RU2698246C1 - Multi-level system for navigation and information support of executive authorities and method for formation and/or use thereof - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to a navigation-information support system. System comprises standard monitoring centers at three hierarchical control levels, each level including a standard monitoring center, and hardware-software means of each standard monitoring center are constructed using service-oriented infrastructure (SOA), common information model (CIM), web monitoring and control technologies (WBEM) and include interconnected integration subsystem, monitored objects monitoring subsystem, spatial data management system, communication and information interaction means.EFFECT: technical result consists in automation of navigation-information support.1 cl, 1 dwg

Description

The proposed group of inventions relates to decision support systems and information and analytical support.

As the closest analogue of the group of inventions, the system of automated monitoring of the state of potentially dangerous objects of the Russian Federation was selected in the interests of providing protection against technological, natural and terrorist threats, proposed in the patent for invention RU 2 296 421, NII KS - a branch of the State Scientific and Production Center named after M.V. Khrunicheva, published 2007. RU 2 296 421 proposes an information system that includes a coordination and analytical center, federal, regional and territorial information and analytical centers. The coordination and analytical center, federal, regional and territorial information and analytical centers are based on the principles of a multi-level hierarchical management system with automatic and automated modes of processing, archiving and providing state authorities with information about the status of potentially dangerous objects. That is, a multilevel system of navigation and information support is proposed, including a set of monitoring centers at three hierarchical levels of management. In turn, the present invention is aimed at further improving information systems of this type and will offer a multilevel system of navigation and information support, which can be used to solve almost any list of tasks of information support of public administration.

In the proposed multilevel system of navigation and information support, which includes a set of monitoring centers at three hierarchical levels of management, typical monitoring centers are used at least at three hierarchical levels of management, depending on the hierarchy of management in a given country. Each level includes at least one typical monitoring center, that is, a unified hardware-software complex, which is the basis of each hierarchical control level. The hardware and software of each typical monitoring center are built using a service-oriented infrastructure (SOA), a common information model (CIM), web-based monitoring and control technologies (WBEM) and include an integration subsystem, a monitoring subsystem for monitoring objects, a spatial data management system, means of communication and information interaction. That is, an information-logical system based on standard monitoring centers located in integration and subordination with each other, with the possibility of contact with external objects, is proposed. The method of forming and / or applying the proposed multi-level navigation and information support system involves deploying and / or connecting at least three hierarchical control levels of the typical monitoring centers described above.

The proposed system is illustrated by the structural and functional diagram of a typical monitoring center.

To expand the technological capabilities of information systems in solving almost any list of tasks of public administration information support, an information and navigation support system is proposed, consisting of standard monitoring centers located at hierarchical management levels, in each of which hardware-software complexes of a special purpose are allocated: integration subsystem 1 with external means, including typical monitoring centers of another level; monitoring subsystem of controlled objects 2; spatial data management system 3 with the display of monitoring results on electronic maps; communication and information interaction 4 (GSM modem, VHF, trunking, satellite communications, Internet access, etc.). Each of the typical monitoring centers provides (adjusted for existing competencies in the management hierarchy) the collection, analysis and display of information about stationary and mobile controlled objects using satellite navigation (GLONASS / GPS / GALILEO / BEIDOU) and communications; interaction with a system of high-precision determination of ephemeris and time corrections; the formation of cartographic reference information - geographic information systems; collection, analysis and display of distress signal information from controlled objects using the COSPAS-SARSAT international satellite search and rescue system.

The means of typical monitoring centers, as well as the subsystems allocated as part of the centers, are a combination of computer tools for processing data and generating commands: servers, personal computers, etc .; user and gateway tools, managed by specialists with the necessary knowledge and experience from their workplaces and interacting with the information and computing resources of these tools, that is, they are human-machine systems - systems that combine human activity and the functioning of an object of technology, based on interaction in accordance with the information received with the control object and the machine through the controls, the technical features of which will be be shared through their functional purpose. These hardware and software systems are built on the architecture of computer systems based on a service-oriented infrastructure (SOA), as well as for monitoring and managing moving objects, a common information model (CIM) and web-based monitoring and control technologies (WBEM). Using a service-oriented infrastructure (SOA) provides a database monitoring process at a typical monitoring center at the levels of the database server, application server and user.

Integration subsystem 1 provides the integration of multiple applications with each other in the isolation mode of changes at the integration point of each application from the integration points of other applications (application integration points are represented as web services); messaging is provided on its own bus, the formation and use of routing rules, including changing routes and filtering messages based on their contents, storage and use of configuration information. As part of the integration subsystem, it is possible to distinguish the following subsystems of the second level: configuration storage subsystem; subsystem for managing business rules, including loading rules for execution by bus; messaging bus a set of integration drivers that ensures the interaction of the message bus with external integrable systems, both using standard interaction interfaces and using special interfaces implemented in external systems.

The monitoring subsystem for monitoring objects 2 includes at least an asynchronous telematic server, a coordinate-time support server, an application server, a spatial data management system server, a router, and a database server. Data collection from navigation receivers is provided; collection of readings of sensors connected to navigation receivers; processing, storage, management (creation, storage, editing) and the issuance (display) of query results from an array of navigation data; management of user rights to access information and / or system functions. Telematics data from the controlled equipment are sent simultaneously to the telematics server (interacts with the database server based on the relational data model) and the application server (interacts with the database server based on the object-oriented data model) for simultaneous processing and sending to the operator’s workstation and means of data storage.

The spatial data management system 3 includes a spatial database, a rasterizer (rasterization of vector maps upon requests from user applications, raster images are automatically generated when processing user requests and saved for later use without new generation), application server, search system, subsystem for interacting with external components (provides access to vector data to system functions and raster images of terrain maps via SOAP and REST interfaces, to tiles with raster images of maps through the WMS TS interface.), administrator's workstation. The application server provides geometric actions with spatial objects, that is, determining intersections, associations, occurrences of objects, calculating geometric characteristics (lengths, angles, areas, distances between objects), finding nearby objects, sorting by distance, etc., as well as a set construction of optimal routes, address search, determination of addresses of objects, operations of picket addressing, etc. In addition, the application server provides differentiation of access rights to information, the right to confirm changes and restrictions associated with spatial data. The spatial data base is formed on the basis of a relational DBMS equipped with spatial extensions that provide geometric calculations in the process of accessing data, implementation of spatial indices and tools for sorting by spatial characteristics of objects, transformation of coordinate systems of object descriptions under conditions of multiple coordinate systems for data.

The work of typical monitoring centers at various hierarchical levels of the navigation information system can be shown by the example of a typical monitoring center of the upper (federal) level - TTsM-F, as well as the example of a typical monitoring center of regional or municipal levels - TTsM-R.

TTsM-F or a set of equivalent top-level centers is a basic element in the deployment of a multi-level navigation and information system; for the interaction of TTsM-F with executive authorities, a cloud environment organized using the Internet can be used. TTsM-F provides with the collection, analysis and display of information about controlled objects to solve the tasks of managing executive bodies using satellite navigation (GLONASS / GPS / GALILEO / BEIDOU); Integration of the center with a system of high-precision determination of ephemeris and time corrections was provided; the collection of information about those in distress was ensured according to the data of the international satellite search and rescue system COSPAS-SARSAT with the issuance of the necessary orders. Also, the TCM-F manages the operation of on-board and individual navigation and information systems, determines the user states of the monitored objects (presence on the route or on the territory), forms and controls the route of the controlled object, including aircraft, including traffic parameters and technical condition. TCM-F manages the sharing of access to information about controlled objects at the user level. Navigation and monitoring information from a typical monitoring center of the lower levels - TTsM-R enters the TTsM-F through the integration subsystem. Similarly, the necessary information received from sources at the top level of government is transmitted to the TCM-R.

Many of the TCM-R provide the deployment of a multi-level navigation and information system at the regional and local (municipal) levels and the necessary information support of the relevant executive authorities. TTsM-R receive navigation information through standard monitoring centers of the upper (federal) level; COSPAS-SARSAT international satellite search and rescue information; provides with the collection, analysis and display of monitoring and management information using satellite navigation (GLONASS / GPS / GALILEO / BEIDOU); generate and transmit emergency messages; manage the work of onboard and individual navigation and information systems; determine the user states of the controlled objects (presence on the route or on the territory), form and control the route of movement of the controlled object, including aircraft, including traffic parameters and technical condition; provide separation of access to information about controlled objects at the user level. As mentioned above, the TTsM-R transmits the necessary information to the TTsM-F, and also exchanges information with typical monitoring centers of the municipal (regional), etc. levels.

Claims (7)

Multilevel system of navigation and information support, including a set of monitoring centers at three hierarchical levels of management, characterized in that they use typical monitoring centers at least three hierarchical levels of management, and each level includes at least one typical monitoring center, and the hardware and software of each typical monitoring center are built using service-oriented infrastructure (SOA), a common information model (CIM), web-based monitoring and control technologies (WBEM) and include interconnected integration subsystem, the monitoring subsystem of controlled objects, the spatial data management system, communications and information interaction, while the integration subsystem includes configuration storage subsystem interconnected, the business rules management subsystem, including loading the rules for execution by the bus, the message transfer bus, a set of integration drivers that ensures the interaction of the message transfer bus with external integrated systems, the monitoring subsystem of controlled objects provides data collection from navigation receivers and includes interconnected asynchronous telematic server, coordinate-time support server, application server, spatial data management system server, router, database server, the spatial data management system includes an interconnected spatial data base, a rasterizer, an application server, a search engine, a subsystem for interacting with external components, and an automated workstation for the administrator.

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