KR102478967B1 - Method and system for providing blockchain-based contract management service interlocked with metaverse - Google Patents

Abstract

An operating method of a system for providing a contract conclusion service for concluding a contract between users in a metaverse space is provided. The operating method comprises: a step of activating a contract conclusion service in the metaverse space displayed on a device of a user; a step of obtaining contractor information and contract condition information based on conversation information between users in the metaverse space; a step in which a contract management server generates a contract draft file by immediately adding the contract condition information to a preset contract template upon receiving the contract condition information; a step in which the contract management server transmits the generated draft contract file and displays the draft contract file on devices of the users; a step in which the contract management server acquires review information about whether the confirmed draft contract file has been reviewed by the users who are contractors in the metaverse space; a step in which the contract management server generates a final contract file based on the review information; a step in which the contract management server requests the users who are contractors to conclude the final contract through the metaverse space and receives information about whether the users have confirmed the final contract; a step in which the contract management server gives a hash value to the final contract file; a step in which the contract management server registers an ID for the final contract file based on the hash value; and a step of transmitting information about the final contract file to the devices of the users.

Description

Method and system for providing contract management service based on metaverse linked blockchain {METHOD AND SYSTEM FOR PROVIDING BLOCKCHAIN-BASED CONTRACT MANAGEMENT SERVICE INTERLOCKED WITH METAVERSE}

The present invention relates to a method and apparatus for providing a contract conclusion service between users, and more particularly, to a method for providing a contract conclusion service between users in a metaverse space and a device that performs a method for providing a contract conclusion service. will be.

Metaverse is a compound word of 'meta', which means virtual and transcendence, and 'universe', which means world and universe, and means a three-dimensional virtual world linked to reality. Users can perform existing online interactions on the metaverse space. For example, users can perform online contract signing services on the metaverse space.

Online contract signing services are applied to various industries such as finance, insurance, real estate, and labor contracts. As interest in online contract execution platforms grows, the market size continues to grow. And the central government and businesses are investing heavily to improve existing online contract signing platforms.

However, since the contract concluded by the online contract conclusion system may be forged and falsified by malicious users, the validity of rights may not be verified. In addition, online contracts may not be admissible as evidence in a lawsuit because they do not guarantee identity, integrity, confidentiality, or non-repudiation.

Therefore, when signing contracts online, including the metaverse, the need to store the signed contracts in the blockchain is emerging. By storing contracts concluded online in the blockchain, there is a need to minimize the risk of contract hacking and at the same time provide an online contract management service that makes it easy to verify the authenticity and originality of the contract. In addition, research and development of an online contract platform that increases accessibility while lowering the psychological burden of users is required for creating contracts between individuals on the metaverse platform.

An object of the present invention to solve the above problems is to provide a method, device, and system for providing a contract signing service between users in a metaverse space.

Another object of the present invention to solve the above problems is to provide a method, device, and system for facilitating contract validity, original verification, and history management by constructing a private chain as a subchain of a public blockchain. there is.

A method of operating a system for providing a contract signing service between users on a metaverse space for achieving the above object includes activating the contract signing service on the metaverse space displayed on a user's device; obtaining contractor information and contract condition information based on conversation information between users on the metaverse space; generating a contract draft file by adding the contract condition information to a preset contract template as soon as the contract management server receives the contract condition information; transmitting, by a contract management server, a draft contract file, and displaying the generated draft file on the device of the user; Acquiring, by the contract management server, review information about whether or not the draft of the confirmation contract has been reviewed from users who are contractors in the metaverse space; generating, by a contract management server, a final contract file based on the review information; The contract management server requests the users who are contractors to conclude a contract for the final contract through the metaverse space and receives confirmation information; giving a hash value to the final contract file by a contract management server; and registering, by a contract management server, an ID for the final contract file based on the hash value. and transmitting information about the final contract file to the devices of the users.

Here, the operating method includes generating an encryption key by encrypting the final contract file; and storing the encryption key and metadata related to the final contract on a blockchain network.

Here, the contract signing service may be activated when the distance between avatars of each of the users is within a preset range on the metaverse space.

Here, the confirmation information may include signature information of each of the users and identification information of each of the users.

Here, the generating of the final contract may include adding signature information of each of the users to the draft contract; generating a tamper-resistant code; adding the tamper protection code to the draft contract; and generating a final contract file based on the draft contract to which the signature information and the tamper protection code are added.

Here, the damage prevention code may be generated based on at least one of information about the metaverse space, identification information of each of the users, and contract conclusion date and time information.

Here, the damage prevention code may be added on an area including an area where the contract conditions included in the draft contract are displayed.

Here, the damage prevention code is added to each of the contract files provided to different users, and the divided damage prevention code is added on a symmetrical position in each of the contract files. can

Here, the operating method includes generating a metaverse contract object output in the form of an object on the metaverse space based on the generated final contract file; and outputting the metaverse contract object on the metaverse space based on the location information of the users' avatars.

Here, the step of generating the metaverse contract object comprises: reducing the image of the final contract file to correspond to the size of the user's avatar on the metaverse space; The method may include correcting at least some damaged areas in the image of the reduced final contract file.

A server of a system for providing a contract signing service between users on the metaverse space for achieving the above object includes a memory in which at least one program command is stored; a processor to execute the at least one program instruction; and a transmitting/receiving device connected to a network to perform communication, wherein the at least one program command activates the contract execution service on the metaverse space displayed on a user's device; obtaining contractor information and contract condition information based on conversation information between users on the metaverse space; Upon receiving the contract condition information, the contract management server creates a contract draft file by adding it to a preset contract template; the contract management server transmits the generated draft contract file and displays it on the user's device; The contract management server obtains review information from users who are contractors in the metaverse space whether the draft of the confirmation contract has been reviewed; the contract management server generates a final contract file based on the review information; The contract management server requests the users who are contractors to conclude a contract for the final contract through the metaverse space and receives confirmation information; the contract management server assigns a hash value to the final contract file; the contract management server registers an ID for the final contract file based on the hash value; And it can be executed to transmit information about the final contract file to the devices of the users.

Here, the at least one program command may be further executed to generate an encryption key by encrypting the final contract file, and to store the encryption key and metadata related to the final contract on a blockchain network.

Here, the contract conclusion service may be characterized in that it is activated when the distance between avatars of each of the users is within a preset range on the metaverse space.

Here, the confirmation information may include signature information of each of the users and identification information of each of the users.

Here, the at least one program command, when executed to generate the final contract, adds signature information of each of the users to the draft contract; generate tamper-evident code; add the tamper-evident code to the draft contract; And it may be executed to generate a final contract file based on the draft contract to which the signature information and the tamper protection code are added.

Here, the damage prevention code may be generated based on at least one of information about the metaverse space, identification information of each of the users, and contract conclusion date and time information.

Here, the damage prevention code may be added on an area including an area where the contract conditions included in the draft contract are displayed.

Here, the damage prevention code is added to each of the contract files provided to different users, and the divided damage prevention code is added on a symmetrical position in each of the contract files. can

Here, the at least one program command generates a metaverse contract object output in the form of an object on the metaverse space based on the generated final contract file; And based on the location information of the users' avatars, it can be executed to output the metaverse contract object on the metaverse space.

Here, the at least one program command, when executed to create the metaverse contract object, reduces the image of the final contract file to correspond to the size of the user's avatar on the metaverse space; It may be executed to correct at least a part of the damaged area in the image of the reduced final contract file.

The system for providing a contract conclusion service between users according to the present invention can provide a system that can easily provide a contract conclusion service between users in the metaverse space.

The system for providing contract conclusion services between users according to the present invention constitutes a private chain as a subchain of a public blockchain to provide contract conclusion services between users to facilitate contract validity, original verification, and history management. .

1 is a diagram showing an embodiment of the structure of a system that provides a contract signing service between users in a metaverse space.
FIG. 2 is an exemplary diagram showing a hardware configuration of a device included in the system for providing a contract signing service between users according to FIG. 1 .
3 is a diagram illustrating an embodiment of a connection structure between users of a system providing a contract signing service between users.
4 is a diagram illustrating an embodiment of a front-end structure and a back-end structure of a system that provides a contract signing service between users.
5 is a flowchart illustrating the operation of the contract conclusion system between users.
6 is a flowchart illustrating an operation of creating a final contract file in a contract conclusion system between users.
7 is a flowchart illustrating an operation of outputting a metaverse contract object of a contract signing system between users.
8 is a diagram illustrating a process of initiating a contract between users' avatars in the metaverse space.
9 is a diagram illustrating a process of activating contract signing between avatars of users in the metaverse space.
10 is a diagram illustrating a process of inputting contract-related information in a contract platform on a metaverse space.
11 is a diagram illustrating an interface output to a contract condition input window.
12 is a diagram illustrating an embodiment of a process of inputting signature information in a contract platform on a metaverse space.
13 is a diagram illustrating another embodiment of a process of inputting signature information in a contract platform on a metaverse space.
14 is a diagram showing an embodiment of a contract created in a contract platform on a metaverse space.
15 is a diagram illustrating an embodiment of a contract created in a contract platform.

Since the present invention can make various changes and have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. The terms and/or include any combination of a plurality of related recited items or any of a plurality of related recited items.

It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be. On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, they should not be interpreted in an ideal or excessively formal meaning. don't

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail. In order to facilitate overall understanding in the description of the present invention, the same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted.

1 is a diagram showing an embodiment of the structure of a system that provides a contract signing service between users in a metaverse space.

1 is a conceptual diagram illustrating an embodiment of the configuration of a system that provides a contract signing service between users in a metaverse space.

Referring to FIG. 1, a system that provides a contract signing service between users in the metaverse space is provided through a server 110 and a network 120 for providing a contract signing service between users and a metaverse-linked blockchain-based contract management service. It may include a user terminal 130 connected to the server 110 . However, since the system for providing a contract signing service between users of FIG. 1 is only one embodiment of the present invention, the present invention is not limitedly interpreted through FIG. 1 .

The server 110 may be a server that provides web pages, app pages, programs or applications related to contract signing services between users on the metaverse space. The server 110 may perform an operation of setting a process according to an electronic contract. When an electronic contract is created and a signature for the electronic contract is secured, the server 110 may map and hash metadata to identify the electronic contract. In addition, the server 110 stores the electronic contract, which is the original content, in a database within the platform, and the encryption key value generated as a result of encryption can be dualized and stored in the blockchain network.

Here, the server 110 may be implemented as a computer capable of accessing a remote server or terminal through a network. Here, the computer may include, for example, a laptop, a desktop, a laptop, and the like equipped with a navigation system and a web browser.

The network 120 may mean a connection structure for exchanging information between the server 110 and the user terminal 130 . The network 120 includes the Internet, a local area network (LAN), a wireless local area network (Wireless Local Area Network), a wide area network (WAN), a personal area network (PAN), 3G, 4G, and long term evolution (LTE). , VoLTE (voice over LTE), 5G NR (new radio) Wi-Fi (wireless-fidelity), Bluetooth, NFC, RFID (radio frequency identification) home network, IoT (internet of things), etc. can include

The user terminal 130 may be connected to the server 110 through the network 120 . The user terminal 130 may be a terminal of a user using a web page, an app page, a program, or an application related to a contract signing service between users on the metaverse space.

Here, the user terminal 130 may be implemented as a computer capable of accessing a remote server or terminal through a network. Here, the computer may include, for example, a laptop, a desktop, a laptop, and the like equipped with a navigation system and a web browser. In this case, the user terminal 130 may be implemented as a terminal capable of accessing a remote server or terminal through a network. The user terminal 130 is, for example, a wireless communication device that ensures portability and mobility, and includes navigation, PCS (Personal Communication System), GSM (Global System for Mobile communications), PDC (Personal Digital Cellular), PHS (Personal Communication System) Handyphone System), PDA (Personal Digital Assistant), IMT (International Mobile Telecommunication)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W-Code Division Multiple Access), Wibro (Wireless Broadband Internet) terminal, It may include all kinds of handheld-based wireless communication devices such as a smartphone, a smart pad, a tablet PC, and the like. Hereinafter, the user terminal 130 may be referred to as a user device.

The server 110 and the user terminal 130 of FIG. 1 may be referred to as a device, and the configuration of the device may be as described below.

FIG. 2 is an exemplary diagram showing a hardware configuration of a device included in the system for providing a contract signing service between users according to FIG. 1 .

Referring to FIG. 2 , the device 200 includes at least one processor 210 and a memory 220 storing instructions instructing the at least one processor 210 to perform at least one step. can include

Here, the at least one processor 210 may mean a central processing unit (CPU), a graphics processing unit (GPU), or a dedicated processor for performing methods according to embodiments of the present invention. can Each of the memory 220 and the storage device 260 may include at least one of a volatile storage medium and a non-volatile storage medium. For example, the memory 220 may include at least one of a read only memory (ROM) and a random access memory (RAM).

In addition, the device 200 may include a transceiver 230 that performs communication through a wireless network. In addition, the device 200 may further include an input interface device 240 , an output interface device 250 , a storage device 260 , and the like. Each component included in the device 200 may be connected by a bus 270 to communicate with each other.

3 is a diagram illustrating an embodiment of a connection structure between users of a system providing a contract signing service between users.

Referring to FIG. 3 , a system that provides a contract signing service between users in the metaverse space may include a user terminal of a signature requester, a user terminal of a signing target, and a management service providing server 300 . And the management service providing server 300 may include a database and a blockchain server.

In the case of proceeding with a contract between the signature requester and the person to be signed, the management service providing server 300 may authenticate the user's identity using decentralized identities (DIDs) of the user terminals 100 .

The management service providing server 300 may encrypt the original electronic contract generated as a result of the user's contract.

The management service providing server 300 may store the original content of the electronic contract in a database. Specifically, the management service providing server 300 may assign a hash value to the original content of the electronic contract and generate a symmetric/asymmetric encryption key including a private key and a public key based on the hash value. In addition, the management service providing server 300 may encrypt the original content of the electronic contract. The management service providing server 300 may store the encrypted original content of the electronic contract in its own server and/or database.

The management service providing server 300 may transmit the key value generated as a result of the encryption of the electronic contract to the signing requester and the signing target party, which are parties to the contract. Thus, the parties to the contract can decrypt the encrypted contract. In addition, the management service providing server 300 creates a block in at least one node constituting the blockchain, and stores the key value generated as a result of the encryption of the electronic contract and the metadata related to the contract signing in the generated block, It can be distributed and stored so that it is dualized with the content.

Here, the database on the platform stores the original content of the electronic contract, and the blockchain network can be characterized in that the key value generated while encrypting the electronic contract is dualized and stored in at least one node constituting the blockchain. A method of dualizing and storing each data using a database and a blockchain network can be referred to as a hybrid blockchain.

Operations by specific configurations of the management service providing server 300 may be as described below.

4 is a diagram illustrating an embodiment of a front-end structure and a back-end structure of a system that provides a contract signing service between users.

Referring to FIG. 4 , a front-end structure and a back-end structure of a system providing a contract signing service between users may be included.

The front-end may include a message channel for web pages and applications, DID authentication, PDF creation and editing, and a configuration that converts to a PDF file and saves it when signing is completed.

The Back-End is a configuration that stores schedules in an off-chain database, and a scheduling layer that creates events or notifications using scheduled property values. It includes the schedule synchronization manager and monitoring components.

And the back-end generates metadata that maps actions between the user and the other party, hashes the generated metadata, and stores it in the database. In addition, the back-end can also map and hash electronic contracts in the form of metadata to perform unique identification before storing on the blockchain.

In addition, the back-end can handle communication between smart contracts and databases, and encrypted data can be stored in the blockchain through smart contracts.

And the back-end may include a credit rating system. The credit rating system may further include a credit rating AI. Credit evaluation AI can be built by setting performance evaluation criteria, collecting, optimizing, and leveling performance data, and then learning and testing the criteria through machine learning.

Specifically, according to an embodiment of the present invention, the management service providing server 300 and/or another server (not shown) is at least one user terminal 100, and a service application, program, app related to contract signing service between users. You can send pages, web pages, etc. In addition, at least one user terminal 100 may install or execute a service application, program, app page, web page, etc. related to a contract signing service between users.

Here, at least one user terminal 100 may receive a service application, program, app page, web page, etc. related to contract signing service between users on the metaverse platform. In addition, the user's terminal 100 in an online state on the metaverse platform may install or execute service applications, programs, app pages, web pages, etc. related to contract signing services between users received through the metaverse platform. On the other hand, the user terminal 100 offline on the metaverse platform is a service application, program, app page, web page, etc. can receive Therefore, the user terminal 100 accesses the metaverse platform based on information received through external programs, app pages, web pages, and/or platforms, and service applications, programs, and app pages related to contract signing services between users. , install or run web pages, etc.

Alternatively, at least one user terminal 100 may drive a service program using a script executed in a web browser. Here, the web browser is a program that allows users to use the web (WWW: World Wide Web) service, and means a program that receives and displays hypertext described in HTML (Hyper Text Mark-up Language). For example, Netscape , Explorer, Chrome, and the like. In addition, an application means an application on a terminal, and may include, for example, an app executed on a mobile terminal (smartphone).

Here, it may be a hybrid blockchain-based system related to contract signing services between users. Here, the hybrid block chain may refer to a block chain characterized in that the original content of the electronic contract is stored in a database on the platform, and the key value generated while encrypting the electronic contract is dualized and stored in at least one node constituting the block chain. there is.

The management service providing server 300 may authenticate the user's identity using decentralized identification (DID) of the user terminals 100 . For example, the server may perform identity authentication of the user using biometric information. DID may use at least one piece of biometric information including fingerprint, iris, voice, and face. The authentication method of FIDO (Fast IDentity Online), a biometric authentication standard, can use the same PKI method as that of public certificates. Therefore, the FIDO authentication method can secure identity verification, integrity, confidentiality, and non-repudiation functions. As a result, the contract created through the contract conclusion service of the present invention can maintain evidence value in court. Here, the management service providing server 300 may authenticate through user-specific biometric information recognition such as fingerprint, voice, and face recognition using FIDO UAF (Universal Authentication Framework). When the biometric information is recognized through the device, the server can be accessed, and then the security key provided or stored in the device can be input in order.

In order to replace paper documents used in judicial procedures with electronic documents, conditions of equivalence, integrity, security, and confidentiality are required. In particular, in the case of criminal justice proceedings, evidence that satisfies the force of evidence must be secured. First, equivalence means that paper documents and electronic documents must be the same. If the evidence in a simple small claims trial is used as an electronic document, this means that there is equivalence. In addition, when an authorized electronic signature is applied to an electronic document, the integrity of the electronic document may be maintained. The authorized electronic signature may use a biometric authentication method as well as an authorized certificate. In addition, the electronic document on which the electronic signature is performed may be encrypted. Therefore, the security and confidentiality of electronic documents can be maintained by using blockchain-based DID.

The management service providing server 300 may encrypt the original electronic contract generated as a result of the user's contract. Encryption is a method for maintaining confidentiality so that unauthorized users or objects cannot know the contents of information during the transmission process of information, and refers to a process of converting information (plain text) into cipher text. Therefore, information cannot be read or understood except by specific persons. At this time, the encryption method may be one of encryption methods such as symmetric key, public key (asymmetric key) encryption, and secret distribution method.

The management service providing server 300 may create a block in at least one node constituting a block chain and store the key value generated as a result of encryption of the electronic contract so as to be dualized with the original content. That is, the original content may be stored in the database of the management service providing server 300 according to an embodiment of the present invention, and the encryption key value may be stored by generating a block as a node in the blockchain.

The management service providing server 300 may store the original content of the electronic contract in a database. At this time, in the case of a simple promise that proceeds as an oral contract, data generated during the oral contract can be stored using a block chain to ensure the integrity of the verbal contract verification data. The blockchain stores each transaction data in a block, and stores the hash of all data in the next block, giving each data a dependency. In other words, since the integrity of all transactions is guaranteed by the chain of blocks, the integrity of proof of verbal contracts can be guaranteed through the characteristics of blockchain that guarantee data integrity.

These blockchains are largely divided into public blockchains and private blockchains. Public blockchains are open blockchains that anyone can access and are not suitable in terms of the security of proof of oral contracts, so only authorized users can access them. A system can be built using hyperledger fabric, which is a blockchain, and to ensure the integrity of oral contract proof data, voice data and text data can be hashed as proof of verbal contract through voice. Thereafter, the hash values of the voice data and the text data are combined with a separator to generate a MainHash. In addition to the generated main hash and text data, metadata such as time and location information at the time of verbal contract are organized into transactions and stored in the blockchain.

The management service providing server 300 may apply a smart contract to connect between the database and the blockchain. A smart contract is a software code implemented on a blockchain platform that guarantees that contracts are automatically executed for assets contained in the blockchain according to the fulfillment of pre-determined conditions. In other words, smart contracts are Automated Self-Enforced Agreements, which combine the two processes of contract establishment and execution into one through blockchain technology. The technical concept of a smart contract is a kind of program that automatically executes according to an event instructing the transfer of assets to the ledger while the transaction records are distributed and stored, decentralized and shared, and the replicated ledger is operated and stored. -Driven Program).

The management service providing server 300 may edit and/or convert the contract data signed by the user terminal 100 and store it in a static file storage.

The management service providing server 300 may perform a unique identification operation by mapping and hashing meta data before storing the electronic contract in the blockchain. The management service providing server 300 may perform a unique identification operation by performing mapping and hashing to record interactions between user terminals 100 . The user terminal 100 and the counterpart terminal 400 may be connected through a peer to peer (P2P) communication channel.

The management service providing server 300 may monitor and evaluate whether the contract is fulfilled when a fixed fulfillment period arrives in the electronic contract. In addition, the management service providing server 300 may store reference data for evaluating contract fulfillment, collect contract fulfillment data, and learn and test the reference data with at least one artificial intelligence algorithm.

An operation of the contract signing system between users implemented through the configurations of FIGS. 3 and 4 may be described below.

5 is a flowchart illustrating the operation of the contract conclusion system between users.

In step S510, the server may activate a contract signing service on the user's device. According to one embodiment, the server may activate a contract signing service on the metaverse space displayed on the user's device. Here, the contract signing service may be activated when the distance between avatars of each user is within a preset range on the metaverse space.

In step S520, the server may obtain contractor information and contract condition information from users' devices. For example, the server may obtain contractor information and contract condition information based on conversation information between users on the metaverse space.

In step S530, the server may generate a draft contract file by adding the acquired contractor information and contract condition information to a preset contract template. For example, the server may add pre-set acquired contract condition information to a contract template immediately after acquiring contract condition information from conversation information between users.

Here, prior to generating the draft contract file, the server may determine a recommendable draft contract template based on conversation information such as chatting between users. For example, the server may crawl contract key phrases from conversation information between users in a chat window. In addition, at least one related contract draft template may be determined based on the crawled contract key phrases.

To this end, the server may implement and execute a pre-learned artificial neural network that takes contract key phrases as input values and contract type as output values. For example, the core phrase of the contract may be phrases related to transactions such as “sale”, “price”, and “amount”, and the type of contract may be a form of contract such as “sale contract” and “money lending contract”. there is.

In step S540, the server may transmit the generated draft contract file to the user terminals of the contractors. Terminals of users may display the contract draft file received from the server. Contractors may input information indicating that they have reviewed the draft contract displayed on the user terminal.

In step S550, the server may obtain review information indicating whether users review the draft confirmation contract from the user terminal.

In step S560, the server may generate a final contract file based on the review information received from the user terminal. For example, the server may generate a final contract file based on the draft contract file when review information is received from user terminals of all contractors. The operation of the server generating the final contract file of the contract conclusion system between users may be as described below.

The contract draft obtained and generated in steps S520 and S530 may be generated by an artificial intelligence learning algorithm. The algorithm for generating a draft contract can be learned by setting data on contract condition information as input data and the type of labeled contract as output data. That is, the algorithm sets contract condition information and various combinations of contract condition information in advance as training data, matches the type of contract to be inferred for each training data, and sets the labeled contract type data as output data. so it can be learned. Such a contract generation algorithm can be relearned and strengthened by the entire contract information when contracts are actually concluded among numerous contracts attempted on the metaverse and stored in the server and blockchain. The entire contract information includes contract condition information automatically detected by the system according to the present invention, contract condition information entered by the user, terms included in conversations related to contracts in actual chatting (including voice and text chatting), and The system may include at least one of the type of contract automatically detected by the system, the type of contract designated by the user, whether or not the contract is actually fulfilled, and the fulfillment rate for each contract type.

6 is a flowchart illustrating an operation of creating a final contract file in a contract conclusion system between users.

In step S561, the server may add information about each user to the draft contract. For example, the server may add at least one information of each user's name, identification ID, identification code, and signature information of each user to the draft contract.

In step S562, the server may generate a damage prevention code based on the contract signing information. Here, the server may generate an anti-tampering code based on at least one of information about the metaverse space, identification information of each user, and contract conclusion date and time information. The information about the metaverse space may include at least one of the metaverse platform and the location information of avatars of users who are subjects of contracts on the metaverse platform.

In step S563, the server may add a tamper protection code to the draft contract. According to one embodiment, the server may add an anti-tampering code to an area including an area displaying contract conditions included in the draft contract.

Alternatively, the server may add a divided anti-tampering code to each of the contract files provided to different users. Here, the divided anti-tampering code may be added on a symmetrical position to each of the contract files provided to different users.

In step S564, the server may generate a final contract file based on the draft contract further including user-related information and a tamper-prevention code.

Referring back to FIG. 5 , in step S570 , the server may request contract conclusion for the final contract from users who are contractors through the metaverse space, and may obtain information on whether or not to confirm the conclusion of the contract.

In step S580, the server may assign a hash value for the final contract file. The server may generate a hash value by generating a random number code having a preset number of bits and applying the generated random number code to a preset hash function. And the server can assign the generated hash value to the final contract file.

In addition, the server extracts a preset bit interval from the generated hash value and applies the extracted bit interval to another preset hash function to generate a symmetric/asymmetric encryption key including a private key and a public key. . Here, the server may generate a symmetric/asymmetric encryption key by applying a random number code to at least one hash function.

The server may encrypt the final contract file using a preset private key and store the encrypted final contract file in its own server and/or a separate database. Here, the private key may be generated based on identification information and/or authentication information of the user terminal of the contracting party.

In step S590, the server may register an ID for the final contract file based on the hash value. Here, the ID for the final contract file may be identification information for specifying the final contract file.

In step S600, the server may transmit information about the final contract file to the devices of the users. Here, the information on the final contract file may include the final contract file, an ID registered in the final contract, an encryption key, and the like.

And, the server can create a final contract object on the metaverse space and output the created object on the metaverse space. Therefore, avatars of users on the metaverse space can acquire the final contract object. And users can reconfirm whether or not the contract has been concluded in the metaverse space. The operation of the server that creates the final contract object on the metaverse space and outputs the created object on the metaverse space may be as described below.

7 is a flowchart illustrating an operation of outputting a metaverse contract object of a contract signing system between users.

In step S710, the server may reduce the image of the final contract file to correspond to the size of the user's avatar on the metaverse space.

In step S720, the server may correct at least a part of the damaged area in the image of the reduced final contract file. For example, if at least some areas including one or more pixels are damaged in the process of reducing the final contract file image, the server may correct at least some areas that are damaged by correcting one or more pixels.

In step S730, the server may create a metaverse contract object that is output in the form of an object on the metaverse space. Here, the metaverse contract object may be an object that can interact with users' avatars in the metaverse space.

In step S740, the server may output the created metaverse contract object on the metaverse space. Here, the server may output a metaverse contract object created based on location information of users who are the subjects of the contract. Therefore, avatars of users can acquire metaverse contract objects in the metaverse space.

8 is a diagram illustrating a process of initiating a contract between users' avatars in the metaverse space.

Referring to Figure 8, the metaverse UI / UX can be output on the output device of the user device. The metaverse UI/UX may include at least one input button for inputting a user input signal through a user device. For example, the at least one input button may include an input button for inputting a command to move the user avatar, an input button for inputting a command to rotate the screen of the device, an input button for inputting a sound signal, and a camera. An input button for inputting a photographed image may be included.

And, at least one or more user avatars may be output on the metaverse UI/UX. On the metaverse UI/UX, users can exchange messages with other users through chatting. The metaverse UI/UX may include a chatting window activation button 810 for activating chatting with other users.

The user may activate message exchange with other users by inputting a signal to the chatting window activation button 810 . In addition, the user may exchange messages with other users by inputting messages into the chatting window. By exchanging messages, users can conclude contracts.

9 is a diagram illustrating a process of activating contract signing between avatars of users in the metaverse space.

Referring to FIG. 9 , at least one user avatar may be displayed on the metaverse UI/UX. In addition, the chat window 910 activated on the metaverse UI / UX may be further output. The activated chat window 910 may output messages exchanged by users on the metaverse space.

In addition, a one-click contract activation button 920 may be displayed on the metaverse UI/UX. The one-click contract activation button 920 may be output on the activated chat window 910, or may be output on the metaverse UI / UX output to the user device. Here, the one-click contract activation button 920 may be activated when the distance between the avatars of contract parties is within a preset range.

When the user inputs a signal to the one-click contract activation button 920 output on the device, the server of the contract conclusion system performs an operation for inputting contract-related information and provides the user with a related interface for obtaining contract-related information. can be provided to the device.

10 is a diagram illustrating a process of inputting contract-related information in a contract platform on a metaverse space.

Referring to FIG. 10 , a user device that has received information about contract activation from a user may output a contract related information input window 1010 . And, the user device may transmit information about contract activation to the server of the contract conclusion system.

The server of the contract conclusion system that has received information on contract activation from the user device may transmit information on at least one interface for inputting contract-related information to the user device. As a result, the user device may output at least one interface for inputting contract-related information based on the information received from the server. Users of the contract platform on the metaverse space can input contract-related information through at least one interface output to the contract-related information input window 1010 on the device. Here, at least one interface may be as shown in FIG. 11 .

11 is a diagram illustrating an interface output to a contract condition input window. Referring to FIG. 11 , the user device may output a contract counterparty information input interface 1110 . The contract counterparty information input interface 1010 may include an area for inputting information capable of specifying the contractual counterparty and an area for outputting related information. The user may input information related to the other party to the contract in an area for inputting information capable of specifying the other party to the contract. Alternatively, the user may input information related to the other party to the contract by clicking the avatar of the other party in the metaverse space or by inputting a signal designating the avatar of the other party to the contract.

The user device may output the contract subject information input interface 1120 . The contract subject information input interface 1120 may include an area for inputting information capable of specifying a contract subject and an area for outputting related information. The user may input contract subject-related information in an area for inputting information capable of specifying a contract subject. Alternatively, the user may input information related to the contract object by clicking on the object of the contract object in the metaverse space or inputting a designating signal.

The user device may output the contract target quantity information input interface 1130 . The contract subject quantity information input interface 1130 may include an area for inputting information capable of specifying the quantity of a contract subject and an area for outputting related guidance item information. The user may input the quantity of the contract subject in an area for inputting information capable of specifying the quantity of the contract subject.

The user device may output the contract target price information input interface 1140 . The contract subject price information input interface 1140 may include an area for inputting information capable of specifying the price of a contract subject and an area for outputting related guidance information. The user may input the price of the contract subject in an area for inputting information capable of specifying the price of the contract subject.

The user device may output the additional special agreement information input interface 1150 . The additional special agreement information input interface 1150 may include an area for inputting additional special agreement information between contracting parties and an area for outputting related guidance information. The user may input special contract terms in an area for inputting additional special contract information between contracting parties.

12 is a diagram illustrating an embodiment of a process of inputting signature information in a contract platform on a metaverse space.

Referring to FIG. 12 , when the parties to the contract confirm the contract created by the contract platform in the metaverse space, a signature input request window 1210 may be output to the user device. If the device currently in use is not a smartphone, the signature input request window 1210 may include a link (eg, QR code, etc.) accessible using the smartphone and a related guide message.

When a user accesses a link using a device such as a smart phone, the device may output a signature input window 1220. Users can enter their signature into the device. As a result, the device can transmit the input signature to the server of the contract signing system between users. Here, the device may transmit user authentication information and/or authentication information to a server of a contract conclusion system between users. Further, the server may authenticate the user based on the user's authentication information and/or authentication information received from the device.

13 is a diagram illustrating another embodiment of a process of inputting signature information in a contract platform on a metaverse space.

Referring to FIG. 13 , when the parties to the contract confirm the contract created by the contract platform on the metaverse space, a signature input request window 1310 may be output to the user device.

If the device currently in use is a smartphone, the signature input request window 1310 may include a signature input window 1320. Users can enter their signature into the device. As a result, the device can transmit the input signature to the server of the contract signing system between users. Here, the device may transmit user authentication information and/or authentication information to a server of a contract conclusion system between users. The server may authenticate the user based on the user's authentication information and/or authentication information received from the device.

14 is a diagram showing an embodiment of a contract created in a contract platform on a metaverse space, and FIG. 15 is a diagram showing an embodiment of a contract created in a contract platform.

Contracts created on the contract platform may include contracts for asserting effectiveness in the metaverse space and/or contracts for asserting effectiveness in reality. For example, the contract shown in FIG. 14 may be a contract for asserting effectiveness in the metaverse space, and the contract shown in FIG. 15 may be a contract for asserting effectiveness in reality.

Referring to FIGS. 14 and 15 , the contract may include information about the parties to the contract, the purpose of the contract, conditions of the contract, other matters, and signatures of the parties to the contract.

Here, in the case of FIG. 14 , the information on the contracting party may be identification information such as an ID of the contracting party. On the other hand, in the case of FIG. 15 , information on the contracting party may be name information of the contracting party.

Also, referring to FIGS. 14 and 15 , a tamper protection code may be added to at least some areas of the contract. Here, the damage prevention code may be obtained by combining at least one of information about the metaverse space, identification information of each user, and contract conclusion date and time information, and converting the combined information into a code form.

The anti-tampering code may be added on an area including an area where contract parties and/or contract conditions included in the draft contract are indicated. Alternatively, the damage prevention code may be divided and added to each of the contract files provided to different users. Here, the divided damage prevention code may be added on a symmetrical position in each of the contract files. For example, when a divided tamper protection code is added to the center of the right boundary of the first contract, another divided tamper protection code may be added to the center of the left boundary of the second contract. As a result, the first contract may be provided to the first user, and the second contract may be provided.

The methods according to the present invention may be implemented in the form of program instructions that can be executed by various computer means and recorded on a computer readable medium. Computer readable media may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on a computer readable medium may be specially designed and configured for the present invention or may be known and usable to those skilled in computer software.

Examples of computer readable media include hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include high-level language codes that can be executed by a computer using an interpreter or the like as well as machine language codes generated by a compiler. The hardware device described above may be configured to operate with at least one software module to perform the operations of the present invention, and vice versa.

Although described with reference to the above embodiments, those skilled in the art will understand that the present invention can be variously modified and changed without departing from the spirit and scope of the present invention described in the claims below. You will be able to.

Claims (20)

In the operating method of the system for providing contract signing services between users on the metaverse space,
activating the contract signing service on the metaverse space displayed on the user's device;
obtaining contractor information and contract condition information based on conversation information between users on the metaverse space;
generating a contract draft file by adding the contract condition information to a preset contract template as soon as the contract management server receives the contract condition information;
transmitting, by a contract management server, a draft contract file, and displaying the generated draft file on the device of the user;
Acquiring, by the contract management server, review information about whether or not the draft of the confirmation contract has been reviewed from users who are contractors in the metaverse space;
generating, by a contract management server, a final contract file based on the review information;
A contract management server requesting users who are contractors to conclude a contract for a final contract through the metaverse space, and receiving confirmation information including signature information of each of the users and identification information of each of the users;
giving a hash value to the final contract file by a contract management server; and
Registering, by a contract management server, an ID for the final contract file based on the hash value; and
Transmitting information about the final contract file to the devices of the users,
The step of generating the final contract,
adding signature information of each of the users to the draft contract;
generating a tamper-resistant code;
adding the tamper protection code to the draft contract; and
And generating a final contract file based on the draft contract to which the signature information and the tamper protection code are added. In claim 1,
Encrypting the final contract file and generating an encryption key; and
Further comprising storing the encryption key and metadata related to the final contract on a blockchain network. In claim 1,
The contract signing service,
On the metaverse space, characterized in that activated when the distance between the avatars of each of the users is within a preset range, the operating method. delete delete In claim 1,
The anti-tampering code,
An operation method characterized in that it is generated based on at least one of information about the metaverse space, identification information of each of the users, and contract conclusion date and time information. In claim 1,
The anti-tampering code,
An operation method characterized in that the contract conditions included in the draft contract are added to an area including a displayed area; In claim 1,
The anti-tampering code,
It is divided and added to each of the contract files provided to different users,
The divided anti-tampering code,
An operation method characterized in that it is added on a symmetrical position in each of the contract files, In claim 1,
Generating a metaverse contract object output in the form of an object on the metaverse space based on the generated final contract file; and
Based on the location information of the avatars of the users, the operation method comprising the step of outputting the metaverse contract object on the metaverse space. In claim 9,
The step of creating the metaverse contract object,
reducing the image of the final contract file to correspond to the size of the user's avatar on the metaverse space;
Comprising the step of correcting at least a part of the damaged area in the image of the reduced final contract file, the operating method. In the server of the system for providing contract signing services between users in the metaverse space,
a memory in which at least one program instruction is stored;
a processor to execute the at least one program instruction; and
Including a transmitting and receiving device that is connected to the network and performs communication,
The at least one program command,
activating the contract signing service on the metaverse space displayed on a user's device;
obtaining contractor information and contract condition information based on conversation information between users on the metaverse space;
Upon receiving the contract condition information, the contract management server creates a contract draft file by adding it to a preset contract template;
the contract management server transmits the generated draft contract file and displays it on the user's device;
The contract management server obtains review information from users who are contractors in the metaverse space whether the draft of the confirmation contract has been reviewed;
the contract management server generates a final contract file based on the review information;
The contract management server requests users who are contractors to conclude a contract for the final contract through the metaverse space, and receives confirmation information including signature information of each of the users and identification information of each of the users;
the contract management server assigns a hash value to the final contract file;
the contract management server registers an ID for the final contract file based on the hash value; And
Execute to transmit information about the final contract file to the devices of the users,
The at least one program command,
In executing to generate the final contract,
add signature information of each of the users to the draft contract;
generate tamper-evident code;
add the tamper-evident code to the draft contract; And
A server of the system, which is executed to generate a final contract file based on the draft contract to which the signature information and the tamper-prevention code are added. In claim 11,
The at least one program command,
Encrypting the final contract file to generate an encryption key, and
A server of the system, further executed to store the encryption key and metadata related to the final contract on a blockchain network. In claim 11,
The contract signing service,
On the metaverse space, the server of the system, characterized in that activated when the distance between the avatars of each of the users is within a preset range. delete delete In claim 11,
The anti-tampering code,
Characterized in that the server of the system is generated based on at least one of information about the metaverse space, identification information of each of the users, and contract conclusion date and time information. In claim 11,
The anti-tampering code,
The server of the system, characterized in that the contract conditions included in the draft contract are added on an area including a displayed area. In claim 11,
The anti-tampering code,
It is divided and added to each of the contract files provided to different users,
The divided anti-tampering code,
Characterized in that it is added on a symmetrical position in each of the contract files, the server of the system. In claim 11,
The at least one program command,
Creating a metaverse contract object output in the form of an object on the metaverse space based on the generated final contract file; And
Based on the location information of the avatars of the users, the server of the system, which is executed to output the metaverse contract object on the metaverse space. In claim 19,
The at least one program command,
In executing to create the metaverse contract object,
reducing the image of the final contract file to correspond to the size of the user's avatar on the metaverse space;
A server of the system, which is executed to correct at least some areas that are damaged in the image of the reduced final contract file.

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