KR101774844B1 - Self-learning module of artificial neural network model using neuro-blockchain combination - Google Patents

Abstract

The present invention relates to a self-learning module of an artificial neural network model using a neuro-block/chain combination, learning a deoxyribonucleic acid (DNA) model by a combination of chain learning and block learning performed in chain and block learning units, respectively. According to the present invention, the model comprises: an input unit to receive a DNA mission which is a function of elements and positions, and is formed with one or more mission modules, and a DNA model which is an artificial neural network model formed with the DNA mission; the chain learning unit to perform learning about a chain interconnecting an activated position of the received DNA mission with other positions; and the block learning unit to perform learning in the activated mission module when the mission module forming the received DNA mission is activated.

Description

[0001] SELF-LEARNING MODULE OF ARTIFICIAL NEURAL NETWORK MODEL USING NEURO-BLOCKCHAIN COMBINATION [0002]

The present invention relates to a self learning module of an artificial neural network model, and more specifically, to a self learning module of an artificial neural network model using a neuroblock chain combination.

Research has been steadily carried out to technologically implement human brain mechanisms to understand and analyze given situations or situations and make decisions. Especially, as the interest in artificial intelligence has increased, AI technology has been dramatically developed through deep learning based on artificial neural network.

In addition, in software engineering, there is an increasing demand for self-adaptive technology to grasp the situation of users and devices and provide customized user services for a better user experience, and is being applied to various fields.

However, there has been little research on self - adaptive learning that combines deep learning - based learning techniques or artificial neural networks with self - adaptive technology in software engineering.

In particular, the artificial neural network model has not been developed so far in order to effectively implement the human brain mechanism to think and solve the problem variably depending on the situation.

As a prior art related to the present invention, Japanese Laid-Open Patent Application No. 10-2012-0057319 (entitled " Intelligent Sensor Middleware Structure Applicable to Various Environments and Self-Adaptable for Smart Environment Configuration, Published Date: June 2012 2005, published patent application No. 10-1999-0044063 (entitled " Method of providing self-adaptive management service using information communication network, published on May 07, 2001).

The present invention has been proposed in order to solve the above-described problems of the previously proposed methods. The present invention provides a DNA model by a combination of chain learning and block learning by performing chain learning and block learning by receiving a DNA mission and a DNA model. The neural network model using neuroblock chain combination, which can be learned, and the DNA model can be changed flexibly through self-learning according to the change of time and situation, And to provide a self learning module.

The present invention also includes a mission that provides indirect and moderate support for decision making and a direct and immediate support for decision making by including unconditional learning of the accepting block learning unit and conditional learning of the reactive block learning unit Learning module of an artificial neural network model using a neuroblock chain combination, in which a DNA model can be self-learned for all of the neural network models.

According to an aspect of the present invention, there is provided a self learning module of an artificial neural network model using a neuroblock chain combination,

As a learning module for learning an artificial neural network model,

An input unit for receiving a DNA mission, which is a function of elements and positions and is composed of at least one mission module, and an artificial neural network model constructed using a DNA mission;

A chain learning unit for learning a chain connecting the activated position and the other position of the input DNA mission; And

And a block learning unit for performing learning in the activated mission module when the mission module constituting the inputted DNA mission is activated,

And that the DNA model is learned by a combination of chain learning and block learning performed by the chain learning unit and the block learning unit, respectively.

Preferably,

Wherein the DNA model comprises a sum of at least one functional sub-model,

The functional lower model can be learned while being varied in accordance with the passage of time by the combination of the chain learning and the block learning to generate the learned DNA model.

Preferably, in the case of pre-training of the DNA model,

The chain learning unit may perform chain learning for all chains interconnecting the activated position and another position.

Preferably, in the case of self-learning of the pre-trained DNA model,

Wherein the block learning unit self-performs block learning of the pre-trained DNA model in a mission module activated by an element input in accordance with a time,

The chain learning unit may perform chain learning for all upper positions connected to positions in the mission module when the block learning ends.

Preferably, the block learning unit includes:

An adaptive block learning method that calculates an optimal comparison compensation value according to a correlation between an input element and a predefined element in a position block of the mission module in a time block composed of at least one unit time and unconditionally learns part; And

And a reactive block learning unit that calculates the reference compensation value and the compensation compensation value according to the correlation between the element input during the unit time and the element defined in the position of the mission module and conditionally learns.

More preferably, the accommodative block learning unit includes:

Setting a time when the mission module is activated as a reference time, setting a unit time and a time block based on the reference time, calculating and storing a comparison compensation value for each set unit time, Block learning can be performed by selecting an optimal comparison compensation value among the stored comparison compensation values.

More preferably, the reactive block learning unit includes:

A reference compensation value is calculated within a set unit time, and a comparison compensation value calculated in a next unit time is calculated based on the reference compensation value, If it is larger than the reference compensation value, the comparison compensation value can be changed to the reference compensation value and the block learning can be performed.

According to the self learning module of the artificial neural network model using the neuroblock chain combination proposed in the present invention, the DNA mission and the DNA model are received and the chain learning and the block learning are performed. By the combination of the chain learning and the block learning, And the DNA model can be changed flexibly through self-learning according to the change of time and situation, and the human brain mechanism can be implemented effectively using this.

Further, according to the present invention, by including unconditional learning of the accepting block learning unit and conditional learning of the reactive block learning unit, it is possible to provide direct and immediate support to the mission and action decision to provide indirect and intermediate support to the decision DNA models can be self-learning for all missions.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram illustrating an overall configuration of an artificial intelligence platform using a deep learning-based self-adaptive learning technique including a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. FIG.
FIG. 2 illustrates a method of self-organizing a DNA mission in a self-organizing module using a neuroblock chain combination according to an embodiment of the present invention. FIG.
FIG. 3 illustrates a method of self-configuring a DNA model in a self-organizing module using a Neuroblock chain combination according to an embodiment of the present invention. FIG.
FIG. 4 illustrates a basic structure of a mission self-organizing module using a neuro-block chain combination according to an embodiment of the present invention. FIG.
5 illustrates symbols of a mission self-organizing module using a neuroblock chain combination according to an embodiment of the present invention.
6 is a diagram illustrating a configuration of a mission self-organizing module using a neuro-block chain combination according to an embodiment of the present invention.
FIG. 7 is a diagram illustrating the concept of a mission self-organizing module using a neuro-block chain combination according to an embodiment of the present invention; FIG.
FIG. 8 is a detailed block diagram of a block chain activation unit in a mission self organizing module using a neuroblock chain combination according to an embodiment of the present invention; FIG.
FIG. 9 and FIG. 10 illustrate a detailed process of self-organization of a DNA mission in a self organizing module of a mission using a neuroblock chain combination according to an embodiment of the present invention. FIG.
11 is a diagram illustrating a basic structure of a self-organizing module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
12 illustrates symbols of a self-organizing module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
13 is a diagram illustrating a structure of a DNA model constructed by a self-organizing module of an artificial neural network model using neuroblock chain combination according to an embodiment of the present invention.
14 is a diagram illustrating a configuration of a self-organizing module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
15 illustrates an example of the number structure of functional sub-models constituting a DNA model in a self-organizing module of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention.
16 is a diagram showing a detailed configuration of a lower model constituent unit in a self organizing module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
17 is a diagram illustrating a method of determining the number of layers of a layer determination unit in a self-organizing module of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention.
18 is a diagram illustrating an example of a method for determining the number of nodes for node determination in a self-organizing module of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention.
19 is a diagram illustrating a process of constructing a DNA model by a self-organizing module of an artificial neural network model using a Neuroblock chain combination according to an embodiment of the present invention.
20 illustrates a basic structure of a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention;
21 is a diagram showing symbols of a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention;
22 is a diagram illustrating a configuration of a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
23 is a diagram illustrating chain learning and block learning in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
24 illustrates a self-learning process of a trained DNA model in a self-learning module of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention.
25 is a diagram showing a detailed configuration of a block learning unit in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
26 is a diagram showing a learning concept of an adaptive block learning unit in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention;
27 is a diagram illustrating a learning process of an adaptive block learning unit in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.
28 is a diagram illustrating a learning concept of a reactive block learning unit in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention;
29 is a diagram illustrating a learning process of a reactive block learning unit in a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

The present invention is based on the assumption that, in order to effectively implement the human brain mechanism, the judgment or thought in the neurons of the human brain is made by the connection between neurons and neurons between the start neurons and surrounding neurons around the start neurons . A certain part of the activated neuron is referred to as a block, a chain between neurons and neurons is represented as a chain, and a combination of blocks and chains, that is, a combination of neuroblock chains, self-organizes the mission in the human brain and self- Process can be implemented.

In the present invention, an artificial intelligence platform based on deep learning-based self-adaptive learning can be implemented and utilized by using the neuroblock chain combination. In other words, the artificial intelligence platform using the neuroblock chain combination according to an embodiment of the present invention can be applied to a human body by standing next to a human being (moving itself such as a robot or a vehicle) To carry or carry out the tasks given or given to the human being, to learn the given situations or actions in real time, and thus to make the human being And can be used effectively in areas where the mission (mission) to be performed is continuously assisted or supported by the human in real time.

More specifically, it can be applied to fields where crops are cultivated in greenhouses, fish cultures in cage farms, student education in schools, etc., in which a period of time elapses, effects such as deep sea exploration, wildfire prevention, avian influenza and foot- It is possible to analyze and learn in case of cyber attack or infringement while resident on uncertain or inaccurate field, network or network such as military battle, etc., and apply it to the field to prevent and respond to future cyber attack or infringement based on it Do.

The artificial intelligence platform including the self learning module of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention can be applied to an algorithm developed for a specific purpose such as existing artificial intelligence, , It is not a method to learn only in a laboratory etc. beforehand and put it into a field or an actual practice by a human, but a simple preliminary learning which is possible even if there is no big data, And can continue to learn in real time while performing the task together.

1 is a diagram showing an overall configuration of an artificial intelligence platform using a deep learning-based self-adaptive learning technique including a self learning module of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. 1, an artificial intelligence platform using a deep learning-based self-adaptive learning technique according to an embodiment of the present invention includes a preprocessor 10 and a self-adaptive learning engine 20 .

That is, in the present invention, the structured data and the unstructured data are processed in the preprocessor 10 to derive the elements, the self-adaptive learning engine 20 can perform self-adaptive learning using the elements, You can tailor your system to match.

Hereinafter, with reference to FIG. 1, each component constituting the artificial intelligence platform using the deep learning-based self-adaptive learning technique according to an embodiment of the present invention will be described in detail.

The preprocessor 10 may process input data to derive elements. That is, the preprocessor 10 can derive an element, which is input information of the adaptive learning engine 20, to be described later in detail from input data including structured data and unstructured data. The preprocessor 10 may include a text conversion module 11, an information extraction module 12, and an element derivation module 13.

The text conversion module 11 can convert unstructured data except text into text data in the input data (Text Conversion). In particular, the text conversion module 11 may convert unstructured data, excluding text including images, images, and sounds, into text data.

The information extraction module 12 can extract information from the text data converted by the text conversion module 11 (Information Extraction). Further, the information extraction module 12 can extract necessary information from the input data of the text form instead of the conversion object of the text conversion module 11.

The element derivation module 13 can derive an element to be input to the self-adaptive learning engine 20 from the extracted information (Element Identification & Elicitation).

The self-adaptive learning engine 20 self-organizes a DNA mission using the elements derived from the preprocessor 10 and generates a deeplaning-based artificial neural network DNA model (DNA Model) self-organizing and self-organizing DNA models. The present invention includes a self-adaptive learning engine (20) that self-organizes a DNA mission and self-configures a DNA model by combining a self-adaptive technology and a deep learning-based learning technology, You can effectively implement the human brain mechanism to model and solve the situation. 1, the self-adaptive learning engine 20 may include a self-organizing module 100, a self-organizing module 200, and a self-learning module 300. The self-

The self organizing module 100 can self-organize DNA missions using the elements derived from the preprocessor 10 (Self-Organization of DNA Mission). More specifically, the self organizing module 100 compares and evaluates the elements input in accordance with the passage of time with the elements in the mission of the predefined organization, and organizes the DNA missions, which change according to the passage of time, can do. Here, the mission is a predefined mission of the organization, and the DNA mission is different from the mission of the self-organizing module 100 of the present invention.

Meanwhile, the DNA mission organized by the self organizing module 100 may be a combination of Blocks of Organization and Chains. That is, the self organizing module 100 can organize a DNA mission by combining blocks and chains of an organization using a neuroblock chain combination technique. Further, depending on the embodiment, the DNA mission may include a special DNA mission consisting of a combination of chains.

In addition, the DNA mission may consist of a sum of mission modules, and the mission module may be a function of the elements received from the preprocessor 10 and the Positions of Organization. At this time, the position of the organization member can be predetermined.

In the present invention, in order for the implemented artificial intelligence platform to support the mission of the human being, it is necessary to perform a mission in an organization (a school, a home, a government, an institution, a corporation, a combat unit, (Position or position) of the member, and the member to which the member belongs or is located. These organizations are usually in the form of a hierarchical tree structure. In the hierarchical tree structure, there is a connection between nodes and nodes (that is, a link between a position and a position of an organization member (chain)). It can be seen as a chain, or chain, between the groups (departments in the organization) that consist of tree structures (blocks).

Thus, when using the neuroblock chain combination technique in the self organizing module 100, a chain is a link between position and position of an organization member and a link between groups within an organization having a certain organizational member. A group in which positions and positions are connected to each other, one organization may be composed of one block, or one organization may be composed of several blocks.

For example, the school is an organization, the people in the school (principals, vice-principals, teachers, students, etc.) become members of the organization, and the principal, teachers, . And, the mission given to the principal, the vice-principal, and the teachers of the school organization is to teach students, and the missions given to students may be to learn. The mission to teach or learn in this way can consist of a chain of principals, sympathizers, teachers, and students.

Also, in the above example, if the school has a principal's office, an office room, and three classes, each of which has different sub-tasks for the performance of the mission, the organization's block can be five. However, if the school is regarded only as an organization performing a single task, it may consist of only one block.

On the other hand, in the above-described five-block organization, a chain in which the blocks are connected to each other can be created. That is, the principal of the principal's office, the teacher of each subject in the school office, and the class leader of three classes can have a chain linking each other.

2 is a diagram illustrating a method of self-organizing a DNA mission in the self organizing module 100 using a Neuroblock chain combination according to an embodiment of the present invention. The self-organizing module 100 of the deep learning-based self-adaptive learning engine 20 according to an embodiment of the present invention includes an organization block (Block i, Block j, Block k, etc.) A DNA mission can be constructed by combining chains (Chain l, Chain m, Chain n, etc.). A composed DNA mission can be represented by the sum of mission modules, which are a function of the position of elements and tissue members.

In addition, a DNA mission may include a special DNA mission consisting of a combination of chains. That is, depending on the embodiment, a DNA mission may be configured by a combination of only chains without an organization block.

Detailed configuration of the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention will be described in detail with reference to FIG. 4 to FIG.

The self-organizing module 200 can self-organize deep-run based artificial neural network DNA models using self-organized DNA missions (Self-Composition of DNA Model). That is, the self-organizing module 200 can construct the artificial neural network DNA model that can receive the DNA mission from the self organizing module 100 and learn on a deep learning basis. The DNA model self-organized by the self-organizing module 200 can be a model that flexibly changes according to input data because it is constructed using a DNA mission that is self-organized by elements input in the course of time.

The DNA model can be a combination of functional blocks (Blocks of Function) and chains. That is, the self-organizing module 200 can organize a DNA model by combining functional blocks and chains using Neuroblock Chain Combination technology.

In addition, the self-organizing module 200 can self-constitute a DNA model composed of a sum of functional submodels.

Here, the function block is a function-specific set of situations in which the learning is possible in the artificial neural network model by imitating the situation judgment method of the human brain, and a block of one organization in the DNA mission is a function block in the DNA model Lt; / RTI > A simple situation can be judged by a single thought, but it can be assumed that a complex situation can be judged by multiple thoughts rather than a single thought. In the process of constructing a model for solving missions, a DNA model can be self-organized by combining functional blocks and chains in such a manner that complex situations are classified by function and grouped for judgment by using such a concept.

In the example of the school as described above, if the principal's office, the office, and the three classes have different sub-duties, the organization's blocks will be five, and the final goal of the school will be a block of five organizations Can be converted into five functional blocks with sub-tasks for each function.

3 is a diagram illustrating a method of self-configuring a DNA model in the self-organizing module 200 using a Neuroblock chain combination according to an embodiment of the present invention. The self-organizing module 200 of the deep learning-based self-adaptive learning engine 20 according to an embodiment of the present invention includes functional blocks and chains as shown in FIG. 3, Functional Submodel i, Functional Submodel j, Functional Submodel m, Functional Submodel m, and Functional Submodel n) can be constructed by combining with the combination technique, and a DNA model can be constructed by summing up functional submodels.

The detailed configuration of the mission self-configuration module 200 using the neuroblock chain combination according to an embodiment of the present invention will be described in detail later with reference to FIG. 11 to FIG.

The self-learning module 300 can self-learn a self-constructed DNA model (Self-Learning of DNA Model). That is, the self-learning module 300 is configured to learn the DNA model configured in the self-organizing module 200, and can learn through the artificial neural network technology.

Detailed configuration of the mission self-learning module 300 using the neuroblock chain combination according to an embodiment of the present invention will be described in detail with reference to FIGS. 20 to 29. FIG.

delete

delete

delete

delete

4 is a diagram illustrating a basic structure of a mission self organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention. As shown in FIG. 4, the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention includes two inputs and one output, and uses a neuroblock chain combination technique .

That is, the self organizing module 100 of the present invention can input a predefined organizational mission and elements extracted from the input data, and output a self-organized DNA mission using a combination of a block and a chain. Therefore, according to the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention, it is possible to organize the DNA mission by grasping the mission itself by using various data, and by using the human brain mechanism Can be effectively implemented.

FIG. 5 is a diagram illustrating symbols of a mission self-organizing module 100 using a Neuroblock chain combination according to an embodiment of the present invention. In FIG. 5, a blue square represents an element, an orange circle represents a position, a star represents a special element, a green square represents a mission module, and a sky blue square represents a DNA mission, and a square in a mission module represents a block and a circle represents a chain.

As shown in FIG. 5, in the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention, as the time progresses in the direction of the lower arrow, the activation condition of the neuroblock chain is satisfied , The green square of the right-hand end of the mission module and the blue square of the DNA mission can be created. Thus, as time passes, the function of the element and the position of the organization member, and the combination of the block and the chain, the mission module and the DNA mission can be organized themselves.

FIG. 6 is a diagram illustrating a configuration of a mission self organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention. 6, the mission self organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention includes a block chain comparing unit 110, a block chain activating unit 120, (130). ≪ / RTI >

FIG. 7 is a diagram illustrating the concept of a mission self organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention. Hereinafter, with reference to FIG. 6 and FIG. 7, each component constituting the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention will be described in detail.

The block chain comparison unit 110 can compare the organizational missions predefined as a function of the elements and Positions of Organization and the DNA missions in self organization using the elements extracted from the input data have. More specifically, the block-chain comparison unit 110 can compare the elements extracted from the input data with the elements of the Positions of Organization that make up the organizational mission.

Here, the organizational mission may be a predefined mission by an administrator, an organization, and the DNA mission may be a self-organized mission of the mission self-organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention. . The DNA mission is the sum of the mission modules, and the mission module can be a function of the position of the elements and tissue members. In addition, the DNA mission can consist of a combination of blocks and chains. Depending on the embodiment, there may be a special DNA mission consisting of only connections of positions not belonging to a specific tissue.

The block-chain activating unit 120 constructs chains and blocks using the elements extracted from the input data, using the comparison result of the block-chain comparing unit 110, and generates a combination of a mission module and a mission module, Can be organized and activated.

That is, if the block chain activating unit 120 satisfies the activation condition of the position, the corresponding position can be activated, and if the activation condition of the mission module or DNA mission is satisfied, the corresponding mission module or DNA mission can be activated. Elements extracted from the input data can be variably activated according to predefined positions and activation conditions of the mission module since a single element or a plurality of elements are sequentially or randomly input over time.

The detailed configuration of the block-chain activating unit 120 will be described later in detail with reference to FIG.

The position identifying unit 130 may identify a position among the elements extracted from the input data and associated with a special element that does not correspond to an element included in the organizational mission. That is, when the element extracted from the input data does not correspond to the element of the predefined position, the position identification unit 130 determines the mission module and the position to which the element belongs, May form chains in the form of special elements for the determined mission module and position. Thus, a DNA mission can have a flexible, flexible structure in which positions, mission modules and missions are organized by themselves as circumstances change.

FIG. 8 is a diagram illustrating a detailed configuration of the block-chain activating unit 120 in the mission self-organizing module 100 using the neuro-block chain combination according to an embodiment of the present invention. 8, the block chain activation unit 120 of the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention includes a position activation unit 121, A block construction unit 123, a mission module activating unit 124, and a mission organization unit 125. [0033]

FIG. 9 and FIG. 10 illustrate a detailed process of self-organization of a DNA mission in the mission self organizing module 100 using a neuroblock chain combination according to an embodiment of the present invention. 8 to 10, in the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention, when each component of the block chain activating part 120 is a block chain The process of self-organization of the DNA mission while interacting with the comparison unit 110 and the position identification unit 130 will be described in detail.

The position activating unit 121 connects the elements extracted from the input data, that is, the positions matched with the elements received from the preprocessing unit 10, using the comparison result of the block chain comparing unit 110, Can be activated. The block chain comparison unit 110 compares the predefined Mission ("Predefined Mission") as shown in the first box, such as "Step 1" of the lower left second box of FIG. 9, An element extracted from the input data can be connected to a position.

In addition, the position activating unit 121 can determine whether the activation condition of the position is satisfied by inputting the elements extracted from the input data according to the passage of time. Here, the activation conditions may be different from each other depending on the position, and may be the number of elements connected to the position. For example, the activation condition of position A may be that five or more elements are connected.

On the other hand, the position activating unit 121 may connect the special element to the position identified by the position identifying unit 130. That is, in the " fourth step " shown in Fig. 9, special elements that are not included in the predefined organizational missions can be connected, such as special elements are linked to specific positions.

The chain generating unit 122 may continuously connect the positions connected to the positions activated by the position activating unit 121 to generate a chain that interconnects a plurality of positions. 9, the chain generation unit 122 searches the positions defined in the predefined organizational mission and determines whether the elements extracted from the input data are connected to the four positions to which the extracted elements are connected The chain can be composed by connecting the positions continuously. Through this chain generation unit 122, a chain connecting all the positions of the predefined organizational mission can be automatically formed.

The block construction unit 123 can construct a block including a position constituting the chain generated by the chain generation unit 122. [ That is, the block construction unit 123 can automatically construct a block including the position of the chain, as shown in the " third step " shown in FIG. A combination of blocks and chains constructed in this way can be a mission module.

On the other hand, the elements extracted from the input data are additionally input in accordance with the passage of time, and various elements including the input special element may be connected to the position, such as " Fourth Step "

The mission module activating unit 124 can activate the mission module when the condition determined according to the organizational mission is satisfied with respect to the position included in the constructed block. More specifically, the mission module activating unit 124 activates the mission module when all the elements extracted from the input data corresponding to the element connected to the position are connected according to the organizational mission, with respect to the position included in the block .

That is, when all the elements included in the positions in the block are connected through the comparison with the predetermined organizational mission, as shown in the " fourth step " shown in FIG. 9, the mission module can be activated in green. 10, the elements extracted from the input data are continuously input, and the elements connected to the positions in the block are connected and filled. In addition, as shown in Fig. 10, Mission modules can be built. In some cases, special elements may be linked to the position.

The mission organization unit 125 can organize a DNA mission when all the mission modules corresponding to the mission modules of the organizational mission are activated. That is, if all the mission modules of the predetermined mission mission are built and completed according to the passage of time, the DNA mission can be organized. That is, as shown in "Step 7" shown in FIG. 10, when all the mission modules are activated in green, a DNA mission can be organized.

As such, DNA missions can be organized in a similar fashion to predefined organizational missions. However, the structure of self-organized DNA missions may be different from the mission of the organization, because elements defined according to changes in circumstances may not be input, and non-predefined elements such as special elements may be input. Therefore, the mission self organizing module 100 using the neuroblock chain combination according to an embodiment of the present invention can self organize a DNA mission having a structure that varies variably according to the time flow or the situation change.

11 is a diagram illustrating a basic structure of a self-organizing module 200 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. As shown in FIG. 11, the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention includes one input and one output, and a neuroblock chain combination technique Can be used.

That is, the present invention can use the predefined organizational mission and the elements extracted from the input data to input the DNA mission organized through the neuroblock chain combination, and output the artificial neural network DNA model composed of the functional sub-model have. Therefore, according to the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention, by using the DNA mission that varies according to the change of the time and the situation, The neural network DNA model can be constructed by itself, which can effectively implement the human brain mechanism.

12 is a diagram illustrating a symbol of a self-organizing module 200 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. In FIG. 12, the blue rectangle is an element, the orange circle is a node, the star is a special element, the gray rectangle is a hidden layer, the yellow rectangle is a functional submodel, and the rectangle located at the right end of a yellow rectangle is a functional And the output of the lower model, respectively.

12, in the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention, elements and accidents based on the Neuroblock chain combination technique over time The artificial neural network DNA model can be constructed by itself as a function of the sequence of. More specifically, as the time progresses in the direction of the arrow at the lower end of FIG. 12, a functional lower model is constructed, and when each functional lower model is completed and operated, the output can be made as a result of the right end.

13 is a diagram showing the structure of a DNA model constructed by the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention. 13, a DNA model self-organizing by the self-organizing module 200 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention includes at least one functional submodel ). ≪ / RTI >

As shown in FIG. 13, the functional lower model may be configured in a three-layer structure including an input layer, a hidden layer, and an output layer. The input layer is composed of elements, and the output layer has the final result value. The hidden layer may be composed of at least one layer, at least one node, and special elements. Here, the special element is not a predefined element, but may refer to an element that is used as a new input as the situation changes. In such a functional sub-model, the structure of the hidden layer may change as the structure of the input DNA mission changes with time.

FIG. 14 is a diagram showing a configuration of a self-organizing module 200 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. 14, a self-organizing module 200 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention includes an input unit 210, a lower model construction unit 220, (230). ≪ / RTI >

The input unit 210 can receive a DNA mission that changes with time. Here, the DNA mission may consist of a sum of at least one or more mission modules, and the mission module constituting the DNA mission may include elements extracted from the data and positions of the organization members Function. In addition, the mission module can be composed of a combination of chain and block via neuroblock chain combination technique.

In the present invention, the input unit 210 receives a DNA mission whose structure changes according to a change in the state over time, and can use it as input information in the lower model construction unit 220 and the DNA model construction unit 230 . Therefore, it is possible to construct a DNA model having a flexible structure in which the hidden layer is changed in accordance with the change of the situation with the passage of time.

The lower model construction unit 220 can self-configure a functional sub model in correspondence with the mission module constituting the DNA mission. Here, the functional sub-model may be a combination of a function block (Blocks of Function) and a chain (Chains).

FIG. 15 is a diagram illustrating the number structure of functional sub-models constituting a DNA model in the self-organizing module 200 of an artificial neural network model using a Neuroblock chain combination according to an embodiment of the present invention. As shown in FIG. 15A, in the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention, the lower model constructing unit 220 basically includes a DNA mission One of the mission modules in the system can be configured as one functional sub-model. In addition, according to the embodiment, as shown in FIG. 15B, two or more mission modules in the DNA mission may be combined into one functional sub-model.

The detailed configuration of the lower model construction unit 220 will be described later in detail with reference to FIG.

The DNA model construction unit 230 can construct the artificial neural network DNA model, which is a sum of at least one functional lower model constructed in the lower model construction unit 220. That is, the DNA model constituted by the present invention can be composed of a sum of functional lower models. If the DNA mission has only one mission module, a DNA model with only one functional sub-model may be constructed.

FIG. 16 is a diagram showing a detailed configuration of a lower model construction unit 220 in a self-organizing module 200 of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention. 16, the lower model construction unit 220 of the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention includes a layer determination unit 221, A determination unit 222 and a hidden layer constituent unit 223.

The layer determination unit 221 can determine the number of layers using the position of the mission module. Hereinafter, with reference to FIG. 17, in the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention, the layer decision unit 221 of the lower model construction unit 220 This will be described in detail.

17 is a diagram illustrating a method of determining the number of layers by the layer determination unit 221 in the self-organizing module 200 of the artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention.

17 (a), the layer determination unit 221 of the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention determines whether or not the same level ("Rule 5-1"), and the number of layers may be further allocated as the level of the position increases ("Rule 5-2"). That is, a position one level higher than a certain level of a mission module in a DNA mission has a layer number of +1, and the number of layers can be increased in the same way until the position reaches the final level. In Fig. 17A, since the position of the mission module is at two levels, a total of two layers can be allocated.

As shown in FIGS. 17B and 17C, the layer determination unit 221 determines whether or not the position at which the number of elements exceeding the threshold value (T, Threshold Value) among the positions of the mission modules is connected , The number of layers may be further allocated to the ratio of the number of exceeded elements to the threshold ("Rule 5-3"). That is, if the number of elements connected to the positions of the respective levels is less than a predetermined threshold value, the layer has +1 layers. If the number of elements added exceeds the threshold value, the number of added elements is increased by +1 You can add a number. However, the maximum number of layers that can be held at the same level can be limited to the number of layers in the position having the maximum number of layers at the corresponding level.

For example, in FIG. 17 (b), a total of seven elements are connected to one of the first level positions of the mission module, which is a limit value, so that a layer of +1 is added to the corresponding position , Two layers are assigned to the first level position and one layer can be assigned to the second level position.

On the other hand, as shown in Fig. 17D, when a special element is input, the layer determination unit 221 can additionally assign the number of layers to the position to which the special element is inputted (" Rule 5- 4"). That is, it is possible to increase the number of layers by +1 for a corresponding position that receives a special element as an input. If there are two or more special elements entered in the position, "Rule 5-3" above can be applied. At this time, it is possible to determine whether the element and the special element are added to exceed the limit value.

Finally, the layer determination unit 221 can determine the total number of layers of the hidden layer by adding the number of layers in all cases shown in (a) to (d) of FIG.

For example, in (d) of FIG. 17, since there is no position where elements exceeding the threshold value are connected, one layer is assigned to each level, but since the special element is connected to the position of the third level, A layer is added, and a total of four layers can be assigned to the functional sub-model.

The node determining unit 222 can determine the number of nodes of each layer using the position of the mission module. 18, in the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention, the node determining unit 222 of the lower model construction unit 220 This will be described in detail.

18 is a diagram illustrating a method of determining the number of nodes by the node determining unit 222 in the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention.

18A and 18B, the node determining unit 222 of the self-organizing module 200 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention determines a node The number of positions of each level of the module and the number of nodes of each layer of the hidden layer are determined to be the same (Rule 6-1), and with respect to the level to which two or more layers are allocated, ("Rule 6-2"). That is, when the number of layers of the corresponding level of the mission module is two or more, the number of nodes is reduced by one each time the layer goes up one level, and the number of nodes can be reduced by the same method until reaching the final layer.

For example, in FIG. 18 (b), since the number of elements exceeding the limit value is connected to the position of the first level of the mission module, two layers are arranged in the first level and one layer is provided in the second level . The two positions of the first level of the mission module are determined as two nodes of the first layer of the functional sub-model, and one node can be arranged by reducing one node to the second layer. In the third layer, one node that is the same as one position in the second level of the mission module can be placed.

18 (c), the node determining unit 222 can maintain the number of nodes of the level assigned to the additional layer by the special element (" Rule 6-3 " ).

When the position of the DNA mission is activated, the hidden layer construction unit 223 can construct a hidden layer using the layer determination unit 221 and the node determination unit 222 in consideration of the relationship of the positions of the mission modules. That is, as soon as the position of the DNA mission satisfies the activation condition, the hidden layer construction unit 223 can start constructing the hidden layer by the combination of the chain and the block considering the relationship of the positions in the block on which the mission module is based have. Thus, as long as the structure of the DNA mission is changed in accordance with the change of time and the situation, the concealment of the DNA model can be continuously changed in conjunction with this.

19 is a diagram illustrating a process of constructing a DNA model by the self-organizing module 200 of an artificial neural network model using a Neuroblock chain combination according to an embodiment of the present invention. 19, a self-organizing module 200 of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention generates a sub model The unit 220 determines the number of layers and nodes and constructs a hidden layer, and the DNA model constructing unit 230 constructs a DNA model by connecting functional sub-models. Since the input DNA mission changes with the passage of time, the self-constituting DNA model can also have a flexible structure that changes with the passage of time.

20 is a diagram illustrating a basic structure of a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. 20, a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention includes two inputs including a DNA mission and a DNA model, Model, and a neuroblock chain combination technique can be used.

That is, according to the present invention, by performing chain learning and block learning by receiving a DNA mission and a DNA model, a DNA model can be learned by a combination of chain learning and block learning, and the learned DNA model can be output. Because the DNA model learns itself by the combination of chain learning and block learning in the actual field, the DNA model can flexibly change through the self-learning according to the change of the time flow and the situation, and it is possible to use the human brain mechanism Can be effectively implemented.

FIG. 21 is a diagram illustrating symbols of a self-learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. In Figure 21, the blue rectangle is an element, the orange circle is a position or node, the star is a special element, the gray rectangle is a hidden layer, the yellow rectangle is a functional submodel, , And the rectangle at the right end of the yellow rectangle represents the output of each functional sub-model.

In the present invention, the DNA model is composed of a sum of at least one functional sub-model, and the functional sub-model is learned by a combination of chain learning and block learning while varying with time, have. In FIG. 21, it is shown that each sub-model is learned by changing its shape according to the time, using a gear wheel shape. As each functional sub-model is learned as the time progresses as shown in the arrow direction at the bottom, the learned output can be generated as shown at the right end of FIG.

22 is a diagram showing a configuration of a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention. 22, a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention includes an input unit 310, a chain learning unit 320, and a block learning unit 330).

The input unit 310 can receive a DNA mission, which is a function of elements and positions and is composed of at least one mission module, and a DNA model, which is an artificial neural network model constructed using a DNA mission. Here, the DNA mission may consist of a sum of at least one or more mission modules, and the mission module constituting the DNA mission may include elements extracted from the data and positions of the organization members Function. In addition, the mission module can be configured as a combination of chain and block using Neuroblock Chain Combination technology.

23 is a diagram showing chain learning and block learning in the self learning module 300 of the neural network model using the neuroblock chain combination according to an embodiment of the present invention. 23, a chain learning unit 320 and a block learning unit 330, which constitute a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention, Will be described in detail.

The chain learning unit 320 can perform learning on a chain that interconnects the activated position and the other position of the inputted DNA mission. Here, the chain learning may be to learn the formation of a chain derived from a predefined mission, as shown in Figs. 9 and 10 and the like. When an activation condition is satisfied, for example, a predetermined number of elements are connected to a position as an element extracted from the data is inputted, the corresponding position included in the DNA mission can be activated. As shown in FIG. 23 (a), the chain learning unit 320 can learn a chain that connects the activated position and the position, and the learning performed between the position and the position can be referred to as chain learning.

The block learning unit 330 can perform learning in the activated mission module when the mission module constituting the inputted DNA mission is activated. Here, the block learning may be to learn the formation of a block derived from a predefined mission, as shown in Figs. 9 and 10, and the like. The mission module can be activated if the activation condition is satisfied, for example, all the predetermined elements are connected to all the positions in the block as the elements extracted from the data are inputted. The block learning unit 330 can perform learning in the activated mission module as shown in FIG. 23 (b), and learning performed in the mission module can be referred to as block learning.

On the other hand, a DNA model can be learned by a combination of chain learning and block learning performed by the chain learning unit 320 and the block learning unit 330, respectively. Hereinafter, the learning method of the DNA model according to the learning time will be described in detail.

First, in the case of the preliminary training of the DNA model, the chain learning unit 320 can perform chain learning for all chains interconnecting the activated position and the other positions. That is, when learning a DNA model for preliminary training, chain learning can be performed on all connected chains between the activated position and the position. At this time, block learning may not be performed.

In the case of the self-learning of the pre-trained DNA model, the block learning unit 330 performs block learning of the pre-trained DNA model in the mission module activated by the input element by time, When finished, the chain learning unit 320 can perform chain learning for all the upper positions connected to the positions in the mission module.

FIG. 24 is a diagram illustrating a self-learning process of a trained DNA model in a self-learning module 300 of an artificial neural network model using a neuro-block chain combination according to an embodiment of the present invention. 24, the self-learning module 300 of the neural network model using neuroblock chain combination according to an embodiment of the present invention, when the trained DNA model learns itself while adapting to the actual field, Block learning may be performed first, followed by chain learning.

That is, the input element activates the mission module according to the change of the situation with time, and when the predefined self-learning condition is satisfied, the activated mission module performs block learning by itself by the block learning unit 330 . When the block learning ends, the chain learning unit 320 can perform chain learning for all the upper positions continuously connected to the position in the corresponding mission module by itself. Thus, the DNA model can be learned by a combination of chain learning and block learning.

Meanwhile, the block learning unit 330 performs block learning when the trained DNA model adapts itself to the actual site and learns by itself. The block learning unit 330 performs block learning on the basis of a predefined element and a time flow Two kinds of block learning can be performed in consideration of the relationship with the input elements according to the following equation. Hereinafter, the detailed configuration of the block learning unit 330 will be described in detail with reference to FIG.

FIG. 25 is a diagram showing a detailed configuration of the block learning unit 330 in the self learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention. 25, a block learning unit 330 of a self learning module 300 of an artificial neural network model using a neuroblock chain combination according to an embodiment of the present invention includes an accommodative block learning unit 331, And a reactive block learning unit 332.

The accommodative block learning unit 331 compares the input element with the predefined element in the position of the mission module in a time block composed of at least one unit time, Reward Comparison can be calculated to learn unconditionally.

FIG. 26 is a diagram illustrating learning concepts of the adaptive block learning unit 331 in the self-learning module 300 of the neural network model using the neuroblock chain combination according to an embodiment of the present invention. 26, the adaptive block learning unit 331 of the self learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention analyzes the current situation, Can be an unconditional learning that is used in missions to determine future situations and provide indirect and moderate support for human decision making.

FIG. 27 is a diagram illustrating a learning process of the adaptive block learning unit 331 in the self learning module 300 of the neural network model using a neuroblock chain combination according to an embodiment of the present invention. 27, the adaptive block learning unit 331 of the self-learning module 300 of the neural network model using the neuroblock chain combination according to an embodiment of the present invention calculates the time when the mission module is activated And a unit time and a time block can be set based on the reference time. That is, the time block starts from the reference time, and may be a unit time multiplied by a time number, and may be composed of a plurality of unit times.

The comparison compensation value can be calculated and stored for every unit time set within the time block starting from the reference time. Here, the comparison compensation value is defined as a compensation weight that is predefined for each element including the number of data that is input to the element connected to the position in the mission module at each unit time, the number of data that does not come in, . Here, with respect to the predefined compensation weights, the weights of the elements connected to the predefined positions and the weights of the special elements may be defined to be different from each other.

At the end of the set time block, block learning can be performed by selecting an optimal comparison compensation value that can support the intermediate decision among the stored comparison compensation values. Here, the method of selecting the optimum comparison compensation value may differ depending on the mission and application, the compensation value selection strategy, and the like. For example, the median value, the mean value, and the mode value among the comparison compensation values can be selected as the optimal comparison compensation value. In some embodiments, the compensation value based on the Monte Carlo simulation is used as the optimal comparison compensation value It can also be selected.

The reactive block learning unit 332 can calculate the reference compensation value and the compensation compensation value according to the correlation between the element input for a unit time and the element previously defined in the position of the mission module, have.

FIG. 28 is a diagram showing the learning concept of the reactive block learning unit 332 in the self-learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention. 28, the reactive block learning unit 332 of the self learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention analyzes the current situation, Can be conditional learning used in missions to determine future situations and provide immediate and immediate support for human behavior decisions.

FIG. 29 is a diagram illustrating a learning process of the reactive block learning unit 332 in the self learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention. 29, the reactive block learning unit 332 of the self learning module 300 of the artificial neural network model using the neuroblock chain combination according to an embodiment of the present invention determines a time point when the mission module is activated The reference time can be set as the reference time, the unit time can be set as the reference time, and the reference compensation value (Reward Reference) can be calculated within the set unit time. In other words, the reference compensation value is calculated in the first unit time from the reference time, where the reference compensation value is the number of data that is input to the element connected to the position in the mission module from the reference time to the unit time, And a function of predefined compensation weights for each element including the special element.

If the comparison compensation value calculated within the next unit time is larger than the reference compensation value, the comparison compensation value can be changed to the reference compensation value and the block learning can be performed. That is, the comparison compensation value can be calculated within a unit time starting from the end of the unit time at which the reference compensation value is calculated, and the comparison compensation value can be calculated in consideration of the item used in calculating the reference compensation value. In other words, if the comparison compensation value is larger than the reference compensation value, the comparison compensation value may be changed to the reference compensation value and the block learning may be started . If the comparison compensation value is smaller than or equal to the reference compensation value, the block learning is not started, and the comparison compensation value is calculated for the next unit time and then compared with the existing compensation value.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

10: preprocessor 11: text conversion module
12: information extraction module 13: element derivation module
20: self-adaptive learning engine 100: self organizing module
110: block chain comparison unit 120: block chain activation unit
121: position activation unit 122: chain generation unit
123: block building unit 124: mission module activating unit
125: mission organization part 130: position identification part
200: self-configuration module 210, 310:
220: Lower model construction unit 221: Layer determination unit
222: node determining unit 223: hidden layer construction unit
230: DNA model component
300: a self-learning module according to an embodiment of the present invention
320: chain learning unit 330: block learning unit
331: Acceptable block learning unit 332: Reactive block learning unit

Claims (7)

As a self-learning device for learning an artificial neural network model,
An input unit 310 for receiving a DNA mission, which is a function of elements and positions and is composed of at least one mission module and an artificial neural network model constructed using a DNA mission;
A chain learning unit (320) for learning a chain interconnecting the activated position and the other position of the input DNA mission; And
And a block learning unit 330 for performing learning in the activated mission module when the mission module constituting the inputted DNA mission is activated,
The DNA model is learned by a combination of chain learning and block learning performed by the chain learning unit 320 and the block learning unit 330,
In the DNA mission,
We compared the pre-defined organizational mission as a function of the elements to be input into the artificial neural network model and the poses of organization and the result of comparing the self-organized DNA mission using the elements extracted from the input data. A block chain activator 120 for constructing chains and blocks using elements extracted from the input data, and organizing and activating a DNA mission, which is a combination of a mission module and a mission module, Chain Activator)
The block-chain activating unit 120,
A position activation unit (121) for connecting positions matched with elements extracted from the input data using the comparison result and activating a position satisfying an activation condition;
A chain generating unit 122 for continuously connecting the positions connected to the positions activated by the position activating unit 121 to generate a chain interconnecting the plurality of positions;
A block construction unit 123 for constructing a block including a position constituting the chain generated by the chain generation unit 122;
A mission module activating unit (124) for activating the mission module when a condition determined according to the organizational mission is satisfied with respect to a position included in the constructed block; And
And a mission organization part (125) for organizing the DNA mission when all mission modules corresponding to the mission module of the organizational mission are activated,
In the case of the preliminary training of the DNA model,
The chain learning unit 320 performs chain learning on all chains interconnecting the activated position and the other position,
In the case of self-learning of the pre-trained DNA model,
The block learning unit 330 performs block learning of the pre-trained DNA model in the mission module activated by the element input in accordance with the passage of time,
Wherein the chain learning unit (320) performs chain learning on all upper positions connected to positions in the mission module when the block learning is completed. The chain learning unit (320) of the artificial neural network model using neuroblock chain combination Learning device .
The method according to claim 1,
Wherein the DNA model comprises a sum of at least one functional sub-model,
Characterized in that the functional lower model is learned while being changed by the combination of the chain learning and the block learning in accordance with the passage of time so as to generate the learned DNA model. The neural network according to claim 1, Device.
delete delete The apparatus of claim 1, wherein the block learning unit (330)
An adaptive block learning method that calculates an optimal comparison compensation value according to a correlation between an input element and a predefined element in a position block of the mission module in a time block composed of at least one unit time and unconditionally learns 331; And
And a reactive block learning unit 332 for calculating a reference compensation value and a compensation compensation value in accordance with the correlation between the element input for a unit time and a predefined element in the position of the mission module, A neural network model self-learning apparatus using neuroblock chain combination.
6. The apparatus of claim 5, wherein the accepting block learning unit (331)
Setting a time when the mission module is activated as a reference time, setting a unit time and a time block based on the reference time, calculating and storing a comparison compensation value for each set unit time, And a block learning is performed by selecting an optimal comparison compensation value among the stored comparison compensation values, and a self learning apparatus of an artificial neural network model using a neuroblock chain combination.
6. The apparatus of claim 5, wherein the reactive block learning unit (332)
A reference compensation value is calculated within a set unit time, and a comparison compensation value calculated in a next unit time is calculated based on the reference compensation value, And the reference compensation value is changed to a reference compensation value and block learning is performed if the reference compensation value is larger than the reference compensation value.

Images