RU2759327C9 - Method for comprehensive monitoring of the state of dynamic objects and systems - Google Patents

Abstract

FIELD: computing technology.

SUBSTANCE: method for comprehensive monitoring of the state of dynamic objects and systems is intended to increase the adaptivity of the monitoring system in various modes by conducting continuous diagnostics in order to monitor the state of metrological characteristics and the accuracy of the measuring information at the required time.

EFFECT: expanded functional capabilities of the monitoring tools and systems, namely, new properties imparted thereon, providing remote, purposeful adaptation of the hardware and software configuration thereof for solving, at the required time, a new set of tasks of intelligent processing of heterogeneous data on the parameters of monitored dynamic systems in the process of operation thereof.

1 cl, 2 dwg

Description

The claimed invention relates to methods for conducting integrated monitoring of the state of dynamic objects and systems and can be used to assess compliance with established standards and predict changes in the state of controlled dynamic objects, systems and macrosystems in various fields of activity, including telecontrol systems and image recognition, formalization and representation of knowledge about the state of dynamic objects, in control systems for various purposes, information support for adoption, control over the execution of decisions.

Integrated monitoring is a set of organizational and technical measures, including monitoring the state of a dynamic system (DS) by various means, assessing the state by measured values of state parameters and predicting state changes under the influence of natural and anthropogenic factors. At the same time, the heterogeneity of elements of artificial and natural origin, which form the structure and composition, as well as the totality of the properties and characteristics of the environment, fully gives reason to consider it a dynamic system of the highest level of the hierarchy.

One of the main tasks of any type of monitoring is the timely provision of the state control bodies of the DS - controlled objects - with reliable information that allows to assess the parameters of the state, identify the causes, trends, and also determine the consequences of the observed changes, create prerequisites for determining a set of organizational and technical measures to correct emerging negative situations before damage is done (see Mikryukov V.Yu. Life safety .. - Rostov-on-Don: Phoenix, 2007, p. 346).

For local monitoring, mobile stations and stationary centers (posts) of control over various physical fields are used, and for regional monitoring, in addition to local monitoring tools, helicopters, airplanes and spacecraft are used to monitor the state of the earth's surface, mineral resources of the subsoil, and the safety of the animal. and flora, etc. (see Korobkin V.I., Peredelsky L.V. Ecology. - Rostov-on-Don: Phoenix, 2007, p. 531-533, p. 586, p. 589).

Currently, various methods of integrated monitoring are widely known.

The closest to the claimed method is the method of integrated monitoring of the state of dynamic objects and systems (see Patent for invention RU 2 574 083, IPC G06F 19/00, Published 10.02.2016 Bull. No. 4), the technical result of which is to expand the functionality monitoring tools and systems, namely in giving them new properties that provide remote, purposeful adaptation of their software and hardware configuration to solve at the required time a new set of tasks for intelligent processing of heterogeneous data on the parameters of controlled dynamic systems in the process of their operation; in increasing the security of data contained in the messages transmitted from the funds to the processing and control center (CCC) about the results of monitoring the state of controlled objects. Prior to the start of measurements, a block matrix-task is formed in the hardware-software complex (HSC) of the DCO for each monitoring tool to control the state of a dynamic system or object. At the same time, the composition of the block matrix-task includes: a sub-matrix-task for measuring the values of the required set of state parameters of the controlled object; a submatrix-task to change the content of the knowledge base and the procedure for using new procedures for intelligent processing of the measured values of the object's parameters; submatrix-task to change the spatio-temporal characteristics of the state of the facility in the process of monitoring. Prior to the start of additional measurements, a block matrix-task containing the following data is entered into the databases and rules of the knowledge bases of the means of monitoring through communication channels: numbered new procedures for intelligent processing of the measured values of state parameters, rules for interpreting and displaying tasks, rules for dividing the matrix-task into submatrices - tasks and generation of reports on monitoring results; rules for using procedures for intelligent processing of measured values; rules for converting measured values into a given form; rules for changing the composition of procedures for intellectual processing of measured values; identifiers of the type of actions and the values of their priority levels when changing the contents of the rule base; a dispatcher module is introduced into the measurement system of monitoring means, with the help of which the frequency of polling parameters, selection, operation of the selected set of measuring modules, as well as the operation of the module for converting the measured values of the parameters of the state of the dynamic system are controlled. If it is necessary to evaluate the state in cases of an operational change in the task, types, structure of the dynamic system, a message containing a block matrix-task is received and converted in the monitoring tool from the HSC of the control body via communication lines, and in the monitoring means it is received and converted in the equipment for receiving and transmitting data. The transformed message is transmitted to the input-output module, where submatrix-tasks are separated from the message and copied, after that a copy of the submatrix-task for measurement is transferred to the measurement system manager, and a copy of the blockmatrix-task is transferred to the rule bases and knowledge base data. In the dispatcher, the composition is formed and then the functioning of the formed set of measuring modules is controlled, which carry out measurements in accordance with a given frequency, then the results of measuring the values of the state parameters are transmitted to the conversion module, where the values are obtained and files of converted values are formed in a given form, then a matrix is formed from the files converted values, which is passed to the database. Then, in accordance with the control rules from the database, the files are transferred to the intelligent processing and evaluation module, where, using a set of procedures, in accordance with the task, the values of the estimates of the parameters and / or integral characteristics of the dynamic system are calculated, then they are compared with the allowable ones, the values are calculated and a matrix is formed dimensionless indicators of compliance (inconsistency) and fictitious indicators of discrepancy between the estimated and specified values of the controlled parameters of the state of the dynamic system, then the matrix of indicators is transmitted to the input-output module, in which it is included in the content of the message about the actual state of the dynamic system, which through the equipment for receiving and transmitting data are transmitted as a complex signal to the DOC, where they are converted and presented in the required form. This method is taken as a prototype.

The disadvantages of this method include:

- insufficient adaptability of the monitoring system in various modes at the required time and, as a result, the reliability of the measurement information necessary to solve a new set of tasks for estimating the state of dynamic systems in the process of their operation;

- non-standardized range of controlled physical parameters in the course of complex monitoring of dynamic objects and systems.

The objective of the present invention is to increase the adaptability of the monitoring system in various modes by conducting continuous diagnostics in order to monitor the state of the metrological characteristics and the reliability of the measurement information at the required time.

The technical result consists in expanding the functionality of monitoring tools and systems, namely, in giving them new properties that provide remote, targeted adaptation of their software and hardware configuration to solve at the required time a new set of tasks for intelligent processing of heterogeneous data on the parameters of controlled DS in the process their functioning.

The solution of the task and obtaining the technical result is ensured by introducing new actions into the known method and changing the order of formation, the form of transferring the results of estimating the state of the DS, which significantly distinguishes the proposed one from the known methods, namely:

- before starting the diagnostics, the control signal generator and the logical switching module are activated in the measuring system of the monitoring means, i.e. a dispatcher, with the help of which control the formation of a control signal of a given accuracy is addressed to the set of measuring modules available on the means of converting the measured values of the state parameters of the controlled Oi (or its elements) into a given form;

- based on the analysis of complex monitoring tasks, the address metrological characteristics of each module of the measuring system are determined, which are necessary for solving operational problems of complex estimation and processing of the measured values of the state parameters of the controlled dynamic system Oi (i-number of the type or configuration of the dynamic system) before they are entered into the knowledge base of the means monitoring;

- define new procedures (the sequence of assessing the accuracy of the measuring system) of the measured values of the parameters Oi;

- form in the hardware-software complex before the measurement of the parameters of the procedure for assessing the accuracy of the intended (or all used) modules of the measuring system. At the same time, the procedure for assessing accuracy additionally includes:

- a set of components (modules) for measuring the measuring system, the metrological characteristics of which must be clarified;

- the sequence of logical, technical, switching and software operations of the procedure for assessing the accuracy of the components of the measuring system;

- data format of the procedure for assessing the accuracy of the components of the measuring system;

- at the request of the measurement, the formed procedure for assessing the accuracy of the components of the measuring system is initiated.

Upon completion of the procedure for assessing the accuracy of the components of the measuring system, the following actions are performed:

- process the received data: in accordance with the accepted rules;

- transfer the received data to the software algorithm for measuring the measuring system;

- on the basis of the data obtained after the procedure for assessing the accuracy of the components of the measuring system, a new measurement algorithm is formed;

- at the required moment in real time, the software and hardware configuration of the monitoring means is remotely adjusted to receive and process additional information necessary to solve a new set of tasks for intelligent processing of heterogeneous data on the parameters of a controlled dynamic system,

- in the processing and control center, a readiness signal is generated for the next stage of measuring the state of the dynamic system.

Continuously during the measurement of physical parameters, derived parameters are calculated based on those measured according to specified rules, and in such a way that the values of all measured parameters and all derived parameters are tied to the same points in time.

The analysis of the prior art provided by the applicant made it possible to establish that there are no analogues characterized by sets of features identical to all the features of the claimed Method for complex monitoring of the state of dynamic objects and systems. Therefore, the claimed technical solution meets the condition of patentability "novelty".

The result of the search for known solutions in this field of technology in order to identify features that match the distinguishing features of the prototype of the proposed technical solution, showed that they do not follow explicitly from the prior art. From the level of technology determined by the applicant, the influence of the transformations envisaged by the essential features of the claimed technical solution on the achievement of the specified technical result has not been revealed. Therefore, the claimed technical solution meets the condition of patentability "inventive step".

The claimed method for complex monitoring of the state of dynamic objects and systems is illustrated by graphic material, where in Fig. 1 shows a diagram of the proposed method, in Fig. 2 shows the measurement module.

Where the positions are:

1 - data processing and control center,

2 - intellectual knowledge center;

3 - knowledge base;

4 - a matrix of indicators of compliance with the actual and permissible values of the state parameters, formed at the i-th stage of monitoring the j-th module;

5 - the base of rules for the formation of a task for the monitoring system;

6 - intelligent processing module;

7 - database;

8 - measurement system manager;

9 - setting the monitoring system;

10 - submatrix of the task for measurement;

11 - submatrix of the task for diagnostics of the monitoring system;

12 - processor of measured values;

13 - control signal module;

14 - measurement results;

15 - measurement modules;

16 - dynamic system;

17 - control signal switch having inputs:

a - measuring input, c - control signal input, d - control input; and measuring output - b;

18 - measuring path;

19 - information exchange module;

20 - control signal receiving module.

The method of complex monitoring of the state of dynamic objects and systems is carried out by the data processing and control center 1, which includes an intelligent knowledge center 2, a knowledge base 3, a matrix of indicators of compliance with the actual and permissible values of the state parameters, formed at the i-th stage of monitoring the j-th module 4, the base of rules for generating a task for the monitoring system 5, the intellectual processing module 6, the database 7, the manager of the measurement system 8, the task for the monitoring system 9, the submatrix of the task for measurement 10, the submatrix of the task for monitoring the monitoring system 11, the processor of the measured values 12, the module control signal 13, measurement results 14, and N measurement modules 15, which measure the parameters of the dynamic system 16.

The measurement of the dynamic system parameters is carried out by the measurement modules 15 and is transmitted to the measured value processor 12. The measured value processor 12 receives a command to launch predefined measurement modules 15 from the measurement system manager 8, controlled by the intelligent processing module 6. The intelligent processing module 6, based on the rule base generating a task for the monitoring system 5, generates a task for the monitoring system 9, consisting of a sub-matrix-task for measurement 10 in the measurement mode or a sub-matrix-task for diagnosing the monitoring system 11 in diagnostic mode.

In the measurement mode, the set of measurement modules 15, controlled by the intelligent processing module 6, measures the parameters of the dynamic system 16. The measurement results 14 through the processor of the measured values 12 under the control of the measurement system manager 8 enter the database 7 of the intelligent processing module 6. The set of measurement modules 15 is determined intelligent processing module 6 based on the rule base for generating a task for the monitoring system 5.

In the monitoring mode, the intelligent processing module 6, based on the rules contained in the rule base for generating a task for the monitoring system 5, generates a task for the monitoring system 9, containing a submatrix task for diagnosing the monitoring system 11. The submatrix task for monitoring the monitoring system 11 defines a set of measurement modules 15, control signal module control algorithm 13. Having completed the monitoring, the intelligent processing module 6 enters the monitoring results into the knowledge base 3, which stores the matrices of indicators of compliance with the actual and permissible values of the state parameters formed at the i-th stage of monitoring j th module 4. Analyzing the indicators for each measurement module 15 in time, the intelligent processing module 6 compares the actual values of the state parameters with the allowable ones and, based on this information, concludes that each mo measurement factor 15, and about the necessary corrections taken into account in the measurements until the next monitoring run. Also, the intelligent processing module 6, based on the knowledge base 3, determines the change in time of the metrological characteristics of each measurement module 15, followed by extrapolation of the measurement results, on the basis of which it generates a conclusion about the moment when the metrological characteristics of each measurement module 15 go beyond the limits of permissible values.

The measurement module 15 consists of a control signal switch 17, a measuring path 18, an information exchange module 19, and a control signal reception module 20.

The input of the measuring path 18 is connected to the control signal switch 17, which has three inputs: a - measuring input, c - control signal input, d - control input; and measuring output - b. In the measurement mode on command at the control input r, the control signal switch 17 connects the measuring path 18 to the measuring input a, to which the measured signal is applied. After processing, the measured signal from the measuring path 18 is fed to the output 6 of the measurement module 15 and, further, is fed to the information exchange module 19.

In the monitoring mode of the data processing and control center 1, by means of the measurement system manager 8, based on the rules for generating a task for the monitoring system 5, a task for the monitoring system 9 is formed, consisting of a submatrix task for diagnosing the monitoring system 11. In accordance with the submatrix task for diagnosing monitoring system 11, the control signal module 13 is activated. The measurement system manager 8, through the information exchange modules 19 of the corresponding measurement modules 15, instructs the control signal switch 17 to switch the measuring path 18 from the measuring input a to the control signal input b. The control signal coming from the control signal module 13 is fed to the control signal input through the control signal receiving module 20, and the monitoring system is diagnosed.

Thus, the tasks of expanding the functionality of monitoring tools and systems with giving them new properties that provide remote, purposeful adaptation of their software and hardware configuration to solve at the required time a new set of tasks for intelligent processing of heterogeneous data on the parameters of controlled DS during their operation has been solved.

Claims (1)

A method for complex monitoring of the state of dynamic objects and systems, which consists in the fact that monitoring tools measure the values of a set of controlled parameters by remote and contact methods, evaluate the values of controlled parameters by their measured values, compare the estimated values with acceptable ones, calculate the values of indicators of compliance or non-compliance with established standards , while the block matrix-tasks include submatrices-tasks for measuring the required set of parameters of the dynamic system, for changing the content of the knowledge base and the procedure for using procedures for intelligent processing of measured values, changing the characteristics of the state of the tool in the process of monitoring, while before entering the database the rules of the knowledge base of the monitoring tools enter the values of the boundaries of the intervals of permissible values, the procedures for intelligent processing of the measured values of the new state parameters, the formation of reports on the results of monitoring, rules for managing the process of measuring parameter values, rules for converting measured values into a given form, rules for evaluating the converted values and comparing the obtained values of estimates of the state parameters of a dynamic system with acceptable values; rules for changing the composition of procedures for intelligent processing of measured values, identifiers for the type of actions and their priority levels when performing data processing operations and changing the contents of the knowledge base, the selection, operation of the selected set of measurement modules, as well as the operation of the module for converting measured values of state parameters of a controlled dynamic system into a given form ; at the required moment in real time, the software and hardware configuration of the monitoring means is remotely configured to receive and process additional information, for this, the content of the task is formed in the processing and control center for the monitoring tool of the state of the dynamic system, after which it is transmitted from the hardware and software complex of the processing and control center, and in the means of monitoring, a message is received and converted in the equipment for receiving and transmitting data, then in the dispatcher the composition of the required set of measuring modules is formed, through which the values of the controlled parameters are then measured, after that the measurement results are transmitted to the conversion module, then they are compared with the permissible ones, calculate the values and form a matrix of indicators of compliance or discrepancy between the estimated and permissible values of the controlled parameters of the state of the dynamic system, then the matrix of indicators is transmitted to the input module - output, in which it is included in the content of the message about the actual state of the dynamic system, which is transmitted through the equipment for receiving and transmitting data to the HSC of the COA, characterized in that new actions and the procedure for forming, the form of transmitting the results of estimating the state of the DS, are additionally introduced, namely: up to the start of diagnostics activates the control signal generator and the logical switching module in the measuring system of the monitoring means, i.e. the dispatcher, with the help of which control the formation of a control signal of a given accuracy addressing the set of measuring modules available on the means of converting the measured values of the state parameters of the controlled Oi or its elements into a given form; based on the analysis of complex monitoring tasks, the address metrological characteristics of each module of the measuring system are determined, which are necessary for solving operational problems of complex estimation and processing of the measured values of the state parameters of the controlled dynamic system Oi (i is the number of the type or configuration of the dynamic system) before they are entered into the knowledge base of monitoring tools ; determine a new procedure for the order of evaluation of the accuracy of the measuring system of the measured values of the parameters Oi; form in the hardware-software complex before the measurement of the parameters of the procedure for assessing the accuracy of the intended or all used modules of the measuring system, while the accuracy assessment procedure additionally includes: a set of measurement components of the measuring system, the metrological characteristics of which must be clarified; the sequence of logical, technical, switching and software operations of the procedure for assessing the accuracy of the components of the measuring system; data format of the procedure for assessing the accuracy of the components of the measuring system; upon request, the measurement initiates a generated procedure for assessing the accuracy of the components of the measuring system; and at the end of the procedure for assessing the accuracy of the components of the measuring system, the following actions are performed: the received data is processed in accordance with the accepted rules; transfer the received data to the software algorithm for measuring the measuring system; based on the data obtained after the procedure for assessing the accuracy of the components of the measuring system, a new measurement algorithm is formed; and at the required moment in real time, remotely configure the software and hardware configuration of the monitoring means to receive and process additional information necessary to solve a new set of tasks for intelligent processing of heterogeneous data on the parameters of a controlled dynamic system; in the processing and control center, a readiness signal is generated for the next stage of measuring the state of the dynamic system; continuously during the measurement of physical parameters, derived parameters are calculated based on those measured according to specified rules, and in such a way that the values of all measured parameters and all derived parameters are tied to the same time points.

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