KR102170031B1 - Method, Recording medium and Blockchain system for confirming blockchain transaction using location information - Google Patents

Abstract

Blockchain transaction authentication method, recording medium and blockchain system are provided. According to this blockchain transaction authentication method, a block chain consisting of blocks containing location information is formed, and when a transaction occurs, the transaction is authenticated using the location information, and the block generated as a result of transaction authentication can be connected to the blockchain. Thus, it is possible to improve the performance of transaction authentication and increase the security of transaction authentication by participating in the network consensus for blockchain transaction authentication only for nodes whose location information is verified. In addition, fewer nodes can participate in the blockchain network consensus while obtaining more secure authentication results, and it will be possible to track transaction history based on location.

Description

Blockchain transaction authentication method using location information, recording medium and blockchain system {Method, Recording medium and Blockchain system for confirming blockchain transaction using location information}

The present invention relates to a block chain transaction authentication method, a recording medium, and a block chain system, and more particularly, to a block chain transaction authentication method, a recording medium, and a block chain system for authenticating transactions using location information.

Blockchain is composed of thousands or tens of thousands of nodes connected by network. And when a transaction is issued, it is operated in a similar manner to a distributed ledger that records the transaction in a distributed node. Therefore, it is virtually impossible to change a transaction once recorded. This is changing the DB connected to the central server in the centralized system, which is fundamentally different from the method of easily changing the previous transaction details. Blockchains that are difficult to forge or alter once executed transactions can be used in various fields such as finance, IoT, electronic voting, and transaction history tracking. This is why blockchain has been in the spotlight recently.

However, blockchain does not have only advantages. As recorded transactions are difficult to forge or alter, the process of authenticating and recording transactions is rather complicated. The transaction authentication required when creating a new block occurs through a process called network consensus. Transactions that took place in the form of P2P are propagated to the periphery, and transactions are authenticated (in fact, with consent) that have been propagated to more than 50% of the nodes constituting the blockchain. Therefore, there is a problem in that transactions are authenticated only after obtaining the consent of many nodes.

The inefficiency of the blockchain network consensus process is directly related to obtaining 50% or more consent. If the block creation is acknowledged and the block chain is operated for the block with the consent of 40%, 30%, and 20% less than 50%, a more efficient system can be built. Of course, this should not compromise the security of transaction authentication in the blockchain.

It is requested to find a way to make such a blockchain consensus simpler and faster.

The present invention was conceived to solve the above problems, and an object of the present invention is to construct a block chain composed of blocks including location information, and when a transaction occurs, use the location information to authenticate the transaction, and It is to provide a block chain transaction authentication method, a recording medium, and a block chain system that connects the block generated as a result of authentication to the block chain.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. I will be able to.

In accordance with an embodiment of the present invention for achieving the above object, a block chain transaction authentication method using a block chain system includes: constructing a block chain composed of blocks including location information; Authenticating the transaction using location information when a transaction occurs; And connecting the block generated as a result of transaction authentication to the blockchain.

In addition, a block including location information may include a location pointer in the block header and a node location list in the block body.

In addition, in the step of constructing a blockchain, a blockchain may be formed with nodes whose locations have been verified.

In addition, it may further include a step of expressing the nodes whose location is identified as a minimum spanning tree to calculate a'total distance sum' which is the sum of distances between nodes constituting the corresponding minimum cost spanning tree. .

In addition, in the step of authenticating the transaction, the nodes that have received the transaction information are expressed as a minimum spanning tree, and the'sum of authentication distances', which is the sum of the distances between the nodes constituting the corresponding minimum cost spanning tree, is calculated. In addition, the transaction may be authenticated using'sum of authentication distances','sum of total distances','number of nodes that have received the transaction information', and'number of nodes whose location is confirmed'.

And, in the step of authenticating the transaction, if the ratio of the'sum of authentication distances' to the'sum of total distances' ('sum of authentication distances' /'sum of total distances') is greater than or equal to the threshold, it is determined that the authentication of the transaction is completed. May be.

In addition, in the step of authenticating the transaction, even if the ratio of the'sum of authentication distances' to the'sum of total distances' ('sum of authentication distances' /'sum of total distances') is less than the threshold value, When'the number of nodes' exceeds half of the'number of nodes whose location is confirmed', it may be determined that the transaction has been authenticated.

In the step of connecting to the blockchain, for all nodes, the block generated as a result of transaction authentication may be additionally connected to the blockchain of each node.

In addition, in the block generated as a result of transaction authentication, a transaction item ID for a corresponding transaction may be recorded.

In addition, in the block generated as a result of the transaction authentication, the location information of the sender device and the location information of the receiver device for the corresponding transaction may be recorded.

On the other hand, according to an embodiment of the present invention, a computer-readable recording medium containing a computer program for performing a block chain transaction authentication method using a block chain system constitutes a block chain consisting of blocks including location information. Step to do; Authenticating the transaction using location information when a transaction occurs; And connecting the block generated as a result of transaction authentication to the blockchain; a computer program for performing a blockchain transaction authentication method is included.

On the other hand, according to an embodiment of the present invention, a block chain system includes a device participating in a transaction using a block chain; And a block chain node that configures a block chain composed of blocks including location information, authenticates the transaction using the location information when a transaction occurs by the device, and connects the block generated as a result of the transaction authentication to the block chain. Include.

According to various embodiments of the present invention, a block chain consisting of blocks containing location information is constructed, and when a transaction occurs, the transaction is authenticated using the location information, and the block generated as a result of transaction authentication is connected to the blockchain. Blockchain transaction authentication method, recording medium and blockchain system can be provided, so that only nodes whose location information is verified participate in the network consensus for blockchain transaction authentication, thereby improving the performance of transaction authentication and It is possible to increase safety. In addition, fewer nodes can participate in the blockchain network consensus while obtaining more secure authentication results, and it will be possible to track transaction history based on location.

1 is a block diagram showing the structure of a block chain system according to an embodiment of the present invention;
2 is a flowchart provided to explain a method of authenticating a block chain transaction according to an embodiment of the present invention,
3 is a diagram showing a structure of one block constituting a block chain according to an embodiment of the present invention;
4 is a diagram illustrating a screen displaying details of one transaction according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 is a block diagram showing the structure of a block chain system according to an embodiment of the present invention. 1, the block chain system 100 is composed of a terminal device 110 and a block chain node 120, and the block chain node 120 is a block chain network 130 composed of other block chain nodes. ).

The terminal device 110 is a device that participates in a transaction using a block chain.

Blockchain node 120 configures a block chain composed of blocks containing location information, and when a transaction occurs by a device, uses the location information to authenticate the transaction, and connects the block generated as a result of transaction authentication to the blockchain. And, the generated block is delivered to other blockchain nodes on the blockchain network 130. It goes without saying that the block chain node 120 may be a separate server, or the terminal device 110 described above may perform the function of a block chain node together.

Through this, the block chain system 100 of FIG. 1 constitutes a location-based block chain.

The blockchain node 120 connected to the Internet can generate location information by checking the location using an IP address or a wireless LAN signal or mobile communication signal collected through a wireless signal receiver mounted on the blockchain node 120. . In addition, such a location-based block chain system 100 participates a block chain node whose location is confirmed as a node constituting a block chain. The network consensus mechanism for transaction authentication of the location-based blockchain system 100 may improve the performance of transaction authentication by additionally utilizing the location information of the blockchain node.

The terminal device 110 (computer, laptop, smartphone, etc.) participating in the transaction may use GPS, wireless LAN, or IP address to generate location information of a point where a transaction occurs or location information of a point where the transaction is processed. In this case, the terminal device 110 may be a sender device or a receiver device in a specific transaction. The generated location information is recorded along with the transaction information in the body of the expanded block.

The terminal device 110 and the blockchain node 120 utilize a wireless LAN signal-based location recognition service including a Wi-Fi Positioning System (WPS) provided by Google when generating location information using a wireless LAN signal. I can. When the terminal device 110 and the blockchain node 120 use an IP address to generate location information, their accuracy is somewhat inferior to the method of using a wireless LAN signal. Accordingly, the terminal device 110 and the blockchain node 120 may generate location information using both methods of using an IP address and a method of using a wireless LAN signal. In this case, the terminal device 110 and the block chain node 120 use the location information when there is an error of more than a threshold between the location information generated using the IP address and the location information generated using the wireless LAN signal. Without doing so, the terminal device 110 and the block chain node 120 may be set to be unknown.

Hereinafter, a method of authenticating a transaction in a blockchain based on location information will be described in detail with reference to FIG. 2. 2 is a flow chart provided to explain a method of authenticating a block chain transaction according to an embodiment of the present invention.

First, the block chain system 100 configures a block chain composed of blocks including location information (S210). Specifically, the block chain system 100 constitutes a block chain with block chain nodes whose location is confirmed, and the nodes whose location is not confirmed are excluded from the block chain.

The structure of a block including location information is shown in FIG. 3. 3 is a diagram showing a structure of one block constituting a block chain according to an embodiment of the present invention.

As shown in FIG. 3, the block is composed of a block header part and a block body part, and it can be seen that various pieces of information are included. Among them, it can be seen that the location pointer 310 is included in the block header and the node location list 320 is included in the block body. In this way, the location information of the block chain nodes participating in the block chain is recorded by expanding the header part of the block and the body part of the block.

The location pointer 310 corresponds to a location pointer field (4 bytes) indicating a portion in which the node location list 320 is recorded in the block body.

In the node location list 320, information of block chain nodes constituting a block chain is recorded together with location information. The node location list 320 is updated when a new node participates in or is excluded from the blockchain.

In the transaction 330, information corresponding to one block chain transaction is recorded. In the transaction 330, transaction-related information such as transaction number information corresponding to the transaction, sending account number, receiving account number, and transaction amount is recorded, and transaction item ID (ID), sender device location information, and And location information of the recipient device is recorded. That is, in the block generated as a result of transaction authentication, the transaction item ID for the transaction is recorded in the transaction field corresponding to the transaction. In addition, in the block generated as a result of the transaction authentication, the location information of the sender device and the location information of the receiver device for the transaction are recorded.

The blocks of the location-based blockchain system 100 are configured as described above.

Hereinafter, a description will be continued based on FIG. 2 again.

When a transaction occurs (S220-Y), the blockchain system 100 authenticates the transaction using the location information (S225).

Specifically, in order to authenticate a transaction, the blockchain system 100 expresses the block chain nodes whose location is first identified as a minimum spanning tree, so that the distance between each node constituting the corresponding minimum cost spanning tree is Calculate the sum of'total distance sum'.

The least cost spanning tree is a network that connects all nodes to a network given a weight at the edge and has the lowest weighted total. Since there is no cycle, it becomes a tree. In this embodiment, the distance between each node is treated as a weight of the network. As an algorithm for obtaining the minimum cost spanning tree, Kruskal's algorithm is widely known, and the same algorithm can be used in this embodiment to generate the minimum cost spanning tree.

The blockchain system 100 determines whether the distribution of blockchain nodes is well spread using the'sum of total distances'. If there are two different blockchain systems in which the same number of blockchain nodes participate in the network consensus for transaction authentication, the blockchain system with a larger'total distance sum' is considered to be physically better distributed. The more blockchain nodes are distributed over a wider area, the more reliable the blockchain system is. If a specific group is in control of the blockchain nodes of the blockchain system, it is highly likely that the blockchain nodes are located close to each other, so it is assumed that the larger the'total distance sum' is, the more reliable blockchain system. It can be.

After that, the blockchain system 100 expresses the blockchain nodes that have received the transaction information as a minimum spanning tree, and is ``authentication'' which is the sum of the distances between each blockchain node constituting the corresponding minimum cost spanning tree. Calculate'Sum of Distance', and use'Sum of Authentication Distance','Sum of Total Distance','Number of Blockchain Nodes to which the Transaction Information is Delivered', and'Number of Blockchain Nodes with Confirmed Location'. You will be authenticated. Here, the blockchain nodes that have received the transaction information are blockchain nodes that have received information on the transaction generated in the blockchain system 100 through the blockchain network 130, and are blockchain nodes participating in authentication. Corresponds to nodes.

Specifically, if the ratio of the'sum of authentication distance' to the'sum of total distances' ('sum of authentication distances' /'sum of total distances') is greater than or equal to the threshold, the blockchain system 100 determines that the transaction has been authenticated. do. Here, the threshold value represents a distance value corresponding to a regional range such that the authentication of the corresponding transaction has been completed, and the value may be set differently according to the degree of authentication.

In addition, even if the ratio of the'sum of authentication distances' to the'sum of total distances' ('sum of authentication distances' /'sum of total distances') is less than the threshold, the'received transaction information is received. If the number of blockchain nodes' exceeds half of the'number of confirmed blockchain nodes', it is judged that the transaction has been authenticated. This indicates that even if the distance requirement is not satisfied, if the number of blockchain nodes participating in authentication exceeds half of the total number of blockchain nodes, authentication is considered complete.

Through this process, the blockchain system 100 performs authentication for transactions.

Meanwhile, in addition to the above-described authentication method, the blockchain system 100 may also use location information in a network consensus authentication method of a Delegated Proof of Stake (DPoS) method. The delegated proof-of-stake method is a method in which a block chain node representing a group is elected to increase the performance of the block chain, and only the elected block chain nodes participate in the network consensus. The location information can also be usefully used in the method of verifying the delegated stake. Specifically, in determining the representative block chain node participating in the delegated proof-of-stake method, the block chain system 100 may determine block chain nodes that are separated by a certain distance or more as representative block chain nodes using location information. Through this, the blockchain system 100 can determine a direction in which the physical distribution of representative blockchain nodes can be evenly achieved. Even in this case, the blockchain system 100 may generate a minimum cost spanning tree and determine representative blockchain nodes participating in authentication using the generated minimum cost spanning tree.

Thereafter, the block chain system 100 connects the block generated as a result of transaction authentication to the block chain (S230). Then, the block chain system 100 transmits the block generated as a result of transaction authentication to other block chain nodes through the block chain network 130 (S240). That is, for all nodes, the block chain system 100 additionally connects the block generated as a result of transaction authentication to the block chain of each node.

In addition, in the block generated as a result of transaction authentication, the transaction item ID for the transaction is recorded. In the block generated as a result of the transaction authentication, the location information of the sender device and the location information of the receiver device for the corresponding transaction are recorded.

Through this process, the blockchain system 100 can authenticate a blockchain transaction using location information.

Location information is not only useful for improving the network consensus performance and safety of the blockchain. By including the location of the transaction in the content stored in the block after authentication is completed, it is possible to track based on the location when tracking the transaction history later.

Blockchains that guarantee anonymity are sometimes problematic due to excessive anonymity guarantees. This is because the P2P transaction method using the blockchain may be abused for transactions such as tax evasion and drug transactions. However, if the location of the transaction is recorded in the contents of the stored transaction and can be traced later, the problem caused by the excessive anonymity of the blockchain can be prevented or alleviated.

To this end, the block chain system 100 first recognizes the location information of the terminal device 110 requesting the transaction and the corresponding transaction request for all transactions, and stores the location information of the block chain node 120 requesting transaction authentication in a block. It is stored and used for tracking location-based transaction history later.

Financial transactions, such as remittance for generating transactions, are generally requested through a terminal device 110 such as a smartphone or PC. Therefore, the blockchain system 100 first records the location information of the terminal device 110. The location information of the terminal device 110 may be determined by collecting GPS or Wi-Fi wireless signals in the case of a smartphone. In the case of a PC connected by wire, GPS signals cannot be used, but in the case of a PC with a receiver that receives the connected PC's IP address and Wi-Fi wireless LAN signal, location information can be generated using wireless signals. In the case of location information generated using an IP address or Wi-Fi wireless LAN signal, the location accuracy may vary depending on the performance of the location recognition system used.

When a transaction occurs through the terminal device 110 in the blockchain system 100, the transaction is transmitted to the blockchain node 120 constituting the blockchain, and the blockchain node 120 provides the transaction information for transaction authentication. Is transmitted through the blockchain network 130. At this time, the blockchain network 130 creates a new block and delivers the transaction, and transaction information is included in the body of the generated block. In each of the transaction information, the location information of the sender device and the location information of the receiver device are recorded in the block generated as a result of the transaction authentication. For location information, WS 84, longitude and latitude coordinate system may be used, or a coordinate system provided by a location recognition system may be used.

In addition, in order to track the transaction history based on the location, the blockchain system 100 newly issues the transaction item ID (ID) at the time they are first created for the transactional item and records it in the body of the block. do.

The method for the blockchain system 100 to track transaction history based on location is as follows.

When the block chain system 100 acquires a transaction item ID (ID) for tracking a transaction based on a location, the block chain network 130 searches for a block corresponding to the transaction item ID, and deals related to the transaction recorded in the block. By arranging the points where the transaction took place on the physical spatial map with reference to the location information and interconnecting the corresponding points according to the trend of time, the transaction history can be visualized on the physical spatial map and the transaction history can be tracked based on the location. There will be. The transaction location may be expressed separately or together with the location information of the terminal device requesting the transaction and the location information of the blockchain node connected to the terminal device requesting the transaction.

In the same way as above, the blockchain system 100 can track transaction history based on location. There are many ways to implement such a transaction history tracking system. The transaction history tracking system can be implemented by making it a separate application system, or it can be implemented by adding a transaction history tracking function to the blockchain. Alternatively, the function can be appropriately distributed across the blockchain and transaction history tracking system.

4 is a diagram illustrating a screen displaying details of one transaction according to an embodiment of the present invention. The blockchain system 100 may create a snapshot of a specific transaction and display it on the screen for tracking location-based transaction history.

As shown in FIG. 4, it can be seen that the transaction item ID 310, the sender location information 320, and the receiver location information 330 are also displayed on the transaction information screen.

In this way, since the block chain system 100 enables location-based tracking of transaction history, even if it is anonymous, information on the transaction point is stored in a block to prevent malicious and illegal use as it cannot be forged or altered. After an incident occurs, it can be tracked and detected. Therefore, the location-based blockchain system 100 can build a much more powerful transaction history tracking system compared to the existing transaction history tracking system.

Meanwhile, it goes without saying that the technical idea of the present invention can also be applied to a computer-readable recording medium containing a computer program for performing functions and methods of the apparatus according to the present embodiment. In addition, the technical idea according to various embodiments of the present invention may be implemented in the form of a computer-readable programming language code recorded on a computer-readable recording medium. The computer-readable recording medium can be any data storage device that can be read by a computer and can store data. For example, a computer-readable recording medium can be a ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical disk, hard disk drive, flash memory, solid state disk (SSD), and the like. Also, a computer-readable code or program stored in a computer-readable recording medium may be transmitted through a network connected between computers.

In addition, although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. In addition, various modifications are possible by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

100: Blockchain system
110: terminal device
120: Blockchain node
130: Blockchain network

Claims (12)

In the blockchain transaction authentication method using the blockchain system,
Constructing a block chain composed of blocks including location information;
Authenticating the transaction using location information when a transaction occurs; And
Including; connecting the block generated as a result of transaction authentication to the blockchain,
The step of constructing a blockchain is to construct a blockchain with nodes whose locations have been verified,
The method further comprising: expressing the nodes whose positions have been identified as a minimum spanning tree to calculate a'total distance sum' which is a sum of distances between nodes constituting the corresponding minimum cost spanning tree; Blockchain transaction authentication method.
The method according to claim 1,
Blocks containing location information,
Blockchain transaction authentication method, characterized in that a location pointer is included in the block header and a node location list is included in the block body.
delete delete The method according to claim 1,
The steps to verify the transaction are:
The nodes receiving the transaction information are expressed as a minimum spanning tree to calculate the'sum of authentication distances', which is the sum of the distances between the nodes constituting the corresponding minimum cost spanning tree, and the'sum of authentication distances' and ' Blockchain transaction authentication method, characterized in that the transaction is authenticated using the sum of the total distance', the number of nodes that have received the transaction information, and the number of nodes whose location has been verified.
The method of claim 5,
The steps to verify the transaction are:
Blockchain transaction authentication method, characterized in that when the ratio of the'sum of authentication distance' to the'sum of total distances'('sum of authentication distances'/'sum of total distances') is more than a threshold value, it is determined that the transaction has been authenticated. .
The method of claim 6,
The steps to verify the transaction are:
Even if the ratio of the'sum of authentication distance' to the'sum of total distances'('sum of authentication distances'/'sum of total distances') is less than the threshold, the'number of nodes that received the transaction information'is'the location is confirmed. Blockchain transaction authentication method, characterized in that it is determined that the authentication of the corresponding transaction has been completed when it exceeds half of'the number of nodes.
The method of claim 7,
The steps to connect to the blockchain are:
Blockchain transaction authentication method, characterized in that for all nodes, blocks generated as a result of transaction authentication are additionally connected to the blockchain of each node.
The method according to claim 1,
Blocks created as a result of transaction verification,
Blockchain transaction authentication method, characterized in that the transaction item ID for the transaction is recorded.
The method according to claim 1,
Blocks created as a result of transaction verification,
Blockchain transaction authentication method, characterized in that the location information of the sender device and the location information of the receiver device for the transaction are recorded.
In the blockchain transaction authentication method using the blockchain system,
Constructing a block chain composed of blocks including location information;
Authenticating the transaction using location information when a transaction occurs; And
Including; connecting the block generated as a result of transaction authentication to the blockchain,
The step of constructing a blockchain is to construct a blockchain with nodes whose locations have been verified,
The method further comprising: expressing the nodes whose positions have been identified as a minimum spanning tree to calculate a'total distance sum' which is a sum of distances between nodes constituting the corresponding minimum cost spanning tree; A computer-readable recording medium containing a computer program that performs the blockchain transaction authentication method.
Devices participating in transactions using blockchain; And
Includes; a block chain node that configures a block chain composed of blocks containing location information, authenticates the transaction using the location information when a transaction occurs by the device, and connects the block generated as a result of transaction authentication to the block chain; and,
Blockchain nodes,
The'total distance sum', which is the sum of the distances between each node constituting the corresponding minimum cost spanning tree by composing a block chain with nodes whose location has been verified, and expressing the nodes with the location verified as a minimum spanning tree Blockchain system, characterized in that to calculate.

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