RU2693680C9 - An intelligent, integrated digital platform for managing large systems, and a way to manage large systems - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to intelligent self-trained automated systems for generating control solutions in a selected field of use and discloses a device, method and system of functions of an intelligent integrated digital platform designed to control large systems, for example, economic, based on analogue-to-digital transformations of universal morphological models using neural networks. Technical result is achieved by architecture with separation into independent and functionally interconnected analogue-to-digital conversion units, with own information storage device each, forming virtual representations of external environment with controlled system, a control system with actuators, future required states of the controlled system, which, interacting with each other in a certain manner in the mode of constantly executing cycles, are trained, self-trained and form the required control decisions permanently.

EFFECT: high adaptability of the intelligent integrated digital platform (IIDP) (hereinafter, the control system) to environment factors of the controlled system, to the application and scalability conditions in the virtual space and the system time of the IIDP, functional resources of analogue-to-digital conversions for making required decisions, for example, economic.

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Description

The invention relates to the field of intelligent self-learning automated systems for the formation of control solutions in the chosen field of application and does not apply to automated systems and military equipment.

From the field of technology known methods and devices that implement the individual elements of the claimed device and method.

RU 2626550 C1 dated 09.08.2016 Software-hardware platform and method of its implementation for wireless communications, Joint-stock company "Research Institute of Microelectronic Apparatus Progress" (RU).

The invention relates to the field of data processing, and more specifically to specialized, connected, programmable computing systems with parallelization and pipelining of computing processes. The technical result consists in increasing the adaptability to the conditions of application and scalability of the functional resources of the software and hardware platform.

RU 2541219 C2 of 11/01/2011 Personalized dictionary for digital assistant, APPL Inc. (US)

The invention relates to computer technology, and in particular to systems such as intelligent automated assistants. The technical result is the automation of user interaction and a number of personalized dictionary devices.

CN 105743881 (А) - 2016-07-06 Media-content business-process integrated control application cloud platform (Media content, business process of integrated management of applications of the cloud platform), CHENGDU SOBEY DIGITAL TECH CO LTD.

The present invention discloses a cloud application platform for managing the integration of multimedia content business process applications, which includes a cloud services desktop, a data acquisition module, a video editor editing module, a single service data management module, and a manual input management service module.

CN 106169167 (A) - 2016-11-30 Management cloud management service platform (CHI), CHENGDU SOBEY DIGITAL TECH CO LTD.

The present invention discloses a method, apparatus and system for managing an intelligent cloud platform that are related to the field of intelligent services for the elderly.

US 2018053114 (A1) - 2018-02-22 Artificial intelligence for context classifier, BRIGHTERION Inc. (US) (Artificial Intelligence to classify context)

The artificial intelligence system includes a computer network server that is connected to receive and analyze many (millions) simultaneous text and / or voice messages in natural languages. Key words or other important words in sentences are recognized and grouped. Each such word contributes to the qualia generator, which generates the word in its possible contexts, themes or other meanings that may exist at the level of sentences, paragraphs and texts. A thesaurus-like table is used to expand the meanings of each word in a range of discrete definitions. Several such tables are used as templates for others to find passages that demonstrate the convergence of meanings. Once the context of the whole message is determined, each paragraph is deconstructed into subcontexts that correspond to a common theme. So specific contexts are then used to produce meaningful output.

WO 2009003072 (A2) - 2008-12-31 Integrated platform for user input of DIGITAL Inc. (A comprehensive platform for user input of digital symbols)

A technology is described that provides an integrated platform for users that allows the use of various types of digital symbols (for example, handwritten characters, scribbled figures, handwritten formulas) when interacting with computer programs.

All of the listed solutions known from the technical field have technical results in their manifestations that are far from the result to which the claimed invention is technically directed. The essential features of these inventions are essentially not consistent with the features of the claimed invention in their essence, therefore the closest analogue, which could be taken as a prototype, was not found.

The technical task, the solution of which the claimed invention is directed, is the creation of a universal, inter-object system for processing unstructured and non-formalized information, which is used in managing large systems using artificial intelligence (AI), and is to search for options for controlling actions for a given objective function in determine a given aggregate indicator (objective function). The solution of this problem is ensured by the fact that the method of creating and building an intelligent integrated digital platform (hereinafter IICIP) in AI systems allows formalizing the input information into a universal morphological (structural) matrix of the object under study (problem to be solved, problems) and, based on this matrix, determine the correlation dependencies elements and combinatorially form all possible options for the implementation of the object under study (tasks, problems) with a given main goal function. The theoretical foundations of this method are set forth in the monograph by A.A. Nazarov "Morphological forecasting." - Ministry of Defense of the USSR, 1986. - 248 p. [1].

The proposed method and system allows to solve the main problem of modern artificial intelligent systems - to create a PICI working in multi-media and data processing centers (DPC), which in turn will solve the problem of building optimal strategies for the development of large systems with a large amount of heterogeneous external information, forecasting and management.

PPI, taking into account external relations (Fig. 1), includes:

1 is a block of the information body of a virtual representation of the current state of the controlled system in the external environment;

2 - block of the information body of the Universum;

3 - information recognition device;

4 - virtual cursor block;

5 - optical information sensor;

5A is an input device for converting optical information;

5P - a device for recognition of converted optical information;

5B — output device for transmitting converted optical information;

6 - channels of synchronized transfer of the converted information;

7 - information harmonic oscillator - generator of internal clock time;

7B — output device for transmitting clocks of the internal clock time;

8 - sound information sensor;

8A - input device for converting audio information;

8P - device for recognition of converted audio information;

8B - output device for transmitting the converted audio information to the information storage (to the database);

9 - block of short-term memory;

9B - output device for transmitting information of the short-term memory matrix with the parameter values of the current and near future states of the controlled system;

10 - sensors of other forms of information;

10A — input devices for converting other forms of information;

10P - devices for recognition of transformed other forms of information;

10B - output devices for transferring converted other forms of information;

11 - input channels of synchronized optical, sound and other forms of information in the block of short-term memory;

12 - information storage (database);

13 is a block of predictive information about the controlled system in the next cycle (future) time;

13A - input device of the predictive information about the controlled system in the next cycle (future) time, sent to the block of short-term memory;

14 is a unit for generating predictive information about the controlled system in the next cycle (future) time;

15 - block preparation and transfer (actual) information about the state change of the controlled system under the influence of a command from the command block, formed on the basis of the predictive information for one clock cycle clock;

16 - unit of formation of information about the predictive status of T-IICP;

16A — input device of the virtual cursor block;

17 is a block of information synchronization of the current and predictive states of T-IICP;

18 - a block confirming the presence in the database of information about the current state of the Universe;

19 - command block T-IICP;

20 - recognition device (neural network) of current information from the database on the current state of the Universe;

21 - the executive body of T-IICIP of influence on the controlled system for executing a command from the command block T-IICIP and for transmitting relevant information to the information body of virtual representations;

21A — input device of the virtual cursor block for up-to-date information from the information store on the current state of T-IITS;

22 is a block of information about the Universe, ordered relative to the current clock cycle;

22A is an input device for information about the Universe, ordered relative to the current clock cycle;

23 - managed system.

Managed system 23 (Fig. 1), for example, an economic one, is a source of initial information for the PICI in various forms: optical, sound, and other. Source information through receivers (sensors) of optical information 5, audio information 8, other forms of information 10 through input devices 5A converted optical, 8A converted audio, 10A converted other forms of information enters the corresponding source information 5P, 8P, 10P devices and its codification , for example, through the corresponding blocks of neural networks, where, respectively, each source form (optical, sound, other) are assigned their own codes for each internal clock tick PPI, and which together at the inlet 11 to block short-term memory 9, for example, a processor, form a matrix with dimension values in the cells equal to the number of source data receivers. Internal time ticks are formed by ticks of a change in the state of the information harmonic oscillator 7, which changes its state depending on the change of the signal transmitted through channels 6 from source information recognition devices, and its value is one of the parameters in the code of each form of encoded information that specifies the current multidimensional values in the free cells of the matrix in the block of short-term memory 9. The same moments of the internal time are recorded together with the optics converted in devices 5A other information forms sent via output devices 5B, 8B, 10B to digital information storage 12 (database), for example, in the form of servers in an external system that are carriers of a PPI database. Each element of the storage of a digital representation of optical, sound and other information in the database 12 has an integral code representing the same element in internal clock time, a combination of the corresponding multidimensional values from the short-term memory matrix, one value from each row of this matrix, called the universal morphological (reflecting ) by the matrix of the controlled system 23. Information about the sequential values of the universal morphological matrix from the block for a short time second memory 9 into the data base 12 via the data output device 9B and the blocks 19, 17 and 15, the purpose of which is discussed below. Simultaneously and in parallel, through the output device 7B and block 14, the database receives information about the internal current time from the information harmonic oscillator 7, according to the sequence of ticks which all current states of the information storage elements 12 (database) are considered, which are considered to be the joint states of the controlled system and the IITSI . Information about the successive values of the universal morphological matrix, received in block 17, from block 17 goes to block 16, where it is corrected in the direction from the past to the future according to the internal current time, information about the beat of which came to block 14 from the information harmonic oscillator 7, and then it is directed through the input device 16A to the virtual cursor block 4. In the same block of the virtual cursor 4 from the executive body 21, which, at the command of the command block 19, acts on the controlled system he is 23, through the input device 21A receives information about the last command impact on the managed system 23 at the current time of the clock time. The overall image of the controlled system 23 from block 22 through the input device 22A and information recognition 3, similar to the 5P, 8P and 10P devices, is fed to block 2 of the Universum information body, which contains information about the controlled system and the external environment, accumulated over the entire duration of the IITS, from where it comes to block 1 of the information body of the virtual representation of the current state of the controlled system 23 in the external environment, where the virtual representation of the PPII is transmitted to the current state via the block of the virtual cursor 4 ui From this block 1 of the information body of the virtual representation of the current state of the controlled system 23 in the external environment, information in optical, sound and other forms goes synchronously to the corresponding initial information in various forms: optical, sound and other, to the corresponding source 5P, 8P, 10P devices information and its codification, and synchronism is provided by the action of the information harmonic oscillator 7. The same information from block 1, combined (through the composition operation) with the original synchronized information is sent through the devices 5B, 8B, 10B to the database 12 IITSP. The cycles of the previously described information transformations are repeated.

The information conversion cycles regarding the PII include an external cycle and a number of internal information conversion cycles.

The external data transformation cycle links (Fig. 2) the PPI, as a whole, represented by the Core IPCP (I-PPIC), the PPII Shell (O-PPII), which together form the Body of the PPII (T-PPIC) or the PPI in general with the controlled system 23, which interacts with the environment 24 relative to the PPI. In this case, as the external environment 24 affects (b) the controlled system 23, and the controlled system 23 has an impact (a) on the external environment.

FIG. 2:

position indexing continues to index the positions in FIG. one:

24 - the external environment in relation to the controlled system 23 and the control system (IICL, the Body of the IICIP);

25 is a blocking arrangement (performing a composition operation);

26 is a device for obtaining and differentiating information according to the forms of information.

From the side of the PPII, the controlled system 23 is also affected through the executive bodies 21 in accordance with the commands from the command block 19, formed according to the information on the state of the controlled system 23, the external environment 24, the PPII, which together form the Universe, which comes as information storage data) 12, and from the block of short-term memory 9 through the device 9B with the values of the parameters of the matrix of short-term memory about the current and near future states of the controlled system 23. Information about the states of control oh system 23 is compiled (combined according to the rules of composition) in block 25 with information about the current and near future states of the external environment 24, and enters the general information flow in various forms and from various sources into the external information system 26 according to its forms, from which 5, 8, 10 through the corresponding input devices 5A of the converted optical, 8A of the converted audio, 10A of the transformed other forms of information enters the I-IITS: in the system of analog-digital transformations of information in the IITS.

The analog-digital nature of I-PICI is reflected in the purpose and interaction of I-PICI blocks, although technically these blocks can have the same execution. Such blocks are: block 2 of the information body of the Universe - the long-term memory of the I-IITSP; unit 1 of the information body of the virtual representation of the current state of the controlled system in the external environment - the inner vision of I-IITSP; block 4 of the virtual cursor; block 9 short-term memory. The named blocks each have their own purpose, and cannot perform other functions in the I-PICI system except for the indicated functions.

Unit 2 of the Information Body of the Universe (or the long-term I-PICI memory) is intended to form and maintain in its devices the Universe Information Body of the semantic network of the external environment, including the semantic networks of the controlled system and the IITS itself (the control system), that is, the structure of the knowledge base Universum at I-PICI.

Unit 2 of the informational body of the virtual representation of the current state of the controlled system in the external environment (internal vision I-IITSP) is designed to reproduce in its devices the appearance (or analog description) of the current state of the controlled system inscribed in the Universe body. In the mode of obtaining information (information exchange) from the external environment in the block is formed and maintained the appearance of the current state of the system. In the blocking mode, the receipt of information from the surrounding space in the block forms and maintains the appearance of the state of the controlled system, generated from the block of the information body of the Universe (inner vision I-CIDI). The formation of the generated appearance is an element of the intellectual function of the IICI.

Block 4 of the virtual cursor is designed to maintain the appearance of the IITS, the current clock time in the mode of obtaining information from the external environment, or to maintain the appearance of the IITS synchronized at the clock time with the tact of the state of the controlled system generated from the Universe block of receiving information information from the surrounding space. Block 4 is an active element of the intellectual function of the PPI.

Block 9 short-term memory is designed to obtain information in the mode of obtaining information from the external environment and the formation of clock cycles on the basis of changes in the received information about the appearance of the controlled system. Changes in the information received form the basis for building and building up the structure of the Universe semantic network in the Universe Information Body block.

These blocks (2, 1, 4, 9, Fig. 1) are built from devices of the same purpose, allowing to recognize and convert the incoming signal into the virtual structure of the semantic network, perform composing and decomposing operations (composition and decomposition), transform and encode information. virtual structures of the semantic network of the corresponding system in the output signal, store the relevant information in the form of a universal digital morphological matrix.

The content of the operations of composition and decomposition (defined in [1]) for a graphic (pictorial, textual and other similar type) description of objects is as follows, for example:

if (abc) is an object, then its decomposition in base (a) gives a pair (a) and (abc), in base (b) - a pair (ab) and (bc), in base (c) - a pair (abc) and (c);

if (ab) and (bc) are objects, then the composition by base (a) is not defined, by base (b) gives (abc), by base (c) is not defined.

Composition and decomposition operations provide operational bases for the transformation of information in the described conversion cycles.

In accordance with the indicated blocks (2, 1, 4, 9), internal cycles of information transformations are formed.

The cycle of long-term memory. It includes transformations of information (for example, optical information) in the subsystem of I-IITSI units and devices. Depending on the contents of commands from the command block 19 and the parameters of the current and forecast states of the controlled system, the information body of the Universe in block 2 is brought into the corresponding state, and gives the description in the form of a universal morphological matrix to block 1. From block 1 of the information body of the virtual presentation information through the device 5B enters the O-IPCP system, from where via the command block 19, through the information generation unit 16 of the current and predicted states of the PPMI is sent to the information block 2 la universe. Then the cycle repeats.

In the absence of information (signals) from the device 5A from block 1 (in the mode of blocking the receipt of information from the surrounding space) information about the state of the controlled system, like information about the possible state of the controlled system, is also sent again through blocks 19 and 16 to block 2. Since information on the state change of the controlled system was not received at the same time, the PICI continues the process of generating information on the possible states of the controlled system according to the transformations generated by unit 4 when moving from the current to eduyuschemu clock cycle of the clock time specified by the information harmonic oscillator 7.

The I-IPCP cycle of internal vision with block 1 of the informational body of the virtual presentation of the current state of the controlled system in the environment is implemented in two versions: information about the current state comes from devices that perceive this information from the environment 24 and the controlled system 23 directly and, further, for example, for optical information, through 5A enters unit 1 in a virtual presentation device, where either changes the virtual representation of the state of the controlled system 23, which corresponds to It is the previous measure of the clock time, or stores it in the absence of recorded sensor 5 and 5A the device state changes. Information about the changed or saved state of the controlled system is converted by the device into digital form of the cell values of the universal morphological matrix, which is sent to the information storage (database) 12 through the device 5B, where it is stored with the assigned data about the position of the controlled system in the Universe, clock time, scale and other state factors that set the values in the rows of the universal morphological matrix. The information contained in the base 12 in the form of a universal morphological matrix, according to the pattern recognition technology in blocks 18 and 20, is transformed into a structure of the semantic description of the controlled system in the external environment, which through the input device 21A enters the block 1 into the virtual presentation device. In parallel, after the action of the executive bodies of the unit 21 on the controlled system 23 and its state changes, information from the controlled system 23 in the external environment 24 is fixed by the sensor 5 and the input device 5A. The cycle of the first option is completed and ready for repetition. The second option (in the mode of blocking the receipt of information from the surrounding space 24) is characterized as the work of the IITS in the sleep state regarding interaction with the controlled system. The source of information reproduced in block 1 in the device of the virtual presentation is the block 22 of information about the Universe. Information in block 1 is received through the input device 21A. In this cycle, in block 1, a virtual representation of the states of the controlled system 24 is supported in the absence of direct contact: the inner vision of the I-ICCP.

The cycle of the virtual cursor in block 1 forms the main intellectual function of the DICI to make decisions for the implementation of the actions of the executive body 21 for managing the system 23.

The virtual cursor is a virtual representation of the set of executive bodies 21 in the virtual representation of the structure of the semantic system of Universum 22, by means of which the analogue of the controlled system is transferred from a given clock state to the next clock state, as a subsystem in the structure of the semantic system of the Universum. A virtual cursor specifying the tact of the clock time, scale and individual parameters of the executive bodies can be moved along the structure of the Universe semantic system in the desired direction (hence the name - the cursor).

The initial information about the state of the managed system, which is affected by the executive bodies 21 of the IICIP, through the input device 5A (for optical information) and the 5P recognition device enters the short-term memory block 9, in which are formed: the initial actual virtual representations for structural relationships in the Universe semantic system , including relations with the executive bodies of the IICL, as well as the corresponding representations in the form of blocks of a universal morphological matrix. These packages of mutually defined representations are digitally forwarded through blocks 19 and 18 to a device for recognizing actual information about the current state of Universe 20, from where they get to block 22 of information about the Universe to form the structure of the Universe semantic system, including the structure of relations with executive bodies (the basis of the structure and corresponding representations of the virtual cursor in block 4). At the same time (at the same clock time), the same packets of mutually defined representations in digital form are sent through the input device 21A to block 4 of the virtual cursor. The virtual representations of the virtual cursor in block 4 and in block 2, reproduced according to the structure of the knowledge base of block 22, are mutually compared (and correlated by the parameters of the universal morphological matrix), arranged and, further forming a single virtual structure, are converted into the required representations of the virtual cursor. The virtual cursor is reproduced in block 1 of the internal view, where it acts as an operator for converting an analog of the current state of the controlled system to the next required (or possible predictive) state, thereby completing the virtual cursor cycle and the cycle of solving the problem of transferring the controlled system to the next clock cycle time . Then the cycle repeats. As well as other considered cycles of information transformations, the virtual cursor cycle has an obvious option that corresponds to the blocking mode of receiving information through the device 5A.

The short-term memory cycle provides the formation of clock cycles by recording changes in the states of the controlled system 23 in the external environment 24. The changes are fixed by permanently comparing information in a standard form (universal morphological matrix) that goes through the 5P recognition device. In block 9, the compositing is performed, and the deviation of any parameter being compared from the value in standard form determines the next clock cycle time in the I-PPID system. The time scale formed by these cycles in block 7 is considered as the system time scale, in which all operations of converting information of the considered cycles are defined.

In the block subsystem: 1 - the information body of the virtual representation of the current state of the IICIP cycle in the external environment (or - I-IICIP internal vision); 2 - the information body of the Universe (or the long-term memory of the I-IITSP); 4 - a virtual cursor designed to maintain the virtual representation of the IITS, the current clock time; - the main (intellectual) function of the IICI for managing the controlled system in the external environment is realized. The implementation of the main (intellectual) function of the IITS is to find and select the best (by some set of criteria) solutions, allowing to transfer the controlled system from the current state S _o to the desired future state S _k . The possibility of achieving the required best (according to a certain set of criteria) solutions is provided by: a) using special tools for processing information of various kinds (optical, sound and other) that allows its presentation in the Universe semantic network; b) the representation of the Universe semantic network by a universal morphological model (matrix); and c) the ability of the ICPI for learning and self-study in a given subject area.

In the block of virtual cursor 4, using the above tools, the permissible formation of the structure of the IITS executive bodies is based on the current current clock time of the control system, synchronized in clock time with the tact of the state of the controlled system generated from the Universe Information Body block 2, so that the composition of this permissible structure and appearance of the current structure of the controlled system is equal to the required trukture controlled system. The described cycle of formation of the required structure of the controlled system is a constantly carried out cycle of the normal state of the PPI.

Due to the fact that the claims must clearly express the essence of the invention as a technical solution (contain a set of essential features, including a generic concept reflecting the purpose of the invention, sufficient to solve the technical problem indicated by the applicant and to obtain a technical result in the implementation of the invention), in the formula For disclosing features of the invention, explanations and references are provided to the figures of the invention. These references allow you to avoid violation of the requirements for the formula of clarity and clarity of its presentation and to ensure the possibility of understanding the semantic content of signs on the basis of the level of technology specialist in this field of technology.

References.

1. A.A. Nazarov "Morphological forecasting." - Ministry of Defense of the USSR, 1986. - 248 p.

2. RU 2626550 C1, 08.09.2016

3. RU 2541219 C2, 11.01.2011

4. RU 174646 U1, 05.24.2017

5. RU 2406129 C2, 03.30.2006

6. RU 2425417C2, 01.27.2006

7. RU 2581784 C2, 11.02.2011

8. US2018053114 (A1), 02.22.2018

9. US2010198888 (A1) 08/05/2010

10. US 2016283923 (A1) 09/29/2016

11. CN 103258188 (A), 08.21.2013

12. CN 105743881 (A), 07/06/2016

13. CN 106169167 (A), 11/30/2016

14. WO 2009003072 (A2), 12/31/2008

Claims (18)

1. Intellectual integrated digital platform (IITSP), designed to manage large systems, including the body of the IITS (T-IITSP) and external information system, characterized in that T-ICCP consists of two mutually related systems: systems of analog-digital transformations of information using neural networks, which is the core of the IITS (I-IITSP), and systems of Universum database units (IICIP with a controlled system and external environment), the command block, the executive bodies of the TIICP and information sensors from the controlled system, which is the IITCP shell (O-IICIP); in which I-ICCP consists of blocks and devices: block 1 of the information body of the virtual representation of the current state of the controlled system in the external environment, which is connected to the block 2 of the information body of the Universe connected to the information recognition device 3 connected to the input device 22A of the Universe information, ordered relative to the current clock cycle; block 4 of the virtual cursor connected to the input device 16A of the virtual cursor block and with the input device 21A of the virtual cursor block for up-to-date information from the TI CPSI current state information store and connected to block 1 of the information body of the virtual representation of the current state of the controlled system in the external environment and with block 2 of the information body of the Universum; block 9 short-term memory connected via input channels 11 synchronized optical and sound information into block short-term memory through the device 5P recognition of the converted optical information with the input device 5A convert optical information, through the device 8P recognition of the converted audio information with the input device 8A convert audio information, and also with the input device 13A of the predictive information about the controlled system in the next cycle (future) cycles The first time sent to block 9 of short-term memory, with output device 9B for transmitting information of the short-term memory matrix with parameter values of the current and nearest future states of the controlled system, where the input devices 5A of optical information conversion and 8A of audio information conversion, are interrelated with block 1 of information the bodies of the virtual representation of the current state of the controlled system in the external environment and are connected — the first with the output device 5B of the transfer of the transformed optical information in the information storage (in the database), and the second with output device 8B for transferring the converted audio information to the information storage (in the database), and where the 5P optical information recognition and 8P audio information recognition devices are each connected via synchronized channels 6 transferring the converted information to the informational harmonic oscillator 7 (internal clock time generator), which is connected to the short-term memory unit 9 and to the output device 7B of the transmission internal clock ticks in block 14 of generating forecast information about the controlled system to the next clock (future) time, transmitting this information to block 13 of the forecast information about the controlled system in the next clock cycle (future), connected through the input device 13A of the forecast information about the controlled system in the next clock (future) clock time with block 9 short-term memory; storage information (database) 12, connected, on the one hand, through output devices 5B and 8B with devices 5P recognition of the converted optical information and 8P recognition of the converted audio information, respectively, and, on the other hand, associated with the device 20 recognition of relevant information from the database of the current state of the Universe associated with the Universe information block 22, ordered relative to the current clock cycle, which is associated with the Univer information input device 22A sum, ordered relative to the current clock time, as well as with block 14 of generating forecast information about the controlled system in the next clock (future) time; block 16 of the formation of information about the predictive state of T-IITSP connected through the input device 16A of the virtual cursor block with block 4 of the virtual cursor; block 15 preparation and transmission of relevant information about the state change of the controlled system under the influence of a command from the command block, formed on the basis of the predictive information for one clock cycle tick time associated with the information store (database) 12, on the one hand, and through the block 17 synchronization information the current and forecast states of the T-IPCP, interconnected with the information storage (database) 12, with the block 16 of the formation of information about the predicted status of the T-PPII; and in which О-ИИЦП consists of blocks and devices: command block 19 T-IICI, which, on the one hand, is mutually connected with block 18 confirming the presence in the database of information about the current state of the Universe, associated with the information store (database) 12 and with the device 20 recognizing actual information from the database of current the Universe state, and, on the other hand, is connected with the output device 9B of transmitting information of the short-term memory matrix with the parameter values of the current and near future states of the controlled system, and also is connected with the executive body 21 -ICPL impact on the managed system 23 to execute a command from the command block T-IICIP, where the executive body 21 T-IICIP is associated with the unit 22 of information about the Universe, ordered relative to the current clock time cycle, and connected with the input device 21A of the virtual cursor block for the current information from the repository of information about the current state of T-IPCP; sensors 5 optical information and 8 audio information associated, respectively, with input devices convert 5A optical and 8A audio information; and providing the specified control of the managed system 23 in the external environment 24 with respect to the controlled system and the PPII in a manner of performing a series of information processing cycles based on the fact that: source information through sensors 5 optical and 8 audio information through input devices 5A converted optical and 8A converted audio information enters the corresponding device 5P and 8P recognition of the converted optical and audio information and its codification, for example, through the corresponding blocks of neural networks, where each source form (optical and sound) are assigned their own codes for each clock cycle of the internal clock time T-IITSP, and which together in the input The analogue 11 synchronized optical and sound information in block 9 of short-term memory forms a matrix with dimensions in the cells equal to the number of recognizable forms of the initial information, and the internal clock ticks of T-IITS are formed by the ticks of the state of the information harmonic oscillator 7, changing its state depending on changes in the signal transmitted by the channels 6 of synchronized transfer of the converted information from the 5P and 8P recognition devices of the converted optical and audio information, and the internal clock clock T-PIDI value is included in each code of each source form (optical and sound) in each cell of the formed matrix in block 9 of short-term memory, and information about the assigned codes through output devices 5B and 8B of the converted optical and sound information enters the information repository 12 (database), for example, in the form of the IITS database servers in the external environment, in which the universal morphological matrix of the Universe is formed with the values of all possible states controlled system 23, which are ordered by the values of the matrix from block 9 short-term memory, information about which is fed to the recognition device 20 (neural network) of relevant information from the database of the current state of the Universe and, further, into block 22 of the Universe information, ordered relatively the current clock cycle time, through the output device 9B of transmitting information of the short-term memory matrix with the parameter values of the current and near future states of the controlled system, through the command block 19 T-IITS and through block 18 confirm the presence in the database of information about the current state of the Universum, where simultaneously, in parallel and sequentially through the output device 7B and block 14 of the formation of predictive information about the controlled system, the current (future) time tick arrives tact and the next (future) tact of the internal clock time T-IITSP, and the predictive information about the controlled system from block 14 enters the block 16 of the formation of information about the predicted state T-IITSP, where through the input device 16A is sent to block 4 of the virtual cursor, which simultaneously from the executive body 21, which, at the command of the command unit 19 T-CIDI, acts on the controlled system 23, through the input device 21A receives information about the last command of the impact on the controlled system 23 at the current clock time, and information about the change in the state of the controlled system 23 from the unit 22 of the information about the Universe, ordered relative to the current clock time cycle, through the input device 22A, through the device 3 Recognition of information enters unit 2 of the Universum information body, which contains information about the controlled system in the external environment, accumulated over the entire duration of the PICI, from where it is sent to block 1 of the virtual information information body of the current state of the controlled system in the external environment, where information from virtual the cursor about the changed state of the controlled system in the external environment, which is confirmed or not confirmed by information from the input devices 5A and 8A, which also enters the block 1, what determines the choice of the next action (the impact on the controlled system 23) from the side of the IICL depending on the criteria that are formed by the IICI in the universal morphological matrix of blocks 20 and 22; after which the cycles of information processing and actions of the PICI are repeated. 2. An intelligent integrated digital platform according to claim 1, characterized in that, in addition to the optical and sound forms of information, the process of interaction with other forms of information is added and further comprises: sensors of other forms of information; recognition devices for transformed other forms of information; output devices for transferring converted other forms of information to the information storage; a block of input devices for converting other forms of information; in this case, a valid formation of the structure, functions, actions of the executive bodies of the control system (IITS) is carried out using the toolkit based on the current clock time of the control system representation that is synchronized at the clock time with the clock appearance of the state of the controlled system generated from the block of the Universe information body, so that the composition of this allowable structure Temperature and shape of the current control system structure equal to the desired structure of the control system, the described cycle of formation of the required structure of the controlled system is constantly carried out cycle IITSP normal state. 3. The method of managing large systems using an intelligent integrated digital platform (PII) according to claim 1, characterized in that in the virtual cursor block using the above toolkit, the permissible formation of the structure, functions, actions of the executive bodies of the management system (PII) is carried out the current current clock time of the control system representation, synchronized at the clock time with the tact of the state of the controlled system generated from the info block of the Universe of the body, so that the composition of this permissible structure and appearance of the current structure of the controlled system is equal to the required structure of the controlled system; The described cycle of formation of the required structure of the controlled system is a constantly carried out cycle of the normal state of the PII; Thus, the architecture is divided into independent and functionally interconnected blocks of analog-digital transformations, each with its own storage device, forming virtual representations of the external environment with a controlled system, a control system with executive bodies, future required states of the controlled system, which, interacting with each other in a certain way in the mode of constantly carried out cycles, undergo training, self-study and form the required control solutions p permanently.

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