond to threats and emergencies.

The use of the Arctic zone of the Russian Federation as a strategic resource base of our country necessitates the creation of special conditions to ensure the safety of the population in the Arctic. In this regard, taking into account the priorities of the socio-economic development of this region, the tasks of particular importance are:

improving the safety of navigation in areas of heavy traffic by implementing a set of measures for hydrometeorological and navigation support in the Arctic zone;

creation of integrated security systems for territories based on the deployment of information and analytical systems for monitoring the status of critical and potentially dangerous objects in the Arctic zone and sources of emergency situations of a natural and technogenic nature.

When creating a system for monitoring critical situations in the Arctic, the following features should be considered:

extreme climatic conditions, including permanent ice cover or drifting ice in the Arctic seas;

focal nature of industrial and economic development of territories and low population density;

remoteness from major industrial centers, high resource consumption and the dependence of economic activity and livelihoods of the population on the supply of fuel, food and essential goods from other regions of Russia;

low stability of ecological systems that determine the biological balance and climate of the Earth, and their dependence even on minor anthropogenic impacts.

Known technical solutions to the problem (1, 2).

The first of the known technical solutions contains at least one block of on-board recording equipment connected by at least two communication channels to a control and data processing unit, which is connected to the on-board equipment of the spacecraft via a communication channel for subsequent dumping of information to the Earth, control and data processing unit includes a pairing device, stand-alone timer device, single-board computer, forced cooling system, temperature sensor system, storage unit, bl a synchronous data transfer unit and secondary power system broadcast commands and power distribution (1).

The disadvantage of this technical solution is its limited functionality, due to the fact that the system does not control the receipt of a complete set of data characterizing the hallmarks of critical situations.

Another technical solution is known that contains a network of remote pollution detectors, a programmable controller with systems for collecting, preprocessing, and transmitting data, as well as a single automated information system with functions for collecting, processing, and storing data transmitted to the interfaces of the information system by remote pollution detectors, while the system for detecting and monitoring pollution of the offshore oil and gas field additionally contains a biosensor for continuous monitoring of heavy metals in water, a nuclear magnetic resonance sensor, an electron paramagnetic resonance sensor, an IR-100 thermal neutron reactor with a sliding box in the active zone (a neutron flux of 2 × 10 n / (cm ² s)) and a stationary gamma radiation unit with dose rate up to 1000 R / h, spectrometric setup with a reservoir pressure maintenance system, radiometric low-background setup, microwave radiation generators of various frequencies from 0.1-60 THz, exemplary holographic matrices with recorded NMR spectra of atoms of substances (metals and organic substances) and identifiable substances, the information block of sea charts and color space photographs of the search areas, an electromagnetic camera (Kirlian camera) for visualizing flooded objects in aerospace images and transferring them to the sea map of the search area using a video camera combined with a personal computer wide-angle phase antennas, GPS tar-60 receiver, PC software package for determining the coordinates of flooded objects and displaying them on the sea map of the area, atomic absorption spectrophotometer, as well as O ther constructional elements (2).

The disadvantage of this technical solution also lies in its limited functional capabilities, ensuring monitoring only emergency oil spills at offshore oil and gas facilities.

The purpose of the utility model is to eliminate this drawback, i.e. in expanding the system’s functionality by collecting and processing data from all external environmental indicators while monitoring critical situations in the Arctic in real time.

This goal is achieved by the fact that in a system containing a module for receiving messages from geographically distributed external indicators of the state of the environment, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system

accordingly, the first information output of the module for receiving messages from geographically distributed external indicators of the state of the environment is the information output of the system intended for issuing messages to the information input of the database server, while the first information input of the system is designed to receive messages from the geographically distributed external indicators of the environment , the first synchronizing input of the system is intended for receiving synchronizing signals for entering messages geographically distributed external indicators of the state of the environment in the module for receiving messages of geographically distributed external indicators of the state of the environment, a module for setting the total number of messages of external indicators of the state of the environment, the information and synchronizing inputs of which are the second information and second synchronizing inputs of the system, respectively, while the second the system information input is designed to receive the total number of messages of external status indicators about environment, the first synchronizing input of the system is designed to receive synchronizing signals for recording the total number of messages of external environmental indicators in the installation module for the total number of messages of external environmental indicators, the integration module of address signals, the address output of which is the address output of the system, intended for issuing addresses write messages to the system database server, and the synchronizing output of the address signal integration module is a synchronizer a system output intended for issuing synchronizing signals to the input of the first channel of the database server interrupt, and a memory module, a module for selecting reference addresses of external environmental indicators in the system server database is introduced, the information input of which is connected to the second information output of the message receiving module - distributed external indicators of the state of the environment, the synchronizing input of the module for selecting the reference addresses of external indicators of the state of the environment In the server database, the system is connected to the first synchronizing input of the system, and the signal outputs of the module for selecting the reference addresses of external environmental indicators in the database of the system server are connected to the corresponding signal inputs of the memory module, message addressing modules of external environmental indicators in the server database systems whose information inputs are connected to the information output of the memory module, the control inputs of the message addressing modules of external indicators The environmental values in the system server database are connected to the corresponding control outputs of the module for selecting the reference addresses of external environmental status indicators in the system server database, the synchronizing output of which is connected to the synchronizing inputs of the message addressing modules of external environmental status indicators in the system server database, the information outputs of the message addressing modules of external environmental indicators in the system server database are connected with the corresponding information inputs of the address signal integration module, the synchronizing outputs of the message addressing modules of external environmental indicators in the system server database are connected to the corresponding synchronizing inputs of the address signal integration module, and the signal outputs of the message addressing modules of external environmental indicators in the system server database are the signal outputs of the system, and the module for monitoring the number of messages received by the system, information the course of which is connected to the information output of the module for setting the total number of messages of external environmental indicators, the counting input of the module for monitoring the number of messages received by the system is connected to the synchronizing output of the address signal integration module, while the clock output of the module for monitoring the number of messages received by the system is a clock output of the system for issuing messages receiving signals, and the control output of the control module of the number of messages received by the system is the control in system output intended for issuing signals for the end of the cycle of receiving messages from geographically distributed external indicators of the state of the environment.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is a structural diagram of a system; FIG. 2 is a block diagram of a module for selecting reference addresses of external indicators of the state of the environment in the system server database, FIG. 3 is a structural diagram of the first, second, and third message addressing modules of external environmental indicators in the system server database; FIG. 4 is a structural diagram of a module for monitoring the number of messages received by the system, FIG. 5 is a block diagram of an address signal integration module.

The integrated system for collecting and processing data of external environmental indicators for monitoring critical situations in the Arctic (Fig. 1) contains a module 1 for receiving messages from geographically distributed external environmental indicators, a module 2 for selecting reference addresses of external environmental indicators in the server database systems, memory module 3, first 4, second 5 and third 6 message addressing modules of external environmental indicators in the system server database, module 7 is installed Application total number of posts of external environmental indicators, to be processed in the system control unit 8, the number of received messages and system integration module 9 address signals.

In FIG. 1 shows the first 11 and second 12 information inputs of the system, the first 13 and second 14 synchronizing inputs of the system, as well as information 15 and address 16 outputs of the system, synchronizing 17 system outputs, the first 18, second 19 and third 20 signal outputs of the system, clock output 21 and control output 22.

The module 1 for receiving messages of geographically distributed external indicators of the state of the environment (Fig. 1) is made in the form of a register having information 11 and synchronizing 13 inputs, as well as the first 24 and second 25 information outputs.

Module 2 selection of reference addresses of external indicators of the state of the environment in the database server system (Fig. 2) contains a decoder 30, elements 31-33 And, elements 34, 35 delay. The drawing shows information 26 and synchronizing 27 inputs, a group of signal 36-38 outputs, a group of control 39-41 outputs and a synchronizing 42 output.

The memory module 3 (Fig. 3) is made in the form of a permanent storage device having read inputs 43-45 and information output 46.

Modules 4, 5 and 6 (Fig. 4) of message addressing of external environmental state detectors in the system server database are identical and contain the first 50 and second 51 registers, adder 52, comparator 53, counter 54, group 55 of And elements, element 56 And, delay elements 57, 58. The drawing shows information 59, control 60 and synchronizing 61 inputs, as well as information 62, synchronizing 63 and signal 64 outputs.

Module 7 for setting the total number of messages of external indicators of the state of the environment to be processed in the system (Fig. 1) is made in the form of a register having information 57 and synchronizing 58 inputs and information 59 output.

Module 8 (Fig. 4) for monitoring the number of messages received by the system contains a counter 66, a comparator 67, and a delay element 68. The drawing shows the information input 65, the counting input 69, as well as the timing 21 and control 22 outputs.

Module 9 (Fig. 5) integration of address signals contains a group of 73 OR elements and an OR element 74. The drawing shows a group of information inputs 81-83 and a group of clock inputs 84-86, as well as address 16 and synchronizing 17 output.

The system operates as follows.

In the process of monitoring critical situations, the data of each of the external indicators of the state of the environment in accordance with the established regulations are received at the system input in the form of messages (codograms) having the following structure

Before the system starts operation, the module 7 with the information input 12 receives the code for the specified number of messages, which should be received from external indicators of the environment in accordance with the established rules, by the synchronizing signal from input 14.

In the process of submitting recorded data by geographically distributed external indicators of the state of the environment in accordance with the established regulations, each of the messages goes to the information input 11 of module 1 of the monitoring system (Fig. 1), and is entered into the register of module 1 with a clock pulse from input 13. Output 24 module 1 is the information output 15 of the system, designed to issue received messages to the information input of the database server of the system.

The code of the identifier of the external indicator of the environmental state from the output 25 of module 1 is fed to the information 26 input of the module 2 and then to the input of the decoder 30, and the synchronizing pulse from the input 13 through the input 27 of the module 2 of the system is delayed by the delay element 34 for the time of entering the code of the identifier of the external status indicator environment in the register of module 1 and the operation of the decoder 30, and then goes to the inputs of elements 31-33 I.

The decoder 30 decrypts the incoming code, opening one of the elements 31-32 And, and prepares the signal path from the output of the delay element 34. For definiteness, we assume that a high potential is received at one input of element 31 I.

Given the fact that only one And 31 element will be open at one input, then passing this And element, the clock pulse from output 36 goes to the read input of a fixed memory cell of the permanent storage device 3.

The following data is stored in a fixed memory cell of module 3:

The read data from the output 46 of module 3 is fed to the information inputs 59 of all modules 4, 5 and 6, however, they will only be accepted by module 4, since the high potential from the output 39 of module 2 is supplied to the control input 60 of module 4 and opens a group of elements one input 55 And and element 56 I.

At the same time, the synchronizing pulse from the output of the element 34 of module 2 is delayed by the delay element 35 for the time of reading the fixed memory cell of the permanent storage device 3, and from the output 42 of the module 2 through the synchronizing input 61 of the module 4 passes through the element 56 AND to the synchronizing inputs of the registers 50 and 51 .

As a result of this, the code of the reference address of the recording of incoming messages from this external environmental status indicator is entered into register 50, and the number of messages that should come from this external environmental status indicator is entered into register 51 of module 4.

From the output of the register 50, the code of the reference address of the record is supplied to one input of the adder 52, the counter 54 output is connected to the other input, and from the output of the register 51, the code of the number of messages to be received is fed to one input of the comparator 53, the other input of which is also connected to the output counter 54.

In parallel with this, the synchronizing pulse from the output of element 56 AND is delayed by the delay element 57 for the time the codes are entered into the registers 50, 51 and fed to the synchronizing input of the comparator 53. With this pulse, the comparator 53 compares the readings of the register 51 with the readings of the counter 54.

Given that the counter 54 is currently in the initial state and its readings are equal to zero, the comparator 53 will give a signal at its first output, from which the clock pulse firstly goes to the clock input of the adder 52, which sums the reference address code from the output register 50 with a zero counter code 54, and at its output 62 the code of the reference address of the database server will be fixed, which from the output 62 of the module 4 goes to the information input 81 of the module 9, and then through the elements 73 OR of the group is issued to the address output 16 system.

Secondly, the same synchronizing pulse arrives at the counting input of the counter 54, bringing the first unit into it, indicating that one message from this external indicator of the state of the environment has already been received.

And finally, thirdly, the same pulse is delayed by the delay element 58 for the response time of the adder 52 of the module 4, and from the output of the 63 module 4 is fed to the input 84 of the module 9, and then through the element 74 OR is issued to the synchronizing output 17 of the system, where it is issued to the input of the first channel of the database server interrupt.

With the arrival of this impulse, the database server switches to the data recording routine of this external environmental indicator from output 15 at the address set on the address output 16 of the system.

In addition, the synchronizing pulse from the output 17 of the system goes to the counting input 69 of module 8 and then goes to the counting input of the counter 66, counting the number of messages received from external indicators of the environment, cumulatively. A fixed number of messages from the counter 66 is issued to one input of the comparator 67, to the other input of which from the input 65 of module 8 a code of a given number of messages is received, which must be received from external indicators of the environment from the output of module 7.

According to the synchronizing pulse from input 69, delayed by the delay element 68 for the time of operation of the counter 66, the comparator 67 compares the counter with a given number of messages received from the output of module 7.

If the counter 66 is less than the specified number of messages, then the comparator 67 of module 8 generates a clock pulse at its output 70, which is supplied to the clock output 21 of the system as a control signal for the system to receive the next message.

If the readings of the counter 66 are equal to the specified number of messages to be received from the module 7, then the comparator 67 of the module 8 generates a pulse at the output 22 of the system, which is the signal that the system is finished.

A feature of the operation of message addressing modules of external environmental indicators is that each of them monitors the receipt of a given number of messages from a specific external environmental indicator.

Indeed, the signal of receipt of all the given messages at the signal output 64 of each of the objects message addressing modules 4, 5, 6 will be issued only if the readings of the counter 54 and the code of the specified number of messages to be received are the same.

This fact will be recorded on the display panel of the monitoring results.

Thus, the introduction of new modules made it possible to significantly expand the functionality of the system by checking the availability of data from all external environmental indicators necessary for the preparation of reporting data in real time.

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

1. RF patent No. 2498399 (05.29.2012)

2. RF patent No. 2587109 (04.16.2015) (prototype).

Claims (1)

An integrated system for collecting and processing data of external environmental indicators for monitoring critical situations in the Arctic, containing a module for receiving messages from geographically distributed external environmental indicators, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, and the first information output of the module receiving messages geographically distributed external indicators of the state of the environment is information output of the system intended for issuing messages to the information input of the database server, while the first information input of the system is designed to receive messages of geographically distributed external indicators of the environment, the first synchronizing input of the system is designed to receive synchronizing signals of entering messages of geographically distributed external indicators environmental conditions in the module for receiving messages from geographically distributed external indicators with environmental conditions, a module for setting the total number of messages of external environmental indicators, the information and synchronizing inputs of which are the second information and second synchronizing inputs of the system, respectively, while the second information input of the system is designed to receive the total number of messages of external environmental indicators, the first synchronizing the system input is intended for receiving synchronizing signals of recording the total number of messages of external indicators environmental conditions in the installation module for the total number of messages of external environmental status indicators, the address signal integration module, the address output of which is the address output of the system, designed to provide message recording addresses to the system database server, and the synchronization output of the address signal integration module is the synchronization output a system designed to issue synchronizing signals to the input of the first channel of the database server interrupt, and a memory module that distinguishes The fact is that the system contains a module for selecting reference addresses of external indicators of the state of the environment in the database of the system server, the information input of which is connected to the second information output of the module for receiving messages from geographically distributed external indicators of the state of the environment, synchronizing the input of the module for selecting the addresses of the reference addresses of external state indicators the environment in the system server database is connected to the first synchronizing input of the system, and the signal outputs of the selection module are of the addresses of external environmental indicators in the database of the system server are connected to the corresponding signal inputs of the memory module, addressing modules of messages of external environmental indicators in the database of the system server, the information inputs of which are connected to the information output of the memory module, the control inputs of external addressing modules environmental indicators in the system server database are connected to the corresponding control outputs of the reference selection module addresses of external environmental indicators in the database of the system server, the synchronizing output of which is connected to the synchronizing inputs of the addressing modules of messages of external environmental indicators in the database of the system server, while the information outputs of the addressing modules of messages of external indicators of environmental status in the database of the system server connected to the corresponding information inputs of the address signal integration module, the synchronizing outputs of the co The messages of external environmental indicators in the database of the system server are connected to the corresponding synchronizing inputs of the address signal integration module, and the signal outputs of the addressing modules of external environmental indicators in the database of the system server are the signal outputs of the system, and the module controls the number of messages received by the system, the information input of which is connected to the information output of the module for setting the total number of messages of external status indicators surrounding On Wednesday, the counting input of the control module for the number of messages received by the system is connected to the synchronizing output of the address signal integration module, while the clock output of the control module for the number of messages received by the system is a clock output of the system designed to issue messages receiving signals, and the control output of the control module for the number of messages received by the system messages is the control output of the system, designed to issue signals to end the cycle of receiving messages from geographically distributed external The indicator of the environment.

Images