KR102376783B1 - The blockchain-based transaction history confirmation system - Google Patents

Abstract

A blockchain-based transaction history confirmation system is provided. The block chain-based transaction history confirmation system includes a user terminal in which a transaction history confirmation program is installed, a first block chain including transaction details through the transaction history confirmation program, and the transaction installed in the user terminal A full data server that verifies the validity of the transaction details stored in the history confirmation program and stores a second block chain including the entire transaction details, wherein the second block chain includes all transactions generated through the entire data server It is a connection structure of blocks in which details are recorded, and the first block chain has a structure in which only blocks recording transaction details related to the user related to the user terminal are selected and connected among the blocks of the second block chain, and the first block chain and blocks included in the second block chain include a previous block hash value and a previous block hash value based on a specific user node, and the first block chain includes a previous block hash value based on the specific user node. A block chain is formed through the connection, and the second block chain forms a block chain through the connection of the previous block hash value.

Description

The blockchain-based transaction history confirmation system

The present invention relates to a blockchain-based transaction history confirmation system, and more specifically, not only the hash value for the block immediately connected to the previous block like the existing blockchain structure, but also the hash value for the previous block related to the transaction history of a specific user node. It relates to a transaction system including a block chain structure composed only of blocks containing (or block height information).

Block chain, also called public transaction ledger, is a technology that prevents hacking that can occur when transacting with cryptocurrency. Whereas existing financial companies keep transaction records on a centralized server, blockchain sends transaction details to all users participating in the transaction and uses a method to prevent data falsification by verifying each transaction. Blockchain is applied to Bitcoin, a representative online cryptocurrency. Bitcoin transparently records transaction details in a ledger that anyone can read, and several computers using Bitcoin verify this record once every 10 minutes to prevent hacking.

On the other hand, blockchain is a data recording technology based on cloud technology and P2P technology, and anyone can become the subject of data storage and management and record the same information respectively. Here, the “block” of the block chain refers to a data storage unit, which is different from the meaning that a block of the file system is the minimum space in which one file can be allocated on a disk. Blockchain technology provides backup because it synchronizes the records of blocks in which the same data is stored between nodes that are the storage subjects of blocks.

Korean Patent Registration 10-1962285 (published on March 26, 2019)

The technical problem to be solved by the present invention is that, while forming and storing a basic block chain with blocks including the transaction details of all customers of the bank in the banking system, the information delivered to each specific customer is valid only for the transaction details of the customer Block chain data that is stored as transaction details and used to verify other customers’ transaction details and blocks is stored while protecting customer privacy by forming a block chain with blocks stored as hash values and delivering it to a specific customer It is to provide a financial transaction system that can minimize the size of

In addition, the technical problem to be solved by the present invention can be applied not only to the banking system but also to the credit card payment system, and while forming and storing a basic block chain with blocks including the entire transaction history of the credit card company, other users ( It is to provide a transaction history confirmation system in which the block chain for each user is stored for customers, franchisees, and relay nodes, which are multiple users).

However, the technical problems to be solved by the present invention are not limited to the above problems, and may be variously expanded without departing from the technical spirit and scope of the present invention.

A block chain-based transaction history confirmation system according to an embodiment of the present invention for solving the above problems, a digital passbook program is installed, and stores a first block chain including financial transaction details through the digital passbook program A user terminal and a bank server that verifies the validity of the financial transaction details stored in the digital passbook program installed in the user terminal and stores a second block chain including the entire financial transaction details, the second block The chain is a connection structure of blocks recording all financial transaction details generated through the bank server, and the first block chain is a block in which financial transaction details related to the user related to the user terminal are recorded among the blocks of the second block chain Only the blocks are selected and connected, and the blocks included in the first block chain and the second block chain include the previous block hash value 410 and the previous block hash value 420 based on a specific user node, The first block chain forms a block chain through the connection of the previous block hash value 420 based on the specific user node, and the second block chain blocks the previous block hash value 410 through the connection. form a chain

In some embodiments according to the present invention, the blocks included in the first block chain store the financial transaction details about the user related to the user terminal as valid transaction details, and are used for other financial transaction details and block verification. The history can be stored as a hash value.

A block chain-based transaction history confirmation system according to another embodiment of the present invention for solving the above problems, a user terminal in which a digital passbook program is installed, and generating a digital signal related to the digital passbook information, and from the user terminal and a bank server for receiving the digital signal, verifying the information on the digital passbook, verifying the validity of the digital passbook, and verifying the validity of a user terminal in which the digital passbook is installed, wherein the user terminal receives the digital passbook Stores a block chain including financial transaction details through The validity of the digital passbook can be verified, and the bank server can verify the validity of the user terminal by sending an authentication code to the user terminal in which the digital passbook is installed and then checking a response corresponding to the authentication code.

In some embodiments according to the present invention, the digital signal may include a QR code or an NFC signal.

In some embodiments according to the present invention, the bank server, after verifying the validity of the digital passbook and the validity of the user terminal, forms the block chain composed of only blocks in which financial transaction details related to the user related to the user terminal are recorded. to transmit to the user terminal.

A block chain-based transaction history confirmation system according to another embodiment of the present invention for solving the above problems, a digital confirmation program is installed, and a first block chain including transaction details that can be confirmed through the digital confirmation program A user terminal that stores, and a server that verifies the validity of the transaction details stored in the digital confirmation program installed in the user terminal, and stores a second block chain including the entire transaction history, wherein the second block chain is a connection structure of blocks recording the entire transaction history, and the first block chain has a structure in which only blocks recording transaction details related to the user related to the user terminal are selected and connected among the blocks of the second block chain, Blocks included in the first block chain and the second block chain include a previous block hash value 410 and a previous block hash value 420 based on a specific user node, and the first block chain includes the specific user node A block chain is formed through the connection of the previous block hash value 420 based on , and the second block chain is formed through the connection of the previous block hash value 410 .

In some embodiments according to the present invention, in the blocks included in the first block chain, transaction details related to the user related to the user terminal are stored as valid transaction details, and other transaction details and details used for block verification are It can be stored as a hash value.

A block chain-based transaction history confirmation system according to another embodiment of the present invention for solving the above problems is a first block in which a credit card payment program is installed and includes transaction details that can be checked through the credit card payment program A user terminal that stores a chain, and a server that verifies the validity of the transaction details stored in the credit card payment program installed in the user terminal and stores a second block chain including the entire transaction history, The 2 block chain is a connection structure of blocks recording the entire transaction history, and the first block chain is a structure in which only blocks recording transaction details related to the user related to the user terminal are selected from among the blocks of the second block chain and connected. , the blocks included in the first block chain and the second block chain include a previous block hash value 410 and a previous block hash value 420 based on a specific user node, and the first block chain includes the A block chain is formed through the connection of the previous block hash value 420 based on a specific user node, and the second block chain is formed through the connection of the previous block hash value 410.

In some embodiments according to the present invention, in the blocks included in the first block chain, transaction details related to the user related to the user terminal are stored as valid transaction details, and other transaction details and details used for block verification are It can be stored as a hash value.

Other specific details of the invention are included in the detailed description and drawings.

According to the present invention, unlike the existing block chain system, each user node stores only blocks including transaction details in which it is involved in its own node, thereby protecting customer privacy regarding transactions and also the size of the block chain data stored. can be minimized

In addition, according to the present invention, the user node can reduce the data storage space and prevent unnecessary resource waste by forming and storing only blocks including the transaction details in which the user node is involved in a new block chain structure.

In addition, according to the present invention, it is possible to prevent damage such as hacking or theft related to transactions through a double verification process for digital devices.

However, the effects of the present invention are not limited to the above effects, and may be variously expanded without departing from the spirit and scope of the present invention.

1 is a diagram illustrating a distributed processing system using a block chain to which the technical idea according to the present invention can be applied.
2 and 3 are block diagrams illustrating the connection of blocks used in a block chain system.
4 is a block diagram schematically illustrating the configuration of a financial transaction system according to the present invention.
5 and 6 are diagrams illustrating an existing block chain connection structure.
7 and 8 are diagrams illustrating a block chain connection structure according to the technical idea of the present invention.
9 is a diagram exemplarily illustrating the generation of a custom block for each user in the present invention.
10 is a diagram illustrating a data comparison process between a digital passbook and a bank server in the present invention.
11 is a diagram illustrating a digital passbook issuance procedure according to the present invention.
12 is a view for explaining a process of recording transaction history information in the financial transaction system according to the present invention.
13 is a diagram illustrating a procedure for performing a bank transaction using a digital passbook in the financial transaction system according to the present invention.
14 is a block diagram illustrating the configuration of a transaction history confirmation system according to the present invention.
15 is a block diagram illustrating the configuration of a credit card payment system according to the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be embodied in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims.

The terminology used herein is for the purpose of describing the embodiments, and is not intended to limit the present invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, "comprises" and/or "comprising" refers to the presence of one or more other components, steps, operations and/or elements mentioned. or addition is not excluded.

Unless otherwise defined, all terms (including technical and scientific terms) used herein may be used with the meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not to be interpreted ideally or excessively unless specifically defined explicitly.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and repeated descriptions of the same components are omitted.

When explaining the concept of a block chain-based digital passbook applied to the financial transaction system according to the present invention, a new block chain structure different from the existing block chain structure is used, but transaction details related to a specific user node are composed of block chain data. It means a passbook of a new concept that can be stored in digital devices and can be used for bank transactions. That is, the digital passbook refers to a blockchain-based digital passbook program installed in a user terminal and used for bank transactions, and hereinafter, it will be referred to as a "digital passbook" for convenience.

In the past, only bank servers have digital financial transaction data, and customers do not have digital financial transaction data itself, so information asymmetry has occurred and data is monopolized. However, due to the development of blockchain technology, even customers who make bank transactions using internet banking can store financial transaction data with transaction details recorded in their own nodes, which is necessary for balancing trust between the bank and customers. .

In addition, the existing passbooks used for bank transactions are paper passbooks, and because of the importance of passbooks, the paper for making passbooks does not use general paper but uses special paper suitable for it. Check the authenticity of passbooks and account numbers It also includes a magnetic device for Therefore, a considerable production cost is consumed to make one paper passbook. The present invention is also proposed to replace such a paper passbook.

If you use blockchain technology, you can change the transaction details of a passbook into a data structure composed of blockchain and store it in a digital device for use. However, it is not possible to create a digital passbook with this data structure with the existing block chain structure. This is because the existing block chain structure is a structure that sequentially connects all blocks.

A decentralized system using existing blockchain technology is created so that all nodes share all blockchain data equally. However, the passbook used for financial transactions cannot and should not share the data of all customers equally. In addition, the amount of transactions performed in a bank increases exponentially over time, and no matter how large the storage space of a digital device is, there is a limit to the storage space. If the transaction details are continuously updated, excessive network traffic is generated. If this series of processes is for all customers of the bank, the total network traffic will be excessively issued.

Therefore, with the existing block chain structure, it is virtually impossible to distribute and store financial transaction details in digital devices. to be saved on the device. Using this, we propose a new financial transaction system that allows you to conduct banking transactions in the same way as doing bank transactions with an existing passbook.

Prior to the description of the present invention, the concept of a distributed processing system (decentralized system) using a block chain will be described.

1 is a diagram illustrating a distributed processing system using a block chain to which the technical idea according to the present invention can be applied.

Referring to FIG. 1 , a distributed processing system 100 using a block chain is a distributed network system consisting of a plurality of nodes 110-170. The nodes 110 to 170 constituting the distributed processing system 100 may be electronic devices having computational capabilities, such as computers, mobile terminals, and dedicated electronic devices.

In general, the distributed processing system 100 can store and refer to information commonly known to all participating nodes in a connected bundle of blocks called a block chain. The nodes 110-170 can communicate with each other and can be divided into a full node that stores, manages, and propagates the block chain and a light node that can simply participate in transactions. . In this specification, when referring to a node without further explanation, it often refers to a complete node that participates in the distributed network of the distributed processing system 100 and performs an operation to create, store, or verify a block chain, but in this It is not limited.

Each block connected to the block chain includes transaction details, that is, transactions within a certain period. The nodes 110-170 can manage transactions by creating, storing, or verifying a block chain according to their respective roles.

According to an embodiment, the transaction may represent various types of transactions. In an embodiment, the transaction may correspond to a financial transaction detail for indicating the state of ownership of money and its change generated through a bank transaction. In another embodiment, the transaction may correspond to a physical transaction detail for indicating the ownership status of a product and its change. Nodes performing a transaction in the distributed processing system 100 may have a private key and a public key pair each cryptographically related.

2 and 3 are block diagrams illustrating the connection of blocks used in a block chain system.

Referring to FIG. 2 , the block chain 200 is a kind of distributed database of one or more sequentially connected blocks 210 , 220 , 230 . The block chain 200 is used to store and manage user's transaction details in the block chain system, and each node participating in the network of the block chain system creates a block and connects it to the block chain 200 . Although a limited number of blocks 210 , 220 , and 230 are illustrated in FIG. 2 , the number of blocks that can be included in the block chain is not limited thereto.

Each block included in the block chain 200 may be configured to include a block header 211 and a block body 213 . The block header 211 may include a hash value of the previous block 220 to indicate a connection relationship between blocks. In the process of verifying whether the block chain 200 is valid, the connection relationship in the block header 211 is used. The block body 213 may include data stored and managed in the block 210 , for example, a transaction list or a transaction chain.

Referring to FIG. 3 , the block header 211 may include a hash 2112 of a previous block, a hash 2113 of a current block, and a nonce 2114 . In addition, the block header 211 may include a root hash 2115 indicating the header of the transaction list in the block.

As described above, the blockchain 200 may include one or more connected blocks. The one or more blocks are connected based on a hash value in the block header 211 . The hash value 2112 of the previous block included in the block header 211 is the same as the current hash 2213 included in the previous block 220 as a hash value of the previous block 220 . The one or more blocks are chained by the hash value of the previous block in each block header. Nodes participating in the distributed network verify the validity of a block based on the hash value of the previous block included in the one or more blocks, so it is impossible for a single malicious node to forge or alter the contents of an already created block Do.

The block body 213 may include a transaction list 2131 . The transaction list 2131 is a list of blockchain-based transactions. For example, the transaction list 2131 may include a record of financial transactions made in the blockchain-based financial system. The transaction list 2131 may be expressed in the form of a tree, and for example, the amount transmitted by user A to user B is recorded in the form of a list, and the storage length in the block is the length of the transaction included in the current block. It can be increased or decreased based on the number.

In addition, the block 210 may include other information 2116 other than the information included in the block header 211 and the block body 213 .

Nodes participating in a decentralized network have the same blockchain, and the same transactions are stored in blocks. A block containing a list of transactions is shared on the network, so all participants can verify it.

4 is a block diagram schematically illustrating the configuration of a financial transaction system according to the present invention.

Referring to FIG. 4 , the digital passbook 320 used in the financial transaction system 300 according to the present invention can communicate and be installed in a digital device (ie, a user terminal) 310 in which a certain storage space is secured. there is.

The financial transaction details of the digital passbook 320 stored in the digital device 310 must match the financial transaction details stored in the bank server 350 . This is because the basic purpose of a passbook is that the customer and the bank have the same transaction details.

To this end, when a bank transaction occurs, the customer and the bank can store the transaction details in the digital passbook 320 by the customer and the bank in the database of the bank server 350 equally. In this way, both sides store the same transaction details, so it can be said that it has the basic function of a passbook. However, such transaction details must always ensure that the customer's digital passbook 320 details and the contents stored in the database of the bank server 350 are the same.

The contents stored in the database of the bank server 350 are less likely to be erroneous due to thorough data management and security, but the contents stored in the customer's digital passbook 320 do not receive transmitted transaction details or store transaction details There is a possibility that some of the information may be erased or the customer may modify the storage history, resulting in incorrect information. Accordingly, it is necessary to check whether the contents of the digital passbook 320 stored in the digital device 310 by the customer are valid data.

At this time, if the customer's bank transaction details are small, each transaction history may be compared with the details stored in the database of the bank server 350 one by one. However, if the customer's transaction details are tens or tens of thousands, comparison with the database details of the bank server 350 becomes complicated. Therefore, there is a need for a blockchain data structure that can easily and quickly check whether distributed data is consistent.

A blockchain data structure is a data structure that trusts that all data in front is the same data as long as the data in the last block is the same. Therefore, even if thousands or tens of thousands of data are stored, checking the data of the last block is the same as checking all data, so the validity of the digital passbook 320 can also be easily checked through the block chain structure.

However, since the existing block chain structure is a structure in which all data is sequentially connected, and all data is sequentially connected, in order to use it effectively, all block chain data must be stored.

The digital passbook 320 contains private data, and it is impossible to store all block chain data because the storage is also stored in the personal digital device 310 . Therefore, the block chain structure used in the digital passbook 320 must use a chain structure between blocks formed only with the financial transaction details of a specific customer.

In this case, since only the transaction details of a specific customer are stored, the amount of data to be stored is very small compared to the total amount of data, and since the data to be stored is one's own, it is difficult to store data in one's own digital device 310. The user's refusal is also eliminated.

However, since the block chain structure is not stored in transaction details, that is, in units of transactions, but is made up of a collection of multiple transactions, it is not possible to separate and store each transaction history. It should be stored as a unit. However, the existing block chain structure cannot form a block chain structure with only specific customer blocks. This is because the blockchain connection is a sequential connection of all blocks.

5 and 6 are diagrams illustrating an existing block chain connection structure, and FIGS. 7 and 8 are diagrams illustrating a block chain connection structure according to the technical idea of the present invention. 9 is a diagram exemplarily illustrating the generation of a custom block for each user in the present invention. 10 is a diagram illustrating a data comparison process between a digital passbook and a bank server in the present invention.

5 and 6, the existing block chain connection structure is formed in such a way that the current block verifies the trust connection to the previous block by storing the hash value of the data of the previous block in the header of the current block. Therefore, the hash connection between the front and back blocks of the block chain is an indispensable element in the existing block chain structure. However, because of this single-connected blockchain structure, for reliable blockchain data, all user nodes must each store the entire blockchain data. This is because reliability between blocks cannot be guaranteed unless the blocks immediately before and after are connected. That is, in the existing block chain structure, reliable data can be connected only by block order. This is not a connection about associations between data within a block.

From the point of view of the entire system called blockchain, it may be reasonable to define the data connection relationship by block order because all blocks must be trusted. As long as the reliability is confirmed, there is no problem in securing the reliability of the entire blockchain data. In other words, each user node does not need to store other blockchain data to process its own transaction data.

7 and 8, in the block chain structure according to the technical idea of the present invention, not only the hash value 410 for the block immediately preceding, but also the hash value (or block height) for the previous block related to a specific user node information) 420, so that blocks can be connected based on a specific user node. Through the block chain structure according to the present invention, it is possible to form a block chain structure consisting of only blocks including the customer's financial transaction details for each customer.

If the blocks to which user node A is related are '#283', '#316', '#782', and '#905', respectively, a hash value (or block height information) 420 is connected between each block. Therefore, data connection between blocks is possible even if the order of blocks is not immediately preceding and following.

In the case of user node A, if the necessary financial transaction data to be associated with it exists in all four blocks, there is no need to store other block chain data as long as its reliability is secured. This prevents unnecessary waste of storage space and achieves reliability, which is a unique characteristic of blockchain technology. Since blocks stored in user node A are connected by hash values (or block height information) 420 between each block based on the user, reliability of data can be secured.

As such, if only user node A's own block chain data is stored, data can be stored in all user nodes without securing a large amount of storage space, which is a problem due to storing the entire block chain data. In addition, as the digital passbook 320, privacy of private financial transaction information can be protected.

The safety and reliability of the blockchain system is ensured because multiple nodes distribute and store the same blockchain data. Accordingly, in the application of the technical idea according to the present invention, not only own data is stored in a block stored in one user node, but also data related to other user nodes are also stored. Therefore, even if each user node selectively stores only the block associated with it, the block is distributed and stored in all user nodes related to the block at the same time.

In the block chain structure, not only the transaction details of a specific user are stored in the block, but also the transaction details of other users. However, since the digital passbook 320 stores its own transaction details and not the transaction details of other customers, it is not necessary and should not have the transaction details of other customers. Therefore, in the financial transaction system 300 according to the present invention, when forming the basic block collecting the transaction details of all customers of the bank, a block including the transaction details of all customers is formed, but when transferring this to the user node for each customer, each customer It is made into a star custom block and transmitted.

9 shows the creation of a custom block for each customer, and the custom block for each customer (user) stores only the transaction details of the corresponding customer as valid transaction details, and is used to verify the transaction details and blocks of other customers is stored as a hash value to protect customer privacy and minimize the size of the block data to be stored.

When the block chain structure for each customer is formed in this way, the validity of the transaction details stored in the digital device 310 can be checked by itself, and only the hash value of the customer's last block stored in the digital passbook 320 is the bank server. Comparing with the hash value of the corresponding block stored in , it can be confirmed that the database details of the customer's digital passbook 320 and the bank server 350 are the same (refer to FIG. 10).

Hereinafter, a process in which a financial transaction occurs through the financial transaction system according to the present invention will be described.

11 is a diagram illustrating a digital passbook issuance procedure according to the present invention. 12 is a view for explaining a process of recording transaction history information in the financial transaction system according to the present invention.

11, the digital passbook 320 issuance procedure according to the present invention is shown. Since the digital passbook 320 is also a type of passbook, the issuance is also made at a bank window or is issued in a non-face-to-face manner through online identity verification. can be The reason why the digital passbook 320 issuance is made at the bank window is that not only the customer must be confirmed, but also whether the digital device 310 storing the digital passbook 320 is valid must be verified.

The verification of the digital device 310 is performed by transmitting the authentication code to the digital device 310 in which the digital passbook app (program) registered by the customer is installed, and then generating the authentication code as a QR code or NFC signal, which is a digital passbook verification method, and Judging by whether the banking system can read it. However, the present invention is not limited thereto, and verification may be performed using other digital signals.

In the banking system, if the authentication code generated by the digital device 310 can be read, the digital device 310 is a device that can install and use the digital passbook 320, so the digital device 310 is registered and the customer's transaction The history block chain data is transmitted to the corresponding digital device 310 .

When the transmission of the block chain data is completed, it is checked whether the digital passbook 320 is usable by reading the digital passbook verification code made of the customer account number, the last block hash value, the current time, etc., and through this, the digital passbook issuance is completed.

12, the process of recording transaction history information in the financial transaction system according to the present invention is shown, and the block chain data to be stored in the digital passbook 320 is a bank transaction (passbook, ATM machine, Internet banking, etc.) ) based on the transaction details created in

When a bank transaction is made, the corresponding transaction details are ultimately stored in the database of the bank server 350, and only the valid transaction details are converted into blocks by comparing the transaction details that occurred at this time with the data data stored in the database of the actual bank server 350. and include it in the entire blockchain data.

When a new block is added by the bank's blockchain system, a custom block is created for each customer within the block based on this and transmitted to each customer's digital device. The blocks customized for each customer are the same as those described with reference to FIG. 9 .

When the transmitted custom block for each customer arrives at the corresponding digital device 310 , the digital passbook 320 notifies that new transaction details have been transmitted, and the customer can open the digital passbook 320 and check it.

In addition, even if a new block does not arrive, the customer's transaction history is always stored in the digital passbook 320, so it can be opened at any time to check the passbook details.

The method of recording the customer's transaction details in the digital passbook 320 has been described so far, but since the passbook is not a book that simply records only the transaction details, it is necessary to make bank transactions through an actual passbook. A procedure for performing a bank transaction through the financial transaction system 300 will be described.

13 is a diagram illustrating a procedure for performing a bank transaction using a digital passbook in the financial transaction system according to the present invention.

Since the digital passbook 320 is data stored in the digital device 310, that is, software, it can be easily copied to other digital devices. Therefore, the digital passbook 320 should not be used in any digital device like a bank app, and the issuance itself should be issued only to an authenticated digital device having a serial number.

For example, in the case of a smartphone, each smartphone has a device number, and the device number and phone number are connected, so that when the base station sends a call signal, it is connected to the corresponding smartphone. By issuing the digital passbook 320 to the authenticated digital device 310 having the serial number in this way, even if a digital passbook of another customer is copied and transferred to a new digital device, bank transactions cannot be performed through this.

If the digital device 310 is lost, someone may acquire the digital device and use it. must be obtained so that it can be used.

In order to make a bank transaction with the digital passbook 320 issued to the authenticated digital device 310 having a serial number, an authentication step must be performed.

First, information of the digital passbook 320 must be read from the digital device 310 . There are largely two methods for reading information from the digital device 310 . The first is to use a QR code, and the second is to use NFC. However, the present invention is not limited thereto, and can be applied to any method that can create and read a digital signal.

When the QR code is used, information on the digital passbook 320 is displayed on the screen of the digital device 310 as a QR code, and then the information on the digital passbook can be read by reading it with a QR code reader.

In the case of the NFC method, the digital device 310 makes the information on the digital passbook 320 into an NFC signal, and by bringing the digital device 310 close to a place that can receive the NFC signal, the information of the digital passbook 320 is stored. to make it read Of course, in order to use this method, the digital device 310 must be able to generate an NFC signal, which is to check whether an NFC signal can be created when opening the digital passbook 320 for the first time through digital passbook verification.

In the digital passbook 320 according to the present invention, both the QR code method and the NFC method can be used, and they can be selectively used according to the convenience of the customer and the policy of the bank.

When the digital passbook usage method is determined according to each customer's digital device 310, the account information of the digital passbook 320 stored in the digital device 310, the last block hash value of the block chain, and the current time, etc. By generating the combined QR code or NFC signal, it is checked whether the account of the corresponding digital passbook is correct, and whether the transaction details stored in the digital passbook 320 match the database details of the bank server 350 .

Basically, except for the customer and the bank, since the account information and the last hash value of the customer cannot be known at the same time, it is possible to check the validity of the digital passbook 320 with this alone.

However, as mentioned above, since the digital passbook of another customer can be copied and used, the authentication step of verifying whether the digital device 310 that issued the digital passbook 320 in the first place is performed once more.

Once it is confirmed that the digital passbook 320 is, the authentication code for the digital passbook 320 is sent to the digital device 310 that was registered when the digital passbook 320 was initially issued, and it is converted to a QR code or NFC signal. make it so you can read it again.

If the digital passbook 320 is copied and used with another digital device, the use of the digital passbook cannot be permitted because the authentication code transmitted from the bank server cannot be received.

After going through such a two-step authentication process, bank transactions through the digital passbook 320 are possible.

From then on, the transaction can be carried out in the same way as a bank transaction using a normal paper passbook, and the transaction is completed by entering the passbook password at the end.

When a transaction is completed, a block is created for the transaction history, and this block is made into a custom block for each customer and transmitted to the customer's digital passbook so that the digital passbook can always keep the latest transaction details.

In addition, the hash value of this new block will be used as digital passbook verification information for subsequent bank transactions.

14 is a block diagram illustrating the configuration of a transaction history confirmation system according to the present invention.

Referring to FIG. 14 , the digital confirmation program used in the transaction history confirmation system according to the present invention may be installed in a digital device (ie, a user terminal) 310 that is capable of communication and has a certain storage space secured.

The validity of the transaction details stored in the digital confirmation program stored in the digital device 310 is verified through the server, and the records are recorded in the entire block chain. And, the block chain stored in the user terminal 310 stores the block chain by the connection of custom blocks for each customer (user).

As described above, in the custom block for each customer, only the transaction details of the customer are stored as valid transaction details, and the other customer’s transaction details and the details used to verify the block are stored as hash values, protecting customer privacy, It also minimizes the size of the block data to be stored.

When the block chain structure for each customer is formed in this way, the validity of the transaction details stored in the user terminal 310 can be checked by itself, and only the hash value of the customer's last block stored in the digital confirmation program is stored in the server. Comparing it with the hash value of the corresponding block, it can be confirmed that the customer's digital confirmation program and the database details of the server are the same.

Transaction details described herein may include, for example, credit card billing details, insurance policy or insurance premium payment details, doctor’s medical records, product purchase refund details or after-sales service, etc. In addition, the transaction history confirmation system according to the present invention can be extended and applied to various fields.

15 is a block diagram illustrating the configuration of a credit card payment system according to the present invention.

Referring to FIG. 15 , the credit card payment program used in the credit card payment system according to the present invention may be installed in a digital device (ie, a user terminal) 310 capable of communication and having a certain storage space secured.

The validity of the transaction details stored in the credit card payment program stored in the digital device 310 is verified through the server, and the records are recorded in the entire block chain. And, the block chain stored in the user terminal 310 stores the block chain by the connection of custom blocks for each customer (user).

As described above, in the custom block for each customer, only the transaction details of the customer are stored as valid transaction details, and the other customer’s transaction details and the details used to verify the block are stored as hash values, protecting customer privacy, It also minimizes the size of the block data to be stored.

When the block chain structure for each customer is formed in this way, the validity of the transaction details stored in the user terminal 310 can be checked by itself, and only the hash value of the customer's last block stored in the digital confirmation program is stored in the server. Comparing it with the hash value of the corresponding block, it can be confirmed that the customer's digital confirmation program and the database details of the server are the same.

It is to be understood that the above-described embodiments are illustrative in all respects and not restrictive, and the scope of the present invention will be indicated by the appended claims rather than the foregoing detailed description. And it should be construed that all changes and modifications derived from the meaning and scope of the claims as well as equivalent concepts are included in the scope of the present invention.

100: distributed processing system
200: Blockchain
300: financial transaction system
310: digital device
320: digital passbook
350: bank server
410: previous block hash value
420: previous block hash value based on a specific user node

Claims (9)

a user terminal installed with a digital passbook program and storing a first block chain including financial transaction details through the digital passbook program; and
A bank server that verifies the validity of the financial transaction details stored in the digital passbook program installed in the user terminal and stores a second block chain including the entire financial transaction details;
The second block chain is a connection structure of blocks that record the entire financial transaction details generated through the bank server,
The first block chain has a structure in which only blocks recording financial transaction details related to the user related to the user terminal are selected and connected among the blocks of the second block chain,
The blocks included in the first block chain and the second block chain include a previous block hash value 410 and a previous block hash value 420 based on a specific user node. Block chain based, which forms a block chain through the connection of the previous block hash value 420 based on the user node, and the second block chain forms the block chain through the connection of the previous block hash value 410 of transaction history confirmation system. The method of claim 1,
The blocks included in the first block chain are
A blockchain-based transaction history confirmation system that stores financial transaction details related to the user related to the user terminal as valid transaction details, and stores other financial transaction details and details used for block verification as hash values. a user terminal having a digital passbook program installed and generating a digital signal related to the digital passbook information; and
A bank server that receives the digital signal from the user terminal, checks the information on the digital passbook, verifies the validity of the digital passbook, and verifies the validity of the user terminal in which the digital passbook is installed;
The user terminal stores a block chain including financial transaction details through the digital passbook,
The bank server can verify the validity of the digital passbook by extracting digital passbook information including account information of the digital passbook, the last block hash value of the block chain, and current time information from the digital signal,
After the bank server sends an authentication code to the user terminal in which the digital passbook is installed, it is possible to verify the validity of the user terminal by checking a response corresponding to the authentication code. 4. The method of claim 3,
The digital signal includes a QR code or NFC signal, a blockchain-based transaction history confirmation system. 4. The method of claim 3,
The bank server,
After verifying the validity of the digital passbook and the validity of the user terminal, the blockchain-based transaction history is formed and transmitted to the user terminal by forming the block chain consisting only of blocks in which financial transaction details relating to the user related to the user terminal are recorded. verification system. a user terminal in which a digital confirmation program is installed and storing a first block chain including transaction details that can be verified through the digital confirmation program; and
A server that verifies the validity of the transaction details stored in the digital confirmation program installed in the user terminal and stores a second block chain including the entire transaction details; includes;
The second block chain is a connection structure of blocks recording the entire transaction history,
The first block chain has a structure in which only blocks in which transaction details related to the user related to the user terminal are recorded are selected and connected among the blocks of the second block chain,
The blocks included in the first block chain and the second block chain include a previous block hash value 410 and a previous block hash value 420 based on a specific user node. Block chain based, which forms a block chain through the connection of the previous block hash value 420 based on the user node, and the second block chain forms the block chain through the connection of the previous block hash value 410 of transaction history confirmation system. 7. The method of claim 6,
The blocks included in the first block chain are
The transaction details related to the user terminal are stored as valid transaction details, and other transaction details and details used for block verification are stored as hash values. a user terminal installed with a credit card payment program and storing a first block chain including transaction details that can be verified through the credit card payment program; and
A server that verifies the validity of the transaction details stored in the credit card payment program installed in the user terminal and stores a second block chain including the entire transaction details; includes,
The second block chain is a connection structure of blocks recording the entire transaction history,
The first block chain has a structure in which only blocks in which transaction details related to the user related to the user terminal are recorded are selected and connected among the blocks of the second block chain,
The blocks included in the first block chain and the second block chain include a previous block hash value 410 and a previous block hash value 420 based on a specific user node. Block chain based, which forms a block chain through the connection of the previous block hash value 420 based on the user node, and the second block chain forms the block chain through the connection of the previous block hash value 410 of transaction history confirmation system. 9. The method of claim 8,
The blocks included in the first block chain are
The transaction details related to the user terminal are stored as valid transaction details, and other transaction details and details used for block verification are stored as hash values.

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