System for situation-analytical centres of organisational system

FIELD: physics; control.

SUBSTANCE: invention relates to a system of situation-analytical centres of an organisational system. The system comprises a telecommunication network, a control centre, situation-analytical centres, control points of departments of the organisational system, two-way communication means, means of monitoring surveillance objects, which affect the state of operations of the organisational system, and enables automated generation of scenarios using computer systems of the control centre, situation-analytical centres and control points of departments of the organisational system, storage of data on the scenarios in a system for storing data for auditing operations of the organisational system, which is part of the control centre, transmission of data on the scenarios via equipment interfaces of the control centre, situation-analytical centres, control points of departments of the organisational system and over the telecommunication network to computer networks of the control centre, situation-analytical centres and control points of departments of the organisational system, to video systems and a computer for setting up the video system of the control centre and situation-analytical centres, to multimedia screens of the control centre, situation-analytical centres and control points of departments of the organisational system to make decisions based on the generated scenarios.

EFFECT: high efficiency of the decision-making process owing to automated generation of scenarios for solving problem situations.

21 cl, 1 tbl, 30 dwg

 

The present technical solution relates to the management of organizational systems, subject area systems are decision support.

Known technical solution [1] EN 57481 U1 contains the receiving module records the standard plans, the receiving module user's requests, the receiving module records plans from the database server, the module selection reference recording address, the module selection reference read address, the module selection the source address of the request, the module forming the actual writing addresses two adder module address generation time period, the module address generation database management module recording and reading of data and the extension data output.

The disadvantage of this technical solution is the lack of opportunities for automated support for simultaneous production plans permit several problematic situations that arise in a complex organizational system and related to the various activities of the company, or plan resolution number of problematic situations caused one problem with different degrees of influence on the activities of the organizational system.

Known technical solution [2] RU 57919 U1 contains a Bank of data from separate databases, rendering a decision, the storage device reference situations, m is the module of choice of methods of influence on the implementation of the decision, the analysis module of decisions, the module forming strategic goals and objectives, forecasting module, the block selection methods of influence on the implementation of the decision. This data Bank contains information on natural resources and state property to other entities that affect the socio-economic development of the state.

The disadvantage of this technical solution is the limited use of display devices provided to the decision maker, computer monitors and printers. This circumstance complicates the operational production of collective decision-making.

Known technical solution [3] EN 105031 U1 contains the unit of the measurement environment of the object, the block information models, the unit of information support unit result, the measuring unit environment analyst, block Protocol support and the block of the object-system integration.

The disadvantage of this technical solution is the lack of information models, taking into account the organizational units of the system, to ensure the activity of which is the technical solution, by type of activity, taking into account the degree of influence on these kinds of problematic situations. This circumstance requires additional, is not the subject area of this technical solution, analytical work on the development objective decision and resolution of problem situations.

Known technical solution [4] EN 28927 U1 contains the center of objective control, controls placed on the objects of observation, and means for two-way communication, connecting the control means with the interface equipment of the center of objective control, the Central objective control contains, at least, a work room and situational room, while the equipment of the working of the hall contains at least one computer, at least one multimedia projector with screen, at least one wall-mounted screen, connected with the possibility of visualization of incoming information, the equipment situation room contains individual screen connected to the equipment of the working of the hall, and means for two-way communication with the working room, the control means include at least a processing unit digital telemetry information, and/or block co-ordinates of the object of observation, and/or controlled area of the object of observation, the block specifying the actual time control status of the monitored object, and the block of the video image of the monitoring object.

The disadvantage of this technical solution is the limitation of its automated capabilities to support the OI two levels of management - on the first level are resolved critical problems based on known techniques, and the second level - the critical issues that require elaboration of the concept of the elimination of the problem. The personnel and equipment that are designed to work on the first level management and specialists and their equipment is designed to operate at the second level of control, are placed in the adjacent room - operating room and in the situation room. This circumstance does not allow to efficiently resolve the problematic situation with respect to geographically distributed over a large space units organizational systems, support activities which provides this solution.

There are currently information management technical system for various purposes, aimed at improving the effectiveness of management processes in the organizational systems of various types. This automates almost all the activities of the organizational systems of enterprises, organizations, corporations and government agencies. One of the most acute problems that need to be addressed when establishing and functioning of these systems is the continuous growth of data volumes required for various tasks. How to ensure effective use is the use of all available technical capabilities and accumulated information resources? How to quickly and accurately solve problems through the use of integrated information resource? Similar questions arise quite a lot, all of them connected with the search of the necessary information, its analysis, elaboration of scenarios for decision-making, selection of the most effective of them with regard to risk assessment and a decision on its implementation, provision of conditions for the effective and timely implementation of solutions. For answers to these and other similar issues related to improving the efficiency of management processes, are increasingly offering technical solutions such as "situation center", "center", "system of objective control of the situation", "automated system for decision support", "information-analytical system of decision-makers and others that can be attributed to a single engineering system situational tanks organizational systems. System situational tanks organizational systems are the concentration of modern information technologies for automated support for management of overall organizational systems of ministries and departments, corporations, companies, banks and, in particular, in the management activities of organizational units systems deployed in both stationary and mobile objects.

A common disadvantage of the known technical solutions [1-4] in the field of engineering systems situational tanks organizational systems is the lack of automated support activities organizational system while development plans permissions several problematic situations related to the various activities of its subsidiaries, and/or plan resolution number of problematic situations caused one problem, with varying degrees of influence on the activities of the organizational units of the system.

Technical task, which directed the present technical solution, which was made in view of the above, is the proposal of a new and improved system situational tanks organizational system that can reduce the time resolution of complex problem situations.

Technical solution - system situational tanks organizational system (SSAS OS) contains the control center (CC), telecommunications network, R situational analysis centers (SAC), M control units organizational systems (CP PIC), K controls placed in the K objects of observation in a controlled environment and/or outside the objects of observation, with the possibility nablyudeniya them, K means two-way wired and/or wireless communication. The objects of observation are such entities, tangible and intangible objects of the organizational system and the external environment that affect the operation status of the organizational system.

Controls include at least a processing unit digital telemetry information, and/or block co-ordinates of the object of observation, and/or controlled area of the object of observation, the block specifying the actual time monitoring of the condition of the monitored object, a block of the video image of the monitoring object, the blocks forming the data on indicators of observed objects, represented by the dimensionless numbers and/or units of measurement.

The telecommunications network is connected with the equipment ZU, equipment SATS, equipment, Poo PIC and information networks external organizational systems.

Means of two-way communication is connected, on the one hand, with means of control over the objects of observation in a controlled environment and, on the other hand, with equipment ZU, or equipment SATS, or equipment Poo PIC.

The situational analysis centers organizational system is designed in such a way that it generates, are stored and displayed on monitors in the computer is in, and/or on the screens of the media and/or on the video screens the following process data:

data D about the desired state of activity of the organizational system as a whole (target activities organizational systems);

data Dnabout the desired state of the n-th activity of the organizational system, n=1, 2, ..., N;

data αnon the assigned priority for the n-th activity organizational systems;

data Snmabout the desired state of the n-th activity in the m-th unit of the organizational system, m=1, 2, ..., M;

data βnmthe priority of the n-th activity in the m-th unit of the organizational system;

data Snmare formed as follows:

- Vnmkdata about the desired state of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, k=1, 2, ..., K;

data γnmkthe priority of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system;

dataVklabout the required l-th indicator of the k-th object of observation, l=1, 2, ..., L_ (Lkl)where L_kLklthe number of indicators that are used to describe the state of the k-th object of observation;

dataVklrepresented by dimensionless numbers, time, metric, weight, cost and other units of measurement; the information about the required performance monitoring object includes information on required indicators of physical, logical, information, spatial, structural, organizational and other types of coupling of the k-th monitoring object with other objects of observation;

dataμklthe priority of the l-th indicator of the k-th object of observation;

dataVnmklabout the required l-th indicator of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system;

data Vnmklare formed as follows:Vnmkl=Vklif the k-th object of observation affects the n-th type of activity carried out in the m-th division organizational systems;andVnmk1=0,

otherwise

data Vnmkare formed as follows:

The situational analysis centers organizational system is designed so that it controls the measurement of performance monitoring objects, convert them to digital form and formation dataVnmk*lon the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, where l=1, 2, ..., L_k; k=1, 2, ..., K; n=1, 2, ..., N; m=1, 2, ..., M DataVnmk *lrepresented by dimensionless numbers, time, metric, weight, cost, and other units. After the formation and preservation of dataVnmk*lare formed, stored and displayed on the screen the following information:

dataΔVnmk*lthe absolute value of the deviation dataV*nmklon the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, from dataVnmklabout the required l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems:ΔVnmk*l= |Vnmkl-Vnmk*l|;

dataVnmk*about the actual condition of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, with

dataSnm*on the actual state of the n-th activity in the m-th unit of the organizational system, with

dataΔSnm*on the actual indicator of the effectiveness of the n-th activity in the m-th unit of the organizational system, withΔSnm*=Snm*/Snm;

data ΔSnm-Crete.the performance data GIP activity, implemented in the m-th unit of the organizational system, decrease, compared with which, the actual indicator indicates the existence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action for its elimination;

data ΔSnm-extrathe performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual value means the possibility of threats to the n-th activity in the m-th unit of the organizational system and the need to take action to prevent the emergence of threats.

data Dnabout the desired state of the n-th activity of the organizational system, with

data D*nabout the actual condition of the n-th activity of the organizational system, with

data ∆ D*non the actual indicator of the effectiveness of the n-th activity of the organizational system, with ∆ D*n=D*n/Dn;

data ∆ Dn-Crete.critical indicator of the effectiveness of the n-th activity of the organizational system, decrease, compared with which, the actual indicator indicates the existence of a threat to this activity the organizational structure established the first system and the need to take action for its elimination;

data ∆ Dn-supplementaryon valid indicator of the effectiveness of the n-th activity of the organizational system, decrease, compared with which, the actual value means the possibility of threats to this type of activity organizational systems and the need to take action to prevent the emergence of threats;

data D about the desired condition of operation of the organizational system as a whole, while

data D* about the actual state of the activities of the organizational system as a whole, while

data ∆ D* actual performance indicators of the organizational system as a whole, while ∆ D*=D*/D;

data ∆ DCrete.critical indicator of the effectiveness of the organizational system as a whole, reduced, compared with which, the actual value ∆ D* effectiveness of the organizational system as a whole means the existence of a threat to the activities of the organizational system as a whole and the need to take action for its elimination;

data ∆ Dsupplementaryon valid indicator of the effectiveness of the organizational system as a whole, reduced, compared with which, the actual value ∆ D* effectiveness of the organizational system as a whole means in which the possibility of occurrence of the risk to organizational systems in General and the need to take action to prevent the emergence of threats.

The situational analysis centers organizational system is designed in such a way that it generates, are stored and displayed on the screens of the following scenarios:

data QCrete.on the number of critical scenarios, designed to support the decision to eliminate the risk to the organizational system as a whole;

data WCrete.on many of the critical scenarios that are designed to support the decision to eliminate the risk to the organizational system as a whole under the condition 0≤ ∆ D*< ∆ DCrete.whileWKpandt.={WKpandt.1andlandWKpandt.2...andlandWKpandt.QKpandt.},

whereWKpandt.q1data q1-Ohm critical scenarios designed the La support the decision to eliminate the risk to the organizational system as a whole, where q1 - data priority critical scenario, q1=1, 2, ..., QCrete.when this condition is metP(WKpandt.q1)P(WKpandt.q1-1),q1=1QKpandt.P(WKpandt.q1)=1,

whereP(WKpandt.q1)andP(WKpandt.q1-1)accordingly, the data about the predicted probabilities for the selection of the critical scriptWKR/mi> andt.q1and critical scriptWKpandt.q1-1,P(WKpandt.0)=0;

data Qbefore.the number of warning scenarios that are designed to support decision-making for the prevention of threats to the activities of the organizational system as a whole;

data Wbefore.of the many warning scenarios that are designed to support decision-making for the prevention of threats to the activities of the organizational system as a whole, provided ∆ DCrete.≤ ∆ D*< ∆ DsupplementarywhileWpped.={Wpped.1andlandWpped.2...andlandWpped.Qp ped.},

whereWpped.q2data q2-Ohm warning scenarios, q2 - data priority this scenario, q2=1, 2, ...,Qbefore.when this condition is metP(Wpped.q2)P(Wpped.q2-1),q2=1Qpped.P(Wpped.q2)=1whereP(Wpped.q2)andP(Wp ped.q2-1)accordingly, the data about the predicted probabilities for selecting the warning scriptWpped.q2and the warning scriptWpped.q2-1,P(Wpped.0)=0;

data Qplan.the number of planned scenarios that are designed to support decision making to improve the efficiency of the organizational system as a whole; data Wplan.on many planning scenarios that are designed to support decision making to improve the efficiency of the organizational system as a whole, provided ∆ Dsupplementary≤ ∆ D*<1, withWplandn.={Wplandn.1 andlandWplandn.2...andlandWplandn.Qplandn.}whereWplandn.q3data q3-Ohm planned scenarios, q3 - data priority this scenario, q3=1, 2, ..., Qplan.when this condition is metP(Wplandn.q3)P(Wplandn.q3-1),q3=1Qplandn.P(Wplandn.q3)=1whereandP(Wplandn.q3-1)accordingly, the data of the predicted probabilities to select a scheduled scriptWplandn.q3and planned scriptWplandn.3-1,P(Wplandn.0)=0;

data Un-Crete.the number of critical scenarios designed to support the decision to eliminate threats to the n-th activity organizational systems;

dataWKpandt.non many critical he is of the Aryans, designed to support the decision to eliminate threats to the n-th activity organizational systems provided0ΔDn*<ΔDn-Kpandt.whileWKpandt.n={WKpandt.n1andlandWKpandt.n2...andlandWKpandt.nUn-Kpandt.}whereWKpandt.nu1data about u1-Ohm critical scenarios, designed to support the decision to eliminate threats to the n-th activity of the organizational system, where u1 - data priority critical scenario, u1=1, 2, ..., Un-Crete.that is the Rea this is the condition P(WKpandt.nu1)P(WKpandt.n(u1-1)),u1=1Un-Kpandt.P(WKpandt.nu1)=1whereP(WKpandt.nu1)andP(WKpandt.n(u1-1))accordingly, the data about the predicted probabilities for the selection of the critical scriptWKpand t.nu1and critical scenario,WKpandt.n(u1-1),P(WKpandt.n0)=0;

data Un-before.the number of warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity organizational systems;

dataWpped.nof the many warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity organizational systems providedΔDn-Kpandt.ΔDn*<ΔDn-daboutp.while Wpped.n={Wpped.n1andlandWpped.n2...andlandWpped.nUn-pped.}whereWpped.nu2data about u2-Ohm warning scenarios, designed to support the adopted solution for the prevention of threats to the n-th activity of the organizational system, where u2 - data priority warning script, u2=1, 2, ..., Un-before.when this condition is metP(Wpped.nu2)P(Wpped.n(u2-1) ),u2=1Un-pped.P(Wpped.nu2)=1whereP(Wpped.nu2)andP(Wpped.n(u2-1))accordingly, the data about the predicted probabilities for selecting the warning scriptWpped.nu2and the warning scriptWpped.n(u2-1) ,P(Wpped.n0)=0;

data Un-plan.the number of planned scenarios that are designed to support decision-making for improving the efficiency of the n-th activity organizational systems;

dataWplandn.non many planning scenarios that are designed to support decision-making for improving the efficiency of the n-th activity organizational systems providedΔDn-daboutp.ΔDn*<1whileWplandn.n={Wplandn.n1andlandWplandn.n2...andlandWp landn.nUn-plandn.}whereWplandn.nu3data u3-Ohm planned scenarios, designed to support decision-making for improving the efficiency of the n-th activity of the organizational system, where u3-data priority planned scenario, u3=1, 2,..., Un-plan.when this condition is metP(Wplandn.nu3)P(Wplandn.n(u3-1)),u3=1Un-plandn.P(Wplandn.nu3)=1 whereP(Wplandn.nu3)andP(Wplandn.n(u3-1))accordingly, the data about the predicted probabilities for selecting the warning scriptWplandn.nu3and the warning scriptWplandn.n(u3-1),P(Wplandn.n0)=0;

data Ynm-Crete.the number of critical scenarios, designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system;

data WKpandt.nmon many of the critical scenarios that are designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system provided0ΔSnm*<ΔSnm-Kpandt.whileWKpandt.nm={WKpandt.nm1andlandWKpandt.nm2...andlandWKpandt.nmYnm-Kpandt.}whereWKpandt.nmy1img src="http://img.russianpatents.com/1185/11853243-s.jpg" height="8" width="13" /> data y1-Ohm critical scenarios, designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system, where y1 - data priority critical scenario, y1=1, 2, ..., Ynm-Crete.when this condition is metP(WKpandt.nmy1)P(WKpandt.nm(y1-1)),y1=1Unm-Kpandt.P(WKpandt.nmy1)=1whereP(WKpandt.nmy1)andP(W Kpandt.nm(y1-1))accordingly, the data about the predicted probabilities for the selection of the critical scriptWKpandt.nmy1and critical scriptWKpandt.nm(y1-1),P(WKpandt.nm0)=0;

data Ynm-before.the number of warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity in the m-th unit of the organizational system;

dataWpped.nmof the many warning scenarios that are designed to support p is innate solutions to prevent threats to the n-th activity in the m-th unit of the organizational system provided ΔSnm-Kpandt.ΔSnm*<ΔSnm-daboutp.,

when thisWpped.nm={WKpandt.nm1andlandWKpandt.nm2...andlandWKpandt.nmYnm-Kpandt.}whereWpped.nmy2data y2-Ohm warning scenarios, designed to support decision-making for the prevention of threats to the n-th activity in the m-th unit of the organizational system, where y2 - data priority warning the first scenario, y2=1, 2,..., Ynm-before.when this condition is metP(Wpped.nmy2)P(Wpped.nm(y2-1)),y2=1Unm-pped.P(Wpped.nmy2)=1whereP(Wpped.nmy2)andP(Wpped.nm(y2-1))accordingly, data on projected likely the positions to select the warning script Wpped.nmy2and the warning scriptWpped.nm(y2-1),P(Wpped.nm0)=0;

data Ynm-plan.the number of planned scenarios that are designed to support decision-making for improving the efficiency of the n-th activity in the m-th unit of the organizational system;

dataWplandn.nmon many planning scenarios that are designed to support decision-making for improving the activity of the n-th activity in the m-th unit of the organizational system providedΔSnm-daboutp.ΔSnm*< 1whileWplandn.nm={Wplandn.nm1andlandWplandn.nm2...andlandWplandn.nmYnm-plandn.}whereWplandn.nuy3data y3-Ohm planned scenarios, designed to support decision-making for improving the efficiency of the n-th activity in the m-th unit of the organizational system, where y3 - data priority planned scenario, y3=1, 2, ..., Ynm-plan.when this condition is metP(Wplandn.nmy3)P(Wmrow> plandn.nm(y3-1)),y3=1Unm-plandn.P(Wplandn.nmy3)=1whereP(Wplandn.nmy3)andP(Wplandn.nm(y3-1))accordingly, the data of the predicted probabilities to select a scheduled scriptWplandn.nmy3and planned script Wplandn.nm(y3-1),P(Wplandn.nm0)=0;

The above process data stored in the data storage system audit of the analytical center in the control center, SAC OS. Periodically audited, updated and used during operation of SSAC OS in the interests of the CC, SATS and Poo PIC.

The essence of the technical solution is illustrated by drawings.

Below is a list of figures.

Fig.1 is a block diagram of a system situational tanks organizational system (SSAS OS).

Fig.2 is a block diagram of the control center SSAC OS.

Fig.3 is a Structural diagram of the situational analysis center, SAC OS.

Fig.4 is a block diagram of the control unit of the organizational system SSAC OS.

Fig.5 - the Algorithm works by SSAC OS for managing the resolution of problems in the controlled area (example 1).

Fig.6 - Correlation of scenarios and performance indicators for the CC, SSAC OS (example 2).

Fig.7 - Correlation of scenarios and indicators of effective the particular for SATS, SSAC OS (example 3).

Fig.8 - Correlation of scenarios and performance indicators for PU after SSAC OS (example 4).

Fig.9 - data Paths between computing complexes HQ and SATS (example 5).

Fig.10 - data Paths between computing complexes HQ PIC and PU (example 6).

Fig.11 - data Paths between the computing complex ZU and information networks external organizational systems (example 7).

Fig.12 - data Paths with quantifiable indicators between computational complex ZU and control over the objects of observation (example 8).

Fig.13 - data Paths with videos between computational complex ZU and control over the objects of observation (example 9).

Fig.14 - data Paths with videos between computer system and video system situational rooms (example 10).

Fig.15 is a Graph-scheme of algorithm 1 (GAW 1). Forming a data blockVnmkl- about the required l-th indicator of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, where l=1, 2, ..., Lk; n=1, 2, ..., N; m=1, 2, ..., M; k=1, 2, ..., K (example 11).

Fig.16 is a Graph-scheme of algorithm 2 (GAW 2). Fo is the formation of block data V nmk- about the desired state of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, where n=1, 2, ..., N; m=1, 2, ..., M; k=1, 2, ..., K (example 12).

Fig.17 is a Graph-scheme of algorithm 3 (GSA 3). Forming a data block Snm- about the desired state of the n-th activity in the m-th unit of the organizational system, n=1, 2, ..., N; m=1, 2, ..., M (example 13).

Fig.18 is a Graph-scheme of algorithm 4 (GSA 4). The formation of the block of data Dn- o the desired state of the n-type activities of the organizational system, where n=1, 2, ..., N (example 14).

Fig.19 is a Graph-scheme of algorithm 5 (5 GSA). Forming a data block D - o the desired condition of operation of the organizational system as a whole (example 15).

Fig.20 is a Graph-scheme of algorithm 6 (GSA 6). The formation of the data about the absolute value of the deviation dataVnmk*lthe actual l index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, the required dataVnmkl(example 16).

Fig.21 is a Structural scheme is and the data storage system, technology-based Network Attached Storage (example 17).

Fig.22 is a diagram of the configuration management process (example 18).

Fig.23 is a Diagram of scanning (example 19).

Fig.24 is a diagram of the inventory process (example 20).

Fig.25 is a Device for collecting information on and.with. SU 1742834.

Fig.26 - Multi-channel digital communication system A. with. SU 1800631 A1.

Fig.27 is a Device for the exchange of information on and.with. SU 1821802 A1.

Fig.28 is a diagram of the relative position of a moving object and a stationary object, indicating a possible change of direction of a moving object.

Fig.29 is a timing chart by changing the duration of the transmitted signals when deleting a moving object from a stationary object.

Fig.30 is a timing chart by changing the duration of the transmitted signals at the approach of a moving object to a stationary object.

Below is a brief description of the drawings with explanations of what they depict.

In Fig.1 shows a block diagram of a system situational tanks organizational system, where 1 is the control center (CC); 2 telecommunication network; 3.1-3.R - situational-analysis centers (SAC); 4.1-4.M - control units of the organizational system (PU POS); 5.1.1-5.1.K1objects of observation in a controlled environment within the area of liability is the liability of the CC; 5.1.1.1 - 5.1.K1.1 - means of control over the objects of observation in a controlled environment within the area of responsibility of the CC; 5.3.r.1 - 5.3.r.K3robjects of observation in a controlled environment outside the area of responsibility SATS, r=1, 2, ..., R; 5.3.r.1.1 - 5.3.r.K3.r.1 - means of control over the objects of observation in a controlled environment within the area of responsibility SATS; 5.4.m.1-5.4.m.K4mobjects of observation in a controlled environment outside the area of responsibility Poo PIC, m=1, 2, ..., M; 5.4.m.1.1-5.4.m.K4m.1 - means of control over the objects of observation in a controlled environment within the area of responsibility PU POS; 6.1.1-6.1.K1- bilateral funds wired and/or wireless communication area of responsibility TSU; 6.3.r.1-6.3.r.K3r- bilateral funds wired and/or wireless communication area of responsibility SATS; 6.4.m.1-6.4.m.K4m- bilateral funds wired and/or wireless communication responsibilities PU POS; 7.1-7.N - information network external organizational systems. When you do this:

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first the inputs and outputs (1-1, ..., 1-K1the equipment of the control center 1 is connected respectively with the first outputs and inputs appropriate means two-way communication 6.1.1, ..., 6.1.K1, second inputs and outputs which are connected respectively with first the mi outputs and inputs of appropriate controls 5.1.1.1, ..., 5.1.K1.1 monitoring objects in a controlled environment 5.1.1, ...,5.1 K1; the second input and output equipment control center 1 is connected respectively with the first exit and entrance of the telecommunication network 2;

the second inputs and outputs (2-1, ..., 2-R) telecommunications network 2 are connected respectively with the first outputs and inputs equipment appropriate Satz 3.1, ..., 3.R; third inputs and outputs (3-1, ..., 3) of the telecommunication network 2 are connected respectively with the first outputs and inputs equipment appropriate PU PIC 4.1, ..., 4.M; fourth inputs and outputs (4-1, ..., 4-H) of the telecommunications network 2 are connected respectively to the outputs and inputs of the respective information networks external organizational systems 7-1, ..., 7-H;

the second inputs and outputs (2-1, ..., 2-K3,rthe equipment of each Satz 3.1, ..., 3.r (r=1, ..., R) is connected to the first outputs and inputs appropriate means two-way communication 6.3.r.1, ..., 6.3.r.K3.r, second inputs and outputs which are connected respectively with the first outputs and inputs of appropriate controls 5.3.r.1.1, ..., 5.3.r.K3,r.1 monitoring objects in a controlled environment 5.3.r.1, ..., 5.3.r.K3,r;

the second inputs and outputs (2-1, ..., 2-K4,mthe equipment of each PU PIC 4.1, ..., 4.m (m=1, ..., M) are connected each with the first outputs and inputs appropriate means of dfugstore is her connection 6.4.m.1, ..., 6.4.m.K4.m, second inputs and outputs which are connected respectively with the first outputs and inputs of appropriate controls 5.4.m.1.1, ..., 5.4.m.K4,m.1 monitoring objects in a controlled environment 5.4.m.1, ..., 5.4.m.K4,m.

In Fig.2 shows the block diagram of the control center 1, the equipment contains equipment analytical center 1.1 and equipment objective control 1.2. Equipment analytical center 1.1 contains computer system 1.1.1 and storage system audits of organizational systems (DSS AD OS) 1.1.2. Equipment Central objective control 1.2 includes: hardware interface 1.2.1, equipment working hall 1.2.2 and equipment situation room 1.2.3. Equipment working hall 1.2.2 contains a computer network 1.2.2.1 and multimedia projector with screen 1.2.2.2. The equipment situation room 1.2.3 contains video system 1.2.3.1 and computer settings video 1.2.3.2. When you do this:

- input and output of computer system 1.1.1, the input and output storage HELL OS are connected respectively with the first exit and entrance, the second exit and entrance hardware interface 1.2.1;

- third, the fourth, fifth and sixth inputs and outputs of the hardware interface 1.2.1 connected respectively with the output and the input of the computer network 1.2.2.1, with exit and entrance the player is dia-projector with screen 1.2.2.2, with the first exit and entrance video 1.2.3.1, with the first output and the input of the computer settings video 1.2.3.2, the second input and the output of which is connected respectively with the second exit and entrance video 1.2.3.1;

- seventh input, output and inputs, the outputs from the eighth group of inputs and outputs (8-1, ..., 8-K1) hardware interface 1.2.1 are, respectively, the second input, output (2-d input/output equipment control center 1 in Fig.1) and the inputs and outputs of the first group of inputs and outputs (inputs/outputs 1-1, ..., 1-K1equipment of the control center 1 in Fig.1) equipment of the control center 1 and respectively connected with the first output, the input of the telecommunication network 2 and the first outputs, inputs appropriate means two-way communication 6.1.1-6.1.K1.

In Fig.3 shows a structural diagram of the situational analysis center (SAC) 3.r (r=1, ..., R), equipment contains equipment analytical center 3.r.1 and the equipment center of objective control 3.r.2. Equipment analytical center 3.r.1 shows a computer system 3.r.1.1. Equipment Central objective control 3.r.2 includes: a hardware interface 3.r.2.1, the equipment working hall 3.r.2.2 and the equipment case room 3.r.2.3. Equipment working hall 3.r.2.2 includes a computer network 3.r.2.2.1 and multimedia project is a torus with screen 3.r.2.2.2. Equipment case room 3.r.2.3 includes a video system 3.r.2.3.1 and the computer configuration display 3.r.2.3.2. When you do this:

- input and output of computer system 3.r.1.1 are connected respectively with the third output and input hardware interface 3.r.2.1, the first input and output which are, respectively, the first input / output equipment 3 SATS.r and are connected respectively with the second (2-r) exit and entrance of the telecommunication network 2;

the second inputs and outputs (2-1, ..., 2-K3.r) hardware interface 3.r.2.1 are, respectively, the second inputs and outputs of the equipment 3 SATS.r and are connected respectively with the first outputs and inputs appropriate means two-way communication 6.3.r.1-6.3.r.K3.r;

- the fourth, fifth, sixth, seventh inputs and outputs of the hardware interface 3.r.2.1 are connected respectively with the output and the input of the computer network 3.r.2.2.1, with the exit and entrance of the multimedia projector and screen 3.r.2.2.2, with the first exit and entrance video 3.r.2.3.1, with the first output and the input of the computer configuration display 3.r.2.3.2;

the second entrance and exit computer setup video 3.r.2.3.2 are connected respectively with the second exit and entrance video 3.r.2.3.1.

In Fig.4 shows a block diagram of the control unit organizational systems (CP PIC) 4.m (m=1, ..., M), equipment which which contains the equipment server room 4.m.1 and equipment working hall 4.m.2. The equipment server room 4.m.1 shows a computer system 4.m.1.1 and a hardware interface 4.m.2.1. Equipment working hall 4.m.2.2 includes a computer network 4.m.2.1 and multimedia projector with screen 4.m.2.2. When you do this:

- input and output of computer system 4.m.1.1 are connected respectively with the third output and input hardware interface 4.m.1.2, the first input and output which are, respectively, the first input / output equipment PU PIC 4.m and are connected respectively with the third (3-m) output channels and the input of the telecommunication network 2;

the second inputs and outputs (2-1, ..., 2-K4.m) hardware interface 4.m.1.2 are respectively the inputs and outputs from the second group of inputs and outputs of the equipment PU PIC 4.m and are connected respectively with the first outputs and inputs appropriate means two-way communication 6.3.m.1-6.4.m.K4.m;

- fourth, the fifth the inputs and outputs of the hardware interface 4.m.1.2 are connected respectively with the output and the input of the computer network 4.m.2.1, with exit and entrance multimedia projector with screen 4.m.2.2.

The above description of block diagrams (Fig.1 - Fig.4) explains the essence of the work of SSAC OS. The situational analysis centers organizational system works as follows.

In the initial state in computing systems HQ, SATS and PU after SSAC OS are formed and upominayutsya process data. A list of these, see "description of the technical solution".

At the stage of operation of SSAC OS means of control over the objects of observation in a controlled environment produce the collection of data on the state of these objects, is the transfer of these data by means of two-way communication and hardware interfaces in CC, SATS and PU VILLAGE, including:

- data transfer with video watching on the monitors of computers within a computer network and multimedia screens in working the halls of the HQ, SATS and PU POS;

- data on the actual performance observed objects, represented by the dimensionless numbers and/or units of measurement in the computational systems HQ, SATS and Poo PIC.

In computer systems CC, SATS and PU SETTLEMENT in accordance with their areas of responsibility is the processing of data about actual and required performance monitoring objects in a controlled environment and to develop data on the actual state of activity of the organizational system as a whole, the activities and status of the monitored objects. Order processing, see "Description of the technical solution description of the application.

Depending on the data produced the following scenarios:

- to eliminate the risk to the organization is sure of the whole system;

- to eliminate the threats to certain types of activities organizational systems;

- to eliminate threats to the activities of the organizational units of the system;

- to prevent threats to the activities of the organizational system as a whole;

- to prevent threats to certain types of activities organizational systems;

- to prevent threats to the activities of the organizational units of the system;

- to improve the effectiveness of the organizational system as a whole;

- to improve efficiency for certain types of activities organizational systems;

- to improve the efficiency of the operations of the units of the organizational system.

The information about scenarios, including at least: data about the monitored objects in a controlled environment, which must be carried out necessary actions; data about the forces and capabilities that are required for carrying out these activities; and information about the order of carrying out of action. And other data needed to perform actions to eliminate threats of a different nature, for their prevention or for the execution of planned works, including information about the recipients of divisions organizational systems and external organizational systems engaged for the work.

Data about scenarios and, when the mu is a necessity, the data of the video objects in a controlled space is transferred using hardware interfaces ZU, SATS and PU PIC and using the telecommunications network, depending on the destination:

in the computers in the computer network in working the halls of the HQ, SATS and PU POS;

in video and computer settings video situational rooms ZU and SATS, the computer configuration provides the distribution of the surface of the screen into segments with measurement parameters, depending on the number and priority placed on the surface data;

- on the screens of the media working in the halls of the HQ, SATS and Poo PIC.

Thus, the equipment of the control center 1 is arranged to be formed in the computer system 1.1.1, storing in the data storage system of auditing the activities of the organizational system 1.1.2, use and transfer for use in situational analysis centers 3.1, ..., 3.R and the control of organizational units of the system 4.1, ..., 3.M data for administration of hardware, data for setting up software and data for administration of the means of protection against harmful software and hardware effects part of ensuring the activities of the institutional system. Listed is use data differ in the following categories: data on critical scenarios designed to support the decision to eliminate the risk to the organizational system as a whole; data warning scenarios, designed to support decision-making for the prevention of threats to the activities of the organizational system as a whole; and information about the planned scenarios, designed to support decision making to improve the efficiency of the organizational system as a whole; data on critical scenarios, designed to support the decision to eliminate the threats to certain types of activities organizational systems; data warning scenarios, designed to support decision-making for the prevention of threats to certain types of activities organizational systems; and information about the planned scenarios, designed to support decision-making for improving the efficiency of certain types of activities organizational systems; data on critical scenarios, designed to support the decision to eliminate the threats to certain types of activities in the departments of organizational systems, data warning scenarios, designed to support decision-making for the prevention of threats to certain types of activities in the departments of organizational systems, data plans is x scenarios designed to support decision-making for improving the efficiency of certain types of activities in the departments of organizational systems.

Shown in Fig.5 - Fig.30 algorithms, charts, and diagrams are examples of how it can be implemented invention (industrial applicability of the proposed technical solution, the confirmation of its feasibility).

The algorithm works by SSAC OS, shown in Fig.5, illustrates the SATS (or CC) in managing the resolution of problems in the area of responsibility SATS (or CC).

Data in SSAS OS formed the following data paths and information paths:

the data paths between the computing complexes HQ and SATS shown in Fig.9 (example 5);

the data paths between the computing complexes HQ PIC and PU shown in Fig.10 (example 6);

the data paths between the computing complex ZU and information networks external organizational systems shown in Fig.11 (example 7);

- data paths with quantifiable indicators between computational complex ZU and control over the objects of the observations displayed in Fig.12 (example 8);

- data paths with videos between computational complex CC and tools control objects observations display the wife of Fig.13 (example 9);

- data paths with videos between computer system and video system situational room shown in Fig.14 (example 10).

Fig.15 - Fig.20 are examples of graph-schemes of algorithms constructed in accordance with the claimed technical solution and prove that they can be run using a simple computational operations complex logical and arithmetic operations.

The implementation of computer systems, computer networks and video with your computer settings included in SSAC OS can be made on the basis of well-known industrial hardware and software of computers and video. By analogy with the above drawings, the graph-schemes of algorithms are based graph-schemes of algorithms for the formation of other data of the proposed technical solution below in table 1.

Above in Fig.5 - Fig.20 examples include, primarily, to the data processing control performance monitoring objects, represented by the dimensionless numbers and the number is in different units of measurement: measurement time of signal transmission, their delays, calendar time, atmospheric pressure, temperature, fluid density, metal, distances, etc.

Other examples, including those shown in Fig.21-30 illustrate the possibility of the implementation of the technical solutions used in other areas of the scorecard views of observed objects.

So, in the paper [5] describes the method for processing inspection data about the performance of ground and surface objects. These data are transmitted for analysis in real-time from generalized sources of information for situational centers of information and telecommunication systems. The sources of generalized information function on the basis of information from technical monitoring tools.

In [6] considers a geographic information system that provides various tools for working with spatial information, allowing you to handle it in digital form and visualize on monitors and video systems.

Implementation of the data storage system of auditing the activities of the organizational system, which is part of the control may be performed based on any of the known technologies of building such systems, for example, technology-based NAS (network disk storage, Network Attached Storage).

In Fig.21 shows a block diagram of the storage system the data technology-based NAS. Technology NAS [7] develops as an alternative to universal servers, supporting many features (printing, application, Fax server, email, etc). In contrast, the NAS device perform only one function - that of a file server.

The NAS is connected to your local network and access the data for an unlimited number of heterogeneous clients (clients with different OS) or other servers. Currently, almost all NAS devices focused on the use of Ethernet (Fast Ethernet, Gigabit Ethernet-based TCP/IP protocols. Access to NAS devices are made using special protocols, file access. The most common file access protocols are protocols CIFS, NFS, and DAFS. Within such servers are specialized operating systems such as MS Windows Storage Server.

Currently, industrial produced such NAS solutions like PowerVault NF100/500/600 built on the basis of mass 1 and 2-processor Dell servers, optimized for rapid deployment of NAS services. They allow you to create a file store up to 10 TB (PowerVault NF600) using SATA or SAS drives and connecting the server to the local network. Also there are more high-performance integrated solution, for example, PowerVault NX1950, up 15 drives and expandable up to 45 C is by connecting additional MD1000 disk shelves.

In Fig.22, Fig.23 and Fig.24 are respectively examples of process diagrams of the configuration management database configuration items (RICE), scanning and inventory infrastructure. These processes can be applied as a logical basis for the training data. Formation, storage and use of data in the data storage system of auditing the activities of the organizational system may be, for example, on the basis of industrially produced specialized programs, such as software system [8]. The description of the above processes is given in [9].

In Fig.25 - Fig.30 shows examples of technical solutions for the implementation of telecommunication networks, communication interfaces, tools, two-way communication and control over the objects of observation in a controlled environment, part of SSAC OS.

In Fig.25 is a diagram of the collection device information [10]. This device implements the method of control over the timeliness of information delivery. The training device is made by the administration block configuration and management (use of information input, the input mode and input settings). As a result, the system implements the interaction between the system elements and their functionality is configured.

The device works is et as follows. Data is collected from the reference points; in our example, at one point measured intervals of one resource. Blocks of the survey provide programmatic control over the processes of measuring, processing of statistical data; sampling data are recorded and stored in silos. Given the opportunity to analyze these data using the automated system level management availability of it services. Depending on the conformity of the measured values to predetermined criteria, the control system provides the necessary information for decision making.

In Fig.26 is a diagram of multi-channel digital communication system [11]. This system is designed for computer networks, in which the paths are constructed between departments organizational systems, operating in different time zones. The technical result is the automatic regulation of the speed of data transmission in the information paths depending on the time of day. The objective is achieved by controlling the frequency generator clock frequency for transmission and reception. Multi-channel digital communication system with variable speed control transmission of data paths is as follows.

In the initial state in the memory unit are written command codes. Removability codes provides the I over time upon receipt of pulses from the output of the divider to the input of the memory block.

The translation system to a working state by applying the command code (combination of control signals):

in the switch unit of the transmitting part of the system;

in the receiver the commands (via group path).

Command codes recorded in the memory block, set:

- speed transmission (reception) signals in the group tract;

- speed transmission (reception) signals through each transmitting and receiving individual block.

Setting transfer rate (receive) signals as follows. At the output of the memory block under the influence of pulses from the divider, you receive a combination of control signals, which goes:

on the transmit side of the system: the control inputs of the switch unit, the first inputs of And gates and an information control unit;

through n-th transmitting the individual unit that transmits a group block group tract group receiving block and the n-th receiving individual block in the receiver of the command.

The signal inputs of the switch unit of the transmitting part of the system receives pulses from the transmitting block groups, which, depending on the state of the switches defined by a combination of control signals transmitted in the transmission of individual blocks.

The combination of control signals from the output of the receiver commands transmitted to the and second input switch unit receiving part of the system. This ensures that the work of the transmitting and receiving parts of the system, agreed:

- speed data input in transmit individual units;

- speed information output from the receiving individual blocks.

Coordinated operation of the control unit and receiver commands provided by feed the clock input of the control unit and to the second input of the receiver are identical sequences of clock pulse signals.

Thus, using combinations of control signals from the output of the memory block and the distinguished depending on the time of day, produced a corresponding frequency clock pulses for reading information signals, which specifies:

- speed transmission and reception of signals in the group section of the system;

and in proportion to the changed speed of the transmission and reception of individual information paths formed by using the transmitting and receiving individual blocks.

Analyzing the load on the information paths organizational systems at different intervals of time and recording the results of analysis in the memory block corresponding command codes, you can set the speed of signal transmission, optimal from the point of view of maximum system throughput for different time intervals.

The piano is, 27 is a diagram of the device for the exchange of information [12]. This device provides the possibility of formation (fracture and/or switching) information channels at given points in time. Providing such opportunities to practice automates the exchange of information between computing systems, computers and two-way means of communication.

Device for the exchange of information works as follows. In the initial state records the following information:

in block 1 of the memory inputs and outputs are recorded numbers of inputs/outputs of the first switching unit, participating in the planning sessions;

in the memory unit 2 inputs and outputs are recorded numbers of inputs/outputs of the second switching unit, participating in the planning sessions. The account is linked to the corresponding inputs/outputs of the first switching unit;

in the block of memory beginning of the session are written to the timestamp T1the start of the session, in relation to the respective pairs of inputs and outputs of the first and second switching blocks;

in the memory block of the session are written to the timestamp T2the end of the session, in relation to the respective pairs of inputs/outputs of the first and second switching blocks.

The recording is done with the appropriate installation of inputs, and the original memory is set to zero, and then is written to inform the tion.

The inputs/outputs of the switching blocks are connected to the inputs/outputs of server systems (personal computers)involved in the metabolic processes in different sessions.

The counter state and the trigger is set to the zero state by the pulse on their inputs run.

Under the influence of the zero combination received at address inputs of all memory blocks, the following connections are made:

- input/output of the first switching unit, which is scheduled to participate in the first session, connects to the first input/output key block;

- input/output of the second switching unit, which is scheduled to participate in the first session, connects to the second input/output key block;

- at the first input of the timer, the start of the session comes a time stamp T1the beginning of the first session. To the second input of timer session start signals to the actual time of the counter States;

- at the first input of the timer when the session enters the timestamp T2the end of the first session. To the second input of timer termination signals to the actual time of the counter States.

Timers start and end of the session change its state by the action of the pulses coming from the clock.

When matching the label of the actual time with a timestamp T 1the first session starts at the output of the timer session start pulse appears, throwing the trigger. The trigger includes a key block and the first input/output connected to the second output/input. This ensures the exchange of packets of information signals between the server systems (personal computers)participating in the first session.

When matching the label of the actual time with a timestamp T2the end of the first session at the output of the timer termination pulse appears. This pulse again throws the trigger, resulting in:

- interrupts the connection of the first input/output and the second output/input key unit;

the first input is connected to the first output, a second input connected to the second output, forming plumes. Thus terminated the exchange of packets of information signals between the server systems (personal computers)participating in the first session;

the counter state is set in the following state in which the unit of currency is preparing for the second session.

Similarly are all scheduled sessions. Then after the passage of the timers maximum values of the processes are repeated until the recording of new information about sessions.

In Fig.28 - Fig.30 is a diagram and chart illustrating a transmission method of disks is the shaft of the signals on the movable object [13], where indicated:

L is the distance by which to move the movable object;

V - speed of movement of the moving object;

fcpthe initial duration of information signals;

T is the repetition period information signals;

TISM- change period duration information signals;

tmin- the value of which is determined by the duration information signals through a period of TISM;

t0- the beginning of the transmission of information signals.

This method of transmission of information signals on the movable object provides increased robustness functioning tract information of a movable object, and is as follows.

On stationary object:

- form of information signals with an initial duration of tcpand the repetition period T. the Duration of tcpinformation signals is set in accordance with the middle way, which moves the movable object.

Signals modulate and emit;

in the case of removal of a moving object from a stationary duration of the signals transmitted between them, with increases over time (Fig.29) the value of tminthrough periods TISMdefined by the following ratio:

- in the case of approximation p of the wheel to a stationary object duration signals, passed between them, over time decreases (Fig.30) also on the value of tminover the same periods TISMdefined by equation (2);

- change (decrease or increase) the duration is terminated after the time t=L/V.

On the movable object signals are received and demodulated.

Changing the duration of the signals makes it possible to maintain at the receiver input constant power, which increases the noise immunity of the information highway. Increased robustness is achieved by increasing the time at the reception for analysis of the presence of the information signal (removing the movable object).

The technical result provided by the above set of features, is to increase the efficiency of the decision-making process through the automated generation of scenarios (plans) to resolve problem situations.

The positive effect is achieved by using computer systems in the control center, situational research centers and in the control of organizational units of the system: (a) on the basis of data obtained control over the objects of observation to analyze the activities of the organizational system, including analysis of the activities of the organizational units of the system, the analysis of individual in the types of activity organizational systems and analysis of the organizational system as a whole; (b) on the basis of the results of this analysis and is formed in advance scripting permissions problem (critical) situations, scenarios prevent these situations and scenarios planned activities in the subject area of activity of the organizational system, to select and transmit for execution in units of the organizational system optimal scenario execution of works to resolve problematic situations, and/or to prevent and/or to improve the performance of the organizational units of the system, certain types of activities or the activities of the organizational system as a whole. The positive effect is the possibility of simultaneous execution of the above works.

Sources of information

1. EN 57481 U1, G05F 12/00 (2006.01), publ. 10.10.2006.

2. EN 57919 U1, G05B 15/00 (2006.01), publ. 27.10.2006.

3. EN 105031 U1, G05B 19/00 (2006.01), publ. 27.05.2011.

4. EN 28927 U1, G05B 19/00, publ. 20.04.2003.

5. "Information technology monitoring on the basis of the collection of information from technical monitoring tools". // Collection of articles "Methods of construction and technology of functioning of situational centers"): Informatics problems, Russian Academy of Sciences, 2011, S. 124-135.

6. "The use of GIS technologies as part of the situational center. // Collection of articles "Methods of construction and technology functioning situation Centro is" - M: Informatics problems, Russian Academy of Sciences, 2011, S. 89-111.

7. "The main data storage systems and their features". // http://www.anti-malware.ru/data_storage_technologies_review, publ. 30.03.2009.

8. "Navy Atrium". // http://www.bmc.com/products/atrium/atrium.html.

9. "Situational centers: information - processes - organization". // Telecommunication, 2011, No. 6, S. 42-46.

10. SU 1742834 A1, CL H04M 3/22, publ. 23.06.92, bull. No. 23.

11. SU 1800631 A1, CL H04J 3/24, publ. 07.03.93, bull. No. 9.

12. SU 1821802 A1, CL G06F 13/00, publ. 15.06.93, bull. No. 22.

13. SU 1769367 A1, CL H04B 7/26, publ. 15.10.92, bull. No. 38.

1. The situational analysis centers organizational system, characterized in that it includes a telecommunication network, the control center, situational analytical centers, control units organizational systems, two-way communication, controls, objects, and the objects of observation are the subjects and objects of the organizational system and the external environment that affect the status of activities organizational systems; controls contain blocks of data generation on the performance monitoring objects, represented by the dimensionless numbers and/or other units of measurement, including the shaping unit telemetry digital information, and/or block co-ordinates of the object of observation and/or controlled area of the object of observation, the block specifying those the current time monitoring of the condition of the monitored object, the block of the video image of the monitoring object; the inputs and outputs of the first group of inputs and outputs of the control center are connected respectively with the first outputs and inputs appropriate means two-way communication, second inputs and outputs which are connected respectively with the first outputs and inputs of the respective control devices of objects of observation; the second input and output of the control center are connected respectively with the first exit and entrance of the telecommunication network; the inputs and outputs from the second group of inputs and outputs telecommunication networks are connected respectively with the first outputs and inputs relevant situational analysis centers; the inputs and outputs of the third group of inputs and outputs telecommunication networks are connected respectively with the first outputs and inputs of the respective control units of the organizational system, the inputs and outputs of the fourth group of inputs and outputs telecommunication networks are connected respectively to the outputs and inputs of the respective information networks external organizational systems; inputs and outputs from the second group of inputs and outputs of each situational analysis center connected to the first outputs and inputs appropriate means two-way communication, second inputs and outputs which are connected respectively with the PE the new outputs and inputs of the respective control means of the monitored objects; the inputs and outputs from the second group of inputs and outputs of each of the control units of the organizational system is connected to the first outputs and inputs appropriate means two-way communication, second inputs and outputs which are connected respectively with the first outputs and inputs of the respective control devices of objects of observation in a controlled environment; providing the possibility of automatic generation of scenarios using computer systems control center, situational tanks and control units organizational systems; data storage scenarios in the data storage system of auditing the activities of the organizational system, which is part of the control center; transmitting the actual data on the status of activities and the status of the objects observations to generate scenarios of computing systems included in the situational analysis centers and control of organizational units of the system via the telecommunications network to the computing center management; transmitting the actual data about the monitored objects to generate scenarios of the control means by means of two-way communication in the computing center management; data about the scenarios of computing comp the EU control center via the telecommunications network in computing systems situational tanks and control of organizational units of the system; data about scenarios using the hardware interfaces of the control center, situational tanks, control units organizational systems and using the telecommunications network in a computer network control center, situational tanks and control units organizational systems, video and computer settings video control center and situational tanks, screens, multimedia control center, situational tanks and control of organizational units of the system for acceptance on the basis of scenarios of solutions; automated generation of scenarios in computer systems control center, situational tanks and control units organizational systems manufactured by data on the actual and required performance monitoring objects and generate data about the actual state of activity of the organizational system as a whole, the activities and status of the monitored objects, depending on the results of data processing are developed scripts to eliminate threats and preventing threats and to improve the effectiveness of the organizational system as a whole, certain types of activities is lnasty organizational systems and activities of the organizational units of the system; the composition of the produced data about the scenarios that are to be stored in the data storage system of auditing the activities of the organizational system, which is part of the control center, includes data about the objects that must be carried out the necessary actions, data about the forces and capabilities that are required for carrying out these actions, and information about the order of carrying out of actions, data about the recipients of divisions organizational systems and external organizational systems engaged for the work, and information about priorities and predicted probabilities for scenario selection when deciding other data needed to perform actions to eliminate threats, prevention and planned works, and the data stored in the data storage system of auditing the activities of the organizational system, periodically audited and updated; in the actual data on the status of activities and on the status of the monitored objects that are transferable to generate scenarios of computing systems included in the situational analysis and control of organizational units of the system via the telecommunications network to the computing center management includes data about the actual condition of the volume of the tov observations which have an impact on the activities carried out in the Department of organizational systems, the absolute values of the deviations of the data on actual performance data from the required performance monitoring objects, which have an impact on the activities carried out in the Department of organizational systems, the actual condition activities implemented within the organizational unit of the system, the actual performance of activities in the division of organizational systems, the actual condition activities of the organizational system, the actual performance of the activities of the organizational system; in the actual data about the objects that are transferable to develop scenarios of the means of control through means of two-way communication in a computer system, includes data on the actual performance monitoring objects, which have an impact on the activities carried out in the departments of organizational systems, and these data are presented dimensionless numbers, time, metric, weight, cost and other units later in the computing center management by processing these data produced in the processing of data about the deviation of actual data from the required data about the performance of the monitored objects and their basis is to develop evidence on the state of these objects; the information about the scenarios that are transferable from computer system control center via the telecommunications network in computing systems situational and analytical systems and control units of the organizational system, includes data for administration of hardware, data for configuring software and data for administration of the means of protection against harmful software and hardware effects part of ensuring the activities of the institutional system, and the scenarios are divided into data about critical, warning and planned scenarios that are designed to support decision making, respectively, to eliminate threats to prevent threats and to improve the effectiveness of organizational system in General, certain types of activities organizational systems and certain types of activities in the departments of organizational systems; enables data transfer with video monitoring objects with interfaces hardware control center, situational tanks, control units organizational systems and using the telecommunications network in video and multimedia screens in the control center and the case is one of the centers, screens multimedia control units of the organizational system.

2. The system under item 1, characterized in that the control center contains the analytic center and the center of objective control, analytical center contains computer system and the storage system audit the activities of the organizational system, the Central objective of the control contains the hardware interface, computer network, one multimedia projector with screen, video system and computer settings video; first, second, third, fourth, fifth and sixth inputs and outputs of the hardware interface connected respectively to the outputs and the inputs of the computing system, the storage system audits of organizational systems, computer networks, multimedia projector with screen, the first exit and entrance video, the first output and the input of the computer configuration display, the second input and the output of which is connected respectively with the second output and the input video; seventh input, output and inputs, the outputs from the eighth group of the inputs and outputs of the hardware interface are, respectively, the second input, an output and inputs, the outputs from the first group of inputs, outputs control center.

3. The system under item 1, characterized in that the situational analysis center provides computing to the complex and the center of objective control, which contains the hardware interface, computer network, one multimedia projector with screen, video system and computer settings video; the first input, the output and the inputs, the outputs from the second group of inputs, outputs, interface equipment are respectively the first input, an output and inputs, the outputs from the second group of inputs, outputs situational analysis center, the third, the fourth, fifth, sixth and seventh inputs and outputs of the hardware interface connected respectively to the outputs and inputs of computer system, computer network, multimedia projector with screen, the first exit and entrance video and the first exit and entrance computer configuration display, the second input and the output of which is connected respectively with the second exit and entrance video.

4. The system under item 1, characterized in that the control unit organizational system includes a computer system, interface equipment, computer network and one multimedia projector with screen; the first input, the output and the inputs, the outputs from the second group of outputs, the inputs of the hardware interface are, respectively, the first input, an output and inputs, the outputs from the second group of inputs, outputs, control unit organizational systems, third, fourth and fifth inputs and outputs of the interface equipment is the equipment connected respectively to the outputs and the inputs of the computing system, computer network and multimedia projector with screen.

5. The system under item 2, characterized in that the control center is configured to be formed in the computer system, storing in the data storage system of auditing the activities of the organizational system, use and transfer for use in situational analytical centers and in the control units of the organizational data systems for administration, hardware, data for setting up software and data for administration of the means of protection against harmful software and hardware effects part of ensuring the activities of the institutional system; the above data is divided into data about critical scenarios that are intended to support decision-making on to eliminate the risk to the organizational system as a whole; data warning scenarios, which are intended to support decision-making for the prevention of threats to the activities of the organizational system as a whole; data on planning scenarios, which are designed to support decision making to improve the efficiency of the organizational system as a whole; data on critical scenarios, which are designed to support a decision on the burden of the threats to certain types of activities organizational system; data warning scenarios, which are intended to support decision-making for the prevention of threats to certain types of activities organizational systems; and information about planning scenarios, which are intended to support decision-making for improving the efficiency of certain types of activities organizational systems; data on critical scenarios, which are intended to support the decision to eliminate the threats to certain types of activities in the departments of organizational systems, data warning scenarios, which are intended to support decision-making for the prevention of threats to certain types of activities in the departments of organizational systems, data planning scenarios, which are designed to support decision making to improve the effectiveness of certain activities in the departments of organizational systems.

6. The system under item 1, characterized in that it is made with the possibility of the formation, preservation and display on the screens of data D about the desired state of activity of the organizational system as a whole, the data Dnabout the required condition and the data αnon the assigned priority for the n-th activity of the organizational system, n=1, 2, ..., N, data, Snmabout the required state and data βnmabout prior the aunt of the n-th activity, implemented in the m-th unit of the organizational system, m=1, 2, ..., M, data, Vnmkabout the required state and data γnmkthe priority of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, k=1, 2, ..., K, data L_k on the number of indicators that are used to describe the state of the k-th object of observation, dataVklabout the required l-th indicator of data andμklthe priority of the l-th indicator of the k-th object of observation, dataVnmkl=Vklabout the required l-th indicator of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, or dataVnmkl=0if desired, the l-th indicator of the k-th object of observation does not affect the n-th type of activity carried out by the m-th unit of the organizational system, l=1, 2, ..., L_k, and data Snmnm1Vnm1nm2Vnm2+...+γnmKVnmKand dataVnmk=μk1Vnmk1+μk2Vnmk2+...+μkL_kVnmkL_kin the composition of the data on the required performance monitoring objects includes information on required indicators of physical, logical, information, spatial, structural, organizational and other types of coupling k-th object surveillance with other objects.

7. The system under item 6, characterized in that it is configured to collect, store, and display data screensV*nmk1on the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, introducing the dimensionless numbers, and/or units, and/or videoson what ojeniyi, in this case n=1, 2, ..., N, m=1, 2, ..., M, k=1, 2, ..., K, l=1, 2, ..., L_k; data on the actual performance of the monitored objects include data on the actual performance of the physical, logical, information, spatial, structural, organizational and other types of coupling k-th object surveillance with other objects.

8. The system under item 7, characterized in that it is made with possibility, after you collect and save dataV*nmk1on the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, making the formation, preservation and display dataV*nmk1=|Vnmkl-V*nmkl|the absolute value of the data changesV*nmk1on the actual l the index of the k-th object of observation which affects the n-th activity, implemented in the m-th unit of the organizational system, compared withVnmk1about the required l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, dataV*nmk=μk1(Vnmk1-ΔV*nmk1)+μk2(Vnmk2-ΔV*nmk2)+...+μkL_k(V*nmkL_k-V*nmkL_k)about the actual condition of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, the data S* nmnm1V*nm1nm2V*nm2+...+γnmKV*nmKon the actual state of the n-th activity in the m-th division organizational systems, data ΔS*nm=S*nm/Snmabout the effectiveness of the n-th activity in the m-th division organizational systems, data D*nn1S*n1n2S*n2,+...+βnMS*nMabout the actual condition of the n-th activity organizational systems, data Dnn1Sn1n2Sn2+...+βnMSnMabout the desired state of the n-th activity organizational systems, data D*n=D*n/Dnabout the effectiveness of the n-th activity organizational systems, data D*=α1D*12D*2,+...+αND*Non the actual operation status of the organizational system as a whole, the data D=α1D12D2,+...+αNDNabout the desired condition of operation of the organizational system as a whole, data ∆ D*=D*/D on the performance indicators of the organizational system as a whole.

9. The system under item 8, characterized in that it is arranged to compose, store, and display data screens ∆ DCrete.on the performance indicators of the organizational system as a whole, reduced, compared with which, fakticheskogo the indicator indicates the existence of a threat to the activities of the organizational system as a whole and the need to take action to address it, data ∆ Dsupplementaryon the performance indicators of the organizational system as a whole, reduced, compared with which, the actual value means the possibility of threats to the activities of the organizational system as a whole and the need to take action to prevent the emergence of threats, data ∆ Dn-Crete.the performance data of the n-th activity of the organizational system, decrease, compared with which, the actual indicator indicates the existence of a threat to this type of activity organizational systems and necessary action for its elimination, data ∆ Dn-supplementarythe performance data of the n-th activity of the organizational system, decrease, compared with which, the actual value means the possibility of threats to this type of activity organizational systems and the need to take action to prevent the emergence of threats, data ΔSnm-Crete.the performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual indicator indicates the existence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action for its elimination, data ΔSnm-extraabout pokazatel the efficiency of the n-th activity, implemented in the m-th unit of the organizational system, decrease, compared with which, the actual value means the possibility of threats to the n-th activity in the m-th unit of the organizational system and the need to take action to prevent the emergence of threats.

10. System on p. 9 characterized in that made with the possibility of the formation, preservation and display data screensWKpandt.1,WKpandt.2, ...,WKpandt.QKpandt.critical scenarios, designed to support the decision to eliminate the risk to the organizational system as a whole under the condition 0≤ ∆ D*< ∆ DCrete.data on the number of QCrete.and data q1=1, 2, ..., QCrete.on priorities for dataWKpandt.1,W Kpandt.2, ...,WKpandt.QKpandt.dataP(WKpandt.1),P(WKpandt.2), ...,P(WKpandt.QKpandt.)about the predicted probabilities of choice when deciding critical scriptWKpandt.1orWKpandt.2, ..., orWKpandt.QKpand t.andP(WKpandt.q1)P(WKpandt.q1-1),P(WKpandt.0)=0,q1=1QKpandt.P(WKpandt.q1)=1.

11. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWpped.1,Wpped.2 , ...,Wpped.Qpped.warning scenarios that are designed to support decision-making for the prevention of threats to the activities of the organizational system as a whole, provided ∆ DCrete.≤ ∆ D*< ∆ Dsupplementarydata on the number of Qbefore.and data q2=1, 2, ..., Qbefore.on priorities for dataWpped.1,Wpped.2, ...,Wpped.Qpped.dataP(Wpped.1),P(Wpped.2), ...,P( Wpped.Qpped.)about the predicted probabilities of choice when deciding warning scriptWpped.1orWpped.2, ..., orWpped.Qpped.andP(Wpped.q2)P(Wpped.q2-1),P(Wpped.0)=0,q2=1 Qpped.P(Wpped.q2)=1.

12. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWplandn.1,Wplandn.2, ...,Wplandn.Qplandn.on target scripts used to support decision making to improve the efficiency of the organizational system as a whole, provided ∆ Dsupplementary≤ ∆ D*<1, the number of Qplan.and data q3=1, 2, ..., Qplan.on priorities for dataWplandn.1,Wplandn. 2, ...,Wplandn.Qplandn.dataP(Wplandn.1),P(Wplandn.2), ...,P(Wplandn.Qplandn.)about the predicted probabilities of choice when deciding planned scriptWplandn.1orWplandn.2, ..., orWplandn.Qplandn. andP(Wplandn.q3)P(Wplandn.q3-1),P(Wplandn.0)=0,q3=1Qplandn.P(Wplandn.q3)=1.

13. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWKpandt.n1,WKpandt.n2, ...,WKpandt.nUn-Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity organizational system under the condition 0≤ ∆ D*n< ∆ Dn-Crete.data on the number of Un-Crete.and data u1=1, 2, ..., Un-Crete.on priorities for dataWKpandt.n1,WKpandt.n2, ...,WKpandt.nUn-Kpandt.dataP(WKpandt.n1),P(WKpandt.n2) , ...,P(WKpandt.n(u1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.n1orWKpandt.n2, ..., orWKpandt.nUn-Kpandt.andP(WKpandt.nu1)P(WKpandt.n(u1-1)),P(WKpandt. n0)=0,u1=1Un-Kpandt.P(WKpandt.nu1)=1.

14. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWpped.n1,Wpped.n2, ...,Wpped.nUn-pped.warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity organizational system, provided that ∆ Dn-Crete.≤ ∆ D*n< ∆ Dn-supplementarydata on the Isla U n-before.data and u2=1, 2, ..., Un-before.on priorities for dataWpped.n1,Wpped.n2, ...,Wpped.nUn-pped.dataP(Wpped.n1),P(Wpped.n2), ...,P(Wpped.n(u2-1))about the predicted probabilities of choice when deciding warning scriptWthe ped.n1orWpped.n2, ..., orWpped.nUn-pped.andP(Wpped.nu2)P(Wpped.n(u2-1)),P(Wpped.n0)=0,u2=1Un-pped.P(Wpped.nu 2)=1.

15. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWplandn.n1,Wplandn.n2, ...,Wplandn.nUn-plandn.on target scripts used to support decision-making for improving the efficiency of the n-th activity organizational system, provided that ∆ Dn-supplementary≤ ∆ D*n<1, the number of Un-plan.and data u3=1, 2, ..., Un-plan.on priorities for dataWplandn.n1,Wplandn.n2, ..., Wplandn.nUn-plandn.dataP(Wplandn.n1),P(Wplandn.n2), ...,P(Wplandn.n(u3-1))about the predicted probabilities of choice when deciding planned scriptWplandn.n1orWplandn.n2, ..., orWplandn.nUn-pland n.andP(Wplandn.nu3)P(Wplandn.n(u3-1)),P(Wplandn.n0)=0,u3=1Un-plandn.P(Wplandn.nu3)=1.

16. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWKpandt.nm1, WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system, provided that 0≤S*nm<ΔSnm-Crete.data on the number of Ynm-Crete.and data y1=1, 2, ..., Ynm-Crete.on priorities for dataWKpandt.nm1,WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt.dataP(WKpandt.nm1 ),P(WKpandt.nm2), ...,P(WKpandt.nm(y1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.nm1orWKpandt.nm2, ..., orWKpandt.nmYnm-Kpandt.andP(WKpandt.nmy1)P(Wmrow> Kpandt.nm(y1-1)),P(WKpandt.nm0)=0,y1=1Ynm-Kpandt.P(WKpandt.nmy1)=1.

17. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWpped.nm1,Wpped.nm2, ...,Wpped.nm Ynm-pped.warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity in the m-th unit of the organizational system, provided that ∆ Snm-Crete.≤ΔS*nm<ΔSnm-extradata on the number of Ynm-before.and data y2=1, 2, ..., Ynm-before.on priorities for dataWpped.nm1,Wpped.nm2, ...,Wpped.nmYnm-pped.dataP(Wpped.nm1),P(Wpped.nm2) , ...,P(Wpped.nm(y2-1))about the predicted probabilities of choice when deciding warning scriptWpped.nm1orWpped.nm2, ..., orWpped.nmYnm-pped.andP(Wpped.nmy2)P(Wpped.nm(y2-1)),P( Wpped.nm0)=0,y2=1Ynm-pped.P(Wpped.nmy2)=1.

18. The system under item 9, characterized in that it is arranged to compose, store, and display data screensWplandn.nm1,Wplandn.nm2, ...,Wplandn.nmYnm-plandn.on target scripts used to support decision making to improve the efficiency of n-th operation is in the m-th unit of the organizational system, provided that ∆ S nm-extra≤ΔS*nm<1, the number of Ynm-plan.and data y3=1, 2,..., Ynm-plan. on priorities for dataWplandn.nm1,Wplandn.nm2, ...,Wplandn.nmYnm-plandn.dataP(Wplandn.nm1),P(Wplandn.nm2), ...,P(Wplandn.nm(y3-1))about the predicted probabilities of choosing the acceptance decisions of the planned script Wplandn.nm1orWplandn.nm2, ..., orWplandn.nmYnm-plandn.andP(Wplandn.nmy2)P(Wplandn.nm(y3-1)),P(Wplandn.nm0)=0,y3=1Ynm-plandn.P (Wplandn.nmy3)=1

19. The system under item 1, characterized in that the control center is configured to compose, store, and display on the screens of data D about the desired state of activity of the organizational system as a whole, the data Dnabout the required condition and the data αnon the assigned priority for the n-th activity of the organizational system, n=1, 2, ..., N, data, Snmabout the required state and data βnmthe priority of the n-th activity in the m-th unit of the organizational system, m=1, 2, ..., M, data, Vnmkabout the required state and data γnmkthe priority of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, k=1, 2, ..., K, data L_k on the number of indicators that are used to describe the state of the k-th object of observation, dataVnmklabout the required l-th indicator status and data µnmklthe priority of the l-th indicator of the k-th object of observation, which affects n-s the type of activity, implemented in the m-th unit of the organizational system, l=1, 2, ..., L_k, with the possibility of receiving dataV*nmk1on the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, dataΔV*nmk1the absolute value of the data changesV*nmk1in comparison with the data ofVnmk1data V*nmkabout the actual condition of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, data S*nmon the actual state of the n-th activity in the m-th division organizational systems, data ΔS*nmthe performance data of the n-th activity in the m-th unit of the organizational system, with the possibility of creation is, save and display data ∆ DCrete.on the performance indicators of the organizational system as a whole, reduced, compared with which, the actual indicator indicates the existence of a threat to the activities of the organizational system as a whole and the need to take action for its elimination, data ∆ Dsupplementaryon the performance indicators of the organizational system as a whole, reduced, compared with which, the actual value means the possibility of threats to the activities of the organizational system as a whole and the need to take action to prevent the emergence of threats, data ∆ Dn-Crete.the performance data of the n-th activity of the organizational system, decrease, compared with which, the actual indicator indicates the existence of a threat to this type of activity organizational systems and necessary action for its elimination, data ∆ Dn-supplementarythe performance data of the n-th activity of the organizational system, decrease, compared with which, the actual value means the possibility of threats to this type of activity organizational systems and the need to take action to prevent the emergence of threats, data ΔSnm-Crete.the performance data of the n-th activities.it is STI, implemented in the m-th unit of the organizational system, decrease, compared with which, the actual indicator indicates the existence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action for its elimination, data ΔSnm-extrathe performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual value means the possibility of threats to the n-th activity in the m-th unit of the organizational system and the need to take action to prevent the emergence of threats, dataWKpandt.1,WKpandt.2, ...,WKpandt.QKpandt.critical scenarios, designed to support the decision to eliminate the risk to the organizational system as a whole under the condition 0≤ ∆ D*< ∆ DCrete.data on the number of QCrete. and data q1=1, 2, ..., QCrete.on priorities for dataWKpandt.1,WKpandt.2, ...,WKpandt.QKpandt.dataP(WKpandt.1),P(WKpandt.2), ...,P(WKpandt.QKpandt.)about the predicted probabilities of choice when deciding critical scriptWKpandt.1or WKpandt.2, ..., orWKpandt.QKpandt.dataWpped.1,Wpped.2, ...,Wpped.Qpped.warning scenarios that are designed to support decision-making for the prevention of threats to the activities of the organizational system as a whole, provided ∆ DCrete.≤ ∆ D*< ∆ Dsupplementarydata on the number of Qbefore.and data q2=1, 2, ..., Qbefore.on priorities for dataWpped.1,Wpped.2, ..., Wpped.Qpped.dataP(Wpped.1),P(Wpped.2), ...,P(Wpped.Qpped.)about the predicted probabilities of choice when deciding warning scriptWpped.1orWpped.2, ..., orWpped.Qpped.dataWmrow> plandn.1,Wplandn.2, ...,Wplandn.Qplandn.on target scripts used to support decision making to improve the efficiency of the organizational system as a whole, provided ∆ Dsupplementary≤ ∆ D*<1, the number of Qplan.and data q3=1, 2, ..., Qplan.on priorities for dataWplandn.1,Wplandn.2, ...,Wplandn.Qplandn.dataP(Wplandn.1), P(Wplandn.2), ...,P(Wplandn.Qplandn.)about the predicted probabilities of choice when deciding planned scriptWplandn.1,Wplandn.2, ...,Wplandn.Qplandn.dataWKpandt.n1,WKpandt.n2, ...,WKpandt.nUnwhat is Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity organizational system under the condition 0≤ ∆ D*n< ∆ Dn-Crete.data on the number of Un-Crete.and data u1=1, 2, ..., Un-Crete.on priorities for dataWKpandt.n1,WKpandt.n2, ...,WKpandt.nUn-Kpandt.dataP(WKpandt.n1),P(WKpandt.n2), ...,P(WKR andt.n(u1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.n1orWKpandt.n2, ..., orWKpandt.nUn-Kpandt.dataWpped.n1,Wpped.n2, ...,Wpped.nUn-pped.warning scenarios that are designed to maintain the Riki decision to prevent threats to the n-th activity organizational system, provided that ∆ D n-Crete.≤ ∆ D*n< ∆ Dn-supplementarydata on the number of Un-before.data and u2=1, 2, ..., Un-before.on priorities for dataWpped.n1,Wpped.n2, ...,Wpped.nUn-pped.dataP(Wpped.n1),P(Wpped.n2), ...,P(Wpped.n(u2-1))about the predicted probabilities of choice when deciding preduprejdayuschego the script Wpped.n1orWpped.n2, ..., orWpped.nUn-pped.dataWplandn.n1,Wplandn.n2, ...,Wplandn.nUn-plandn.on target scripts used to support decision-making for improving the efficiency of the n-th activity organizational system, provided that ∆ Dn-supplementary≤ ∆ D*n<1, the number of Un-plan.and data u3=1, 2, ..., Un-plan.on priorities for dataW plandn.n1,Wplandn.n2, ...,Wplandn.nUn-plandn.dataP(Wplandn.n1),P(Wplandn.n2), ...,P(Wplandn.n(u3-1))about the predicted probabilities of choice when deciding planned scriptWplandn.n1or Wplandn.n2, ..., orWplandn.nUn-plandn.dataWKpandt.nm1,WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system, provided that 0≤S*nm<ΔSnm-Crete.data on the number of Ynm-Crete.and data y1=1, 2, ..., Ynm-Crete.on priorities for dataWKpandt.nm1 ,WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt.dataP(WKpandt.nm1),P(WKpandt.nm2), ...,P(WKpandt.nm(y1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.nm1orWKpmi> andt.nm2, ..., orWKpandt.nmYnm-Kpandt.dataWpped.nm1,Wpped.nm2, ...,Wpped.nmYnm-pped.warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity in the m-th unit of the organizational system, provided that ∆ Snm-Crete.≤ΔS*nm<ΔSnm-extradata on the number of Ynm-before.and data y2=1, 2, ..., Ynm-before.on priorities for dataWpped.nm1Wpped.nm2, ...,Wpped.nmYnm-pped.dataP(Wpped.nm1),P(Wpped.nm2), ...,P(Wpped.nm(y2-1))about the predicted probabilities of choice when deciding warning scriptWpped.nm1orWpthe ed.nm2, ..., orWpped.nmYnm-pped.dataWplandn.nm1,Wplandn.nm2, ...,Wplandn.nmYnm-plandn.on target scripts used to support decision-making for improving the efficiency of the n-th activity in the m-th unit of the organizational system, provided that ∆ Snm-extra≤ΔS*nm<1, the number of Ynm-plan.and data y3=1, 2, ..., Ynm-plan.on priorities for dataWplandn.nm1, Wplandn.nm2, ...,Wplandn.nmYnm-plandn.dataP(Wplandn.nm1),P(Wplandn.nm2), ...,P(Wplandn.nm(y3-1))about the predicted probabilities of choice when deciding planned scriptWplandn.nm1orWplandn.n/mi> m2, ..., orWplandn.nmYnm-plandn.with data transfer capabilityWKpandt.n1,WKpandt.n2, ...,WKpandt.n(u1-1),Wpped.n1,Wpped.n2, ...,Wpped.n(u2-1) ,Wplandn.n1,Wplandn.n2, ...,Wplandn.n(u3-1), ∆ Dn-Crete., ∆ Dn-supplementaryThat ∆ Snm-Crete.That ∆ Snm-extraUn-Crete., u1,P(WKpandt.n1),P(WKpandt.n2), ...,P(WKpandt.n(u1-1))Un-before., u2,P(Wpped. n1),P(Wpped.n2), ...,P(Wpped.n(u2-1))Un-plan., u3,P(Wplandn.n1),P(Wplandn.n2), ...,P(Wplandn.n(u3-1))in situational analysis centers from the system situational tanks organizational system, with data transfer capability WKpandt.nm1,WKpandt.nm2, ...,WKpandt.nm(y1-1),Wpped.nm1,Wpped.nm2, ...,Wpped.nm(y2-1),Wplandn.nm1,Wplandn.nm2 , ...,Wplandn.nm(y3-1)That ∆ Snm-Crete.That ∆ Snm-extra, Ynm-Crete., y1,P(WKpandt.nm1),P(WKpandt.nm2), ...,P(WKpandt.nm(y1-1)), Ynm-before., y2,P(Wpped.nm1),P(Wpped.nm2), ..., P(Wpped.nm(y2-1)), Ynm-plan., y3,P(Wplandn.nm1),P(Wplandn.nm2), ...,P(Wplandn.nm(y3-1))in the control units of the organizational system from the system situational analysis centers.

20. The system under item 1, characterized in that the number R of situational tanks is equal to the number N of activities, with each situational analysis center has a capability of receiving, storing and displaying data Dnabout the required condition and the data αnon the assigned priority for one of the species on the activities of the organizational system, where ∀n∈1, 2, ..., N, dataV*nmklon the actual l the index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, dataΔV*nmklthe absolute value of the data changesV*nmklcompared withVnmkldata V*nmkabout the actual condition of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, data S*nmthe actual state of the n-th activity in the m-th division organizational systems, data ΔS*nmthe performance data of the n-th activity in the m-th unit of the organizational system, where m=1, 2, ..., M, k=1, 2, ..., K, l=1, 2, ..., L_k, with the ability to compose, store, and display data D*nabout the fact the logical state of the n-th activity organizational systems, data ∆ D*nthe performance data of the n-th activity of the organizational system, with data transfer capability ∆ D*nand data ∆ D*nin the control center, with the possibility of receiving, storing and displaying data ∆ Dn-Crete.the performance data of the n-th activity of the organizational system, decrease, compared with which, the actual indicator indicates the existence of a threat to this type of activity organizational systems and necessary action for its elimination, data ∆ Dn-supplementarythe performance data of the n-th activity of the organizational system, decrease, compared with which, the actual value means the possibility of threats to this type of activity organizational systems and the need to take action to prevent the emergence of threats, data ΔSnm-Crete.the performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual indicator indicates the existence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action for its elimination, data ΔSnm-extrathe performance data of the n-th activity in the m-th unit of organizationalists, the decrease, compared with which, the actual value means the possibility of threats to the n-th activity in the m-th unit of the organizational system and the need to take action to prevent the emergence of threats, dataWKpandt.n1,WKpandt.n2, ...,WKpandt.nUn-Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity organizational systems, data on the number of Un-Crete.and data u1=1, 2, ..., Un-Crete.dataP(WKpandt.n1),P(WKpandt.n2) , ...,P(WKpandt.n(u1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.n1orWKpandt.n2, ..., orWKpandt.nUn-Kpandt.dataWpped.n1,Wpped.n2, ...,Wpped.nUn-pped. warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity organizational systems, data on the number of Un-before.data and u2=1, 2,..., Un-before.on priorities for dataWpped.n1,Wpped.n2, ...,Wpped.nUn-pped.dataP(Wpped.n1),P(Wpped.n2), ...,P(Wpped.n(u2-1)) about the predicted probabilities of choice when deciding warning scriptWpped.n1orWpped.n2, ..., orWpped.nUn-pped.dataWplandn.n1,Wplandn.n2, ...,Wplandn.nUn-plandn.on target scripts used to support decision-making for improving the efficiency of the n-th activity organizational systems, data on the number of U and data u3=1, 2, ..., Un-plan.on priorities for dataWplandn.n1,Wplandn.n2, ...,Wplandn.nUn-plandn.dataP(Wplandn.n1),P(Wplandn.n2), ...,P(Wplandn.n(u3-1))about the predicted probabilities of choice when deciding planned scriptWpland n.n1orWplandn.n2, ..., orWplandn.nUn-plandn..

21. The system under item 1, characterized in that the control m-th unit of the organizational system has a capability of receiving, storing and displaying data Snmabout the required state and data βnmthe priority of the n-th activity in the m-th division organizational systems, data Vnmkabout the required state and data γnmkthe priority of the k-th object of observation, which affects the n-th type of activity carried out in the m-th division organizational systems, data L_k on the number of indicators that are used to describe the state of the k-th object of observation, dataVnmklabout the required l-th indicator status and data µnmklthe priority of the l-th indicator of the state of k-th object h is the observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, with the ability to compose, store, and display dataV*nmk1on the actual l-th index of the k-th object of observation, which affects the n-th type of activity carried out in the m-th unit of the organizational system, with the possibility, in case of data changesV*nmk1compose, store, and display data screensΔV*nmk1the absolute value of the data changesV*nmk1in comparison with the data ofVnmk1data V*nmkabout the actual condition of the k-th object of observation, which affects the n-th type of activity carried out in m-ω is podrazdeleniye organizational systems, data S*nmon the actual state of the n-th activity in the m-th division organizational systems, data ΔS*nmthe performance data of the n-th activity in the m-th unit of the organizational system, with data transfer capabilityV*nmk1,V*nmk1V*nmkS*nmand ΔS*nmin the control center and situational tanks from the system situational tanks organizational systems, capable of receiving, storing and displaying data ΔSnm-Crete.the performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual indicator indicates the existence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action for its elimination, data ΔSnm-extrathe performance data of the n-th activity in the m-th unit of the organizational system, decrease, compared with which, the actual indicator has enabled the possibility of the emergence of threats to the n-th activity in the m-th unit of the organizational system and the need to take action to prevent the emergence of threats, dataWKpandt.nm1,WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt.critical scenarios, designed to support the decision to eliminate threats to the n-th activity in the m-th unit of the organizational system, data on the number of Ynm-Crete.and data y1=1, 2, ..., Ynm-Crete.on priorities for dataWKpandt.nm1,WKpandt.nm2, ...,WKpandt.nmYnm-Kpandt., d is the R P(WKpandt.nm1),P(WKpandt.nm2), ...,P(WKpandt.nm(y1-1))about the predicted probabilities of choice when deciding critical scriptWKpandt.nm1orWKpandt.nm2, ..., orWKpandt.nmYnm-Kpandt.dataWpped .nm1,Wpped.nm2, ...,Wpped.nmYnm-pped.warning scenarios that are designed to support decision-making for the prevention of threats to the n-th activity in the m-th unit of the organizational system, data on the number of Ynm-before.and data y2=1, 2, ..., Ynm-before.on priorities for dataWpped.nm1,Wpped.nm2, ...,Wpped.nmYnm-pped.dataP(W ped.nm1),P(Wpped.nm2), ...,P(Wpped.nm(y2-1))about the predicted probabilities of choice when deciding warning scriptWpped.nm1orWpped.nm2, ..., orWpped.nmYnm-pped.dataWplandn.nm1img src="http://img.russianpatents.com/1185/11853417-s.jpg" height="7" width="12" /> ,Wplandn.nm2, ...,Wplandn.nmYnm-plandn.on target scripts used to support decision-making for improving the efficiency of the n-th activity in the m-th unit of the organizational system, data on the number of Ynm-plan.and data y3=1, 2, ..., Ynm-plan.on priorities for dataWplandn.nm1,Wplandn.nm2, ...,Wplandn.nmYnm-plandn.dataP(Wplandn.nm1) ,P(Wplandn.nm2), ...,P(Wplandn.nm(y3-1))about the predicted probabilities of choice when deciding planned scriptWplandn.nm1orWplandn.nm2, ..., orWplandn.nmYnm-plandn.where n=1, 2, ..., N; m=1, 2, ..., M; k=1, 2, ..., K; l=1, 2, ..., L_k.



 

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13 cl, 4 dwg

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