WO2023239080A1 - Virtual asset transfer method for preventing incorrect deposit - Google Patents

Abstract

The present disclosure discloses a virtual asset transfer method for preventing an incorrect deposit. The virtual asset transfer method for preventing an incorrect deposit, according to the present disclosure, may comprise the steps of: receiving, from a recipient terminal via a short-range wireless communication method, a transaction password and a recipient wallet address coded by using the transaction password; restoring the coded recipient wallet address by using the transaction password; and generating a transfer transaction using the recipient wallet address as a recipient by using the restored recipient wallet address.

Description

How to transfer virtual assets to prevent incorrect deposits

This disclosure relates to a virtual asset transfer method to prevent erroneous deposits. More specifically, it relates to a method of preventing unauthorized receipt of virtual assets by converting the recipient's wallet address when performing a virtual asset transaction.

Currently, in order to transfer virtual assets, you need to know the recipient's wallet address based on the public key. These wallet addresses generally consist of a mixed array of random letters and numbers in the form of '0xAb5801a7D389523b8E11364e05C5VB233259B', and anyone who knows the wallet address can send random virtual assets to that address.

Referring to Figure 1, the details of each virtual asset transfer are disclosed in a space accessible to anyone. In addition, the virtual asset transaction hash value, sender's wallet address (10), recipient's wallet address (20), and transfer amount (30) are transparently disclosed.

Due to the above characteristics, now that virtual asset trading is active, cases of abusing it for various purposes often occur. For example, a person issuing a new virtual asset transfers money to the wallet address of the original issuer of the Ethereum virtual asset and announces incorrect information that ‘the creator of Ethereum is interested in a new virtual asset’ without the consent of the recipient. There are examples, etc.

In addition, due to the problem that the wallet address is composed of a string that cannot be easily identified, such as a mixed array of random numbers and letters, incorrect remittances frequently occur due to incorrect wallet addresses when transferring virtual assets. In addition, when an incorrect remittance occurs like this, recovery is impossible due to the nature of blockchain transactions, causing inconvenience to users.

Therefore, there is a need for a virtual asset transfer or remittance method that accurately transmits the wallet address using wireless communication to prevent erroneous transfers and reflects the recipient's intention, but existing virtual asset wallet services do not provide this function.

The technical task to be achieved through several embodiments of the present disclosure is to provide a virtual asset transfer method that prevents errors in the virtual asset transfer process by receiving the recipient's wallet address through short-range wireless communication. will be.

Another technical task to be achieved through some embodiments of the present disclosure is to provide a virtual asset transfer method to prevent erroneous deposits by preventing an unspecified number of people from knowing the recipient's wallet address.

Another technical task to be achieved through some embodiments of the present disclosure is to provide a virtual asset transfer method that strengthens the security of the recipient's wallet address by deleting the recipient's wallet address included in the transaction after the transaction is performed.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above technical problem, a virtual asset transfer method to prevent incorrect deposits according to an embodiment of the present disclosure is to transmit a transaction password and a recipient wallet address coded using the transaction password through a short-distance wireless network. Receiving from the recipient's terminal through short-range wireless communication, restoring the coded recipient's wallet address using the transaction password, and using the restored recipient's wallet address to It may include the step of creating a transfer transaction with the recipient's wallet address as the recipient.

The transaction password may be a one-time password generated by the recipient terminal.

The step of creating a transfer transaction with the recipient's wallet address as the recipient using the restored recipient's wallet address includes determining whether the password entered into the sender's terminal matches the transaction password, If the password entered into the sender's terminal matches the transaction password, the step of restoring the coded recipient wallet address using the transaction password may be included.

The virtual asset transfer method for preventing incorrect deposits may further include transmitting the generated transfer transaction to the recipient terminal, and transmitting the generated transfer transaction to the blockchain network by the recipient terminal. there is.

The step of transmitting the generated transfer transaction to the recipient terminal may include transmitting the generated transfer transaction to the recipient terminal through the short-range wireless communication method.

The step of transmitting the generated transfer transaction to the recipient terminal through the short-distance wireless communication method includes the computing system and the recipient before predefined requirements are satisfied after restoring the coded recipient wallet address. Only when the connection for the short-range wireless communication between terminals is completed, it may include transmitting the generated transfer transaction to the recipient terminal through the short-range wireless communication method.

The predefined requirement may be that a predefined time has elapsed since restoring the coded recipient wallet address.

A cryptocurrency transaction method using short-range wireless communication according to another embodiment of the present disclosure to solve the above technical problem involves receiving the recipient's wallet address coded using a transaction password from the recipient's terminal through short-range wireless communication. A step of receiving a transaction password from the user, a step of restoring the coded beneficiary wallet address using the previously entered transaction password, and using the restored beneficiary wallet address to retrieve the beneficiary wallet address. It may include creating a transfer transaction with the recipient as the recipient.

1 is a diagram illustrating disclosed virtual asset transaction details to explain the background technology of the present disclosure.

Figure 2 is a diagram illustrating an environment in which a virtual asset transfer method to prevent incorrect deposits can be applied.

Figure 3 is a flowchart of a virtual asset transfer method to prevent erroneous deposits, according to an embodiment of the present disclosure.

FIG. 4 is a flowchart for explaining in detail some of the operations described with reference to FIG. 3 .

FIG. 5 is a flowchart for explaining in detail some of the operations described with reference to FIG. 3.

6 is a hardware configuration diagram of a computing system that can be used as a component in some embodiments of the present disclosure.

Hereinafter, preferred embodiments of the present disclosure will be described in detail with reference to the attached drawings. The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the technical idea of the present invention is not limited to the following embodiments and may be implemented in various different forms. The following examples are merely intended to complete the technical idea of the present invention and to be used in the technical field to which the present invention pertains. It is provided to fully inform those skilled in the art of the scope of the present invention, and the technical idea of the present invention is only defined by the scope of the claims.

In describing the present disclosure, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, several embodiments of the present disclosure will be described with reference to the drawings.

Figure 2 is an environmental configuration diagram in which a virtual asset transfer method to prevent incorrect deposits according to an embodiment of the present disclosure can be applied. As shown in FIG. 2, the virtual asset transfer method to prevent incorrect deposits according to this embodiment can be implemented by interacting with the sender terminal 100, the recipient terminal 200, and the blockchain network 300. . In FIG. 2, the sender terminal 100 and the recipient terminal 200 are shown as smartphones, but of course, they can include all types of terminals including short-range wireless communication modules. For example, the sender terminal 100 and the recipient terminal 200 according to an embodiment of the present disclosure may be any one of a laptop, tablet, or phablet.

Hereinafter, each component shown in FIG. 2 will be described in more detail.

The remitter terminal 100 is the remitter's personal terminal that performs virtual asset transfer. The sender terminal 100 can specify the recipient terminal 200 to which virtual assets will be transferred according to the sender's input. Here, virtual assets are assets issued and traded using digital distributed ledger or blockchain technology and may include cryptocurrencies or digital tokens including Bitcoin and Ethereum.

Additionally, the sender terminal 100 can receive the coded recipient wallet address from the recipient terminal 200 through short-range wireless communication. The step of receiving the coded recipient wallet address will be described in detail later. Here, short-range wireless communication may be any one of Wi-Fi, Bluetooth, NFC (Near Field Communication), and Zigbee, but is not limited thereto.

Additionally, the cryptocurrency wallet having the wallet address may include different public keys and private keys for each wallet.

The sender terminal 100 can restore the coded recipient wallet address. Here, the sender's terminal can input a password to restore the coded recipient's wallet address. Additionally, a virtual asset transfer transaction can be created based on the restored wallet address. Here, the virtual asset transfer transaction may include the amount specified by the sender, the sender's wallet address, the recipient's wallet address, and the transaction hash value. Thereafter, the sender terminal 100 may transmit the generated transfer transaction to the blockchain network 300.

The remitter terminal 100 responds to the fact that the short-range wireless communication connection with the recipient terminal 200 is completed before the predefined requirements are satisfied after restoring the coded recipient wallet address, and The transaction may be transmitted to the recipient terminal 200. The step of transmitting the transaction to the recipient terminal 200 will be described in detail later with reference to FIG. 5.

The recipient terminal 200 is the recipient's personal terminal that receives virtual assets. The recipient terminal 200 may request remittance from a specific sender according to the recipient's input.

The recipient terminal 200 can code the recipient's wallet address using the transaction password. Here, coding may mean encryption that converts the recipient's wallet address into a list of meaningless characters, but may include any processing by a computing device that converts the original form of the recipient's wallet address into an unrecognizable form.

The recipient terminal 200 completes the short-distance wireless communication connection with the sender terminal 100 before the predefined requirements are satisfied after restoring the coded recipient wallet address by the sender terminal 100. In response to being done, the generated transfer transaction may be received. The received transfer transaction may be transmitted to the blockchain network by the recipient terminal 200.

The blockchain network 300 is a virtual space where blocks, which are ledger data recording transaction information of virtual asset users, are stored. Here, the block may include virtual asset transaction details that can be viewed by an unspecified number of people. The blockchain network 300 may receive the virtual asset transfer transaction from the recipient or the sender.

Hereinafter, with reference to FIGS. 3 to 5, a virtual asset transfer method for preventing incorrect deposits according to an embodiment of the present disclosure will be described in more detail. Hereinafter, the steps to be described in several flowcharts may be understood as being performed by the sender terminal 100, unless otherwise specified.

Figure 3 is a flowchart of a virtual asset transfer method to prevent erroneous deposits according to this embodiment.

In step S100, the sender or recipient may request a transaction from the other party. In order to send money to the recipient's wallet address, the sender may request the recipient to transmit the recipient's wallet address via short-range wireless communication through a letter, electronic letter, or verbal communication. In addition, of course, any communication means capable of conveying the intention of the request may be included.

In step S200, the recipient terminal may code the recipient wallet address using the transaction password. Here, the coding may be encryption performed on the wallet address, but may include any processing by a computing device that converts the original recipient's wallet address string into an unidentifiable state in order to prevent it from being disclosed to the sender. It should be noted that this may be possible.

In some embodiments related to step S200, the transaction password may be a One Time Password. The one-time password may be a string consisting of four Arabic numbers from 1 to 9 that changes every time a transaction is requested. The one-time password may be generated by the recipient terminal for the coding to strengthen the security of the recipient's wallet address. Additionally, the one-time password can be used to restore the recipient's wallet address.

If the password used to protect the recipient's wallet address is immutable, there is a risk that the sender will remember the password and perform a transfer that the recipient does not want in the future. According to this embodiment, by using a one-time password, a different password must always be entered to find out the recipient's wallet address, thereby preventing the transfer of virtual assets against the recipient's will.

In step S300, the sender's terminal can receive the coded recipient's wallet address through short-range wireless communication. The coded recipient's wallet address is only used to create a transfer transaction to transfer a virtual asset equal to the amount specified by the sender to the recipient's wallet address, and may not be visually displayed to the sender. Here, the short-range wireless communication method may be NFC, but is not limited to any of Wi-Fi, Bluetooth, NFC (Near Field Communication), or Zigbee.

In some embodiments related to step S300, the recipient may transmit the coded recipient wallet address to the sender terminal by approaching the sender terminal at a predetermined distance or more in response to the fact that the code of the recipient wallet address has been completed. there is. In addition, even though the recipient's wallet address has been coded, the recipient can cancel the transaction by not approaching the sender's terminal at a predetermined distance or longer than a predetermined condition. Of course, the transaction can be canceled through specific manipulation of the recipient's terminal.

In step S400, the sender's terminal can restore the wallet address using the transaction password. Here, the sender may request the recipient to convey the transaction password via letter, electronic communication, or verbal communication.

In some embodiments related to step S400, the recipient terminal may transmit the transaction password to the sender terminal through short-range wireless communication.

According to this embodiment, the sender terminal only receives the transaction password through short-range wireless communication through the recipient terminal, and the transaction password is not expressed in a visible state, so the sender remembers the transaction password and In the future, the recipient cannot make a remittance that he or she does not want.

Hereinafter, in some other embodiments related to step S400, a method of restoring a wallet address using a transaction password will be described with reference to FIG. 4.

Referring to FIG. 4, in step S410, the remitter terminal may evaluate whether the password entered into the remitter terminal is the same as the transaction password, which is a one-time password generated by the recipient terminal. The sender can input four Arabic numbers from 0 to 9 in response to the sender's terminal requesting to enter a transaction password.

In step S420, the sender terminal can restore the coded recipient wallet address using the transaction password. If the string of four Arabic numerals entered by the sender is the same as the transaction password, which is a one-time password generated by the recipient terminal that is the subject of this transaction, the sender terminal converts the coded recipient wallet address to the original recipient wallet address. can do.

According to this embodiment, the sender cannot know the recipient's wallet address without the transaction password, so the recipient may not be able to perform arbitrary remittance for purposes not desired.

In step S430, the sender terminal responds that the string of four Arabic numerals entered by the sender is different from the transaction password, which is a one-time password generated by the recipient terminal that is the object of this transaction, and provides the password to the sender. You may be asked to enter it again. Here, the remitter terminal may request to re-enter the password in response to the fact that the re-entered password is also different from the transaction password.

In step S431, the sender's terminal may evaluate whether the number of times the sender's password has been entered does not match the transaction password three or more times. According to this embodiment, even if the sender enters the password incorrectly for an unspecified reason, he or she can continue the transaction without going through unnecessary processes by re-entering the password.

In step S432, the sender's terminal may cancel the transaction in response to the fact that the number of times the sender's password has been entered does not match the transaction password three or more times. When the transaction cancellation is performed, a notification message that the transaction has been canceled may be output to the recipient's terminal and delivered to the recipient.

If the sender continuously randomly enters the password several times and accidentally matches the transaction password, the recipient may perform an unwanted virtual asset transfer. According to this embodiment, if the sender enters the password incorrectly three or more times, a specific message is displayed on the recipient's terminal. By notifying the recipient through the message that a random sender is performing a virtual asset transfer that the recipient does not want, the recipient may take measures to further strengthen the protection of the wallet address.

Above, a method of restoring a coded recipient wallet address using a transaction password according to an embodiment of the present disclosure has been described. Operations related to the method for restoring the coded recipient wallet address may be used independently, but the scope of the present disclosure is not limited thereto, and a plurality of operations may be used together.

Hereinafter, with reference to FIG. 5, a detailed description will be given of how the sender's terminal creates a transfer transaction in step S500 of FIG. 3.

In step S510, the sender terminal may create a transfer transaction to be transmitted to the blockchain network based on the restored recipient wallet address. The transfer transaction may include the sender's wallet address, the recipient's wallet address, the transaction hash value, and the transfer amount.

In some embodiments related to step S510, the transaction hash value may be output in a coded state to the sender's terminal. The transaction hash value may have an arbitrary string of predetermined digits depending on the type of virtual asset.

If the sender is aware of the transaction hash value, the recipient's wallet address can be found by conducting a search within the blockchain network based on the transaction hash value. According to this embodiment, by hiding the transaction hash value, the sender cannot find out the recipient's wallet address through the virtual asset transaction hash value.

In step S520, the sender terminal may evaluate whether the recipient terminal is still within a short-range wireless communication range with the sender terminal after a predefined time. The predefined time may be a time designated by the sender or recipient, and may also be an initial value set in the sender's terminal and the recipient's terminal. However, in some embodiments related to S520, if the time specified by the remitter is shorter than the time specified by the recipient, the predefined time may be set to the time specified by the remitter, but the opposite case may also be included.

In step S521, in response to the fact that the sender terminal is still within a short-distance wireless communication range of the recipient terminal for more than a predefined time, the generated transfer transaction may be transmitted to the recipient terminal. Here, in order to prevent disclosure of the sender's wallet address and the recipient's wallet address, the transfer transaction may be coded in a form that the recipient cannot recognize.

In some embodiments related to step S521, the step of the sender terminal transmitting the transfer transaction generated by the sender terminal to the recipient terminal may be performed after approval by the sender or recipient.

In some other embodiments related to step S521, the sender terminal may delete the transfer transaction existing in the sender terminal in response to the recipient terminal successfully receiving the generated transfer transaction. According to this embodiment, it is also possible to prevent an error in which a virtual asset transfer is performed twice due to a transfer transaction remaining in the sender's terminal after the transaction between the sender and the recipient.

In step S522, in response to the fact that the recipient terminal is not within a short-range wireless communication range with the sender terminal after a predefined time, the sender terminal may transmit the generated transfer transaction to the blockchain network. By transmitting the generated transfer transaction to the blockchain network, the sender terminal can notify the sender that the transaction has been transmitted to the blockchain network by outputting a message.

In some embodiments related to step S522, the sender may create a raw transaction by final signing the transfer transaction with a public key unique to the virtual asset wallet owned by the sender. The generated raw transaction can be transmitted by the sender to the terminal of another person who owns a virtual asset wallet. Additionally, a specific terminal that has received the raw transaction can transmit the transaction to the blockchain network.

According to this embodiment, the sender cannot visually confirm the recipient's wallet address during the virtual asset transfer process. Therefore, the recipient's wallet address is not disclosed in a space accessible to an unspecified number of people, so the transfer of virtual assets that the recipient does not want may not be performed by an unspecified number of people, including the sender.

In some other embodiments related to step S522, the blockchain network may charge the sender a virtual asset transfer fee in response to the generated transfer transaction being sent to the blockchain network by the sender terminal.

In step S530, the recipient terminal that has received the transfer transaction may transmit the transfer transaction to the blockchain network. However, since the recipient should also not know the sender's wallet address and transaction hash value, it will be understood that the transfer transaction cannot be viewed by the recipient and is coded. By transmitting the generated transfer transaction to the blockchain network, the recipient terminal can notify the recipient that the transaction has been transmitted to the blockchain network by outputting a message.

Here, the transfer transaction may be finally signed with the unique public key of the virtual asset wallet owned by the sender.

According to this embodiment, the sender's wallet address is only transmitted to the recipient's terminal in the form of a transfer transaction by short-distance wireless communication, and since the recipient cannot visually confirm the sender's wallet address, the sender's wallet address is also secure. You can achieve this even stronger effect.

In step S540, the sender terminal or recipient terminal that transmitted the transfer transaction to the blockchain network may evaluate whether the transmission was successfully processed. In some embodiments related to step S540, the sender terminal or the recipient terminal may evaluate the transmission process through a specific signal received by the blockchain network. In addition, the remitter terminal or the recipient terminal may be evaluated by referring to the blockchain network, but in the case where the evaluation is performed manually by the remitter or recipient, the remitter terminal or the recipient terminal automatically performs the evaluation by a pre-designated operation. It should be noted that if it can be performed, it is not limited to any one.

In some embodiments related to step S540, when the recipient terminal transmits the transfer transaction to the blockchain network, the recipient terminal responds that the transfer transaction has been successfully transmitted to the blockchain network, A signal or notification that the transaction has been successfully transmitted may be delivered to the sender terminal.

In step S550, the sender terminal may permanently delete the restored recipient wallet address stored to create the transfer transaction in response to the fact that the transfer transaction has been successfully transmitted by the sender terminal or the recipient terminal.

In order to perform the transaction, a malicious sender may search for the restored recipient's wallet address stored in the terminal, store it separately, and then perform a virtual asset transfer that the recipient does not want. According to this embodiment, even if the recipient does not take separate security measures after the transaction, the original recipient's wallet address is automatically deleted, which can have the effect of strengthening the security of the recipient's wallet address.

So far, a virtual asset transfer method to prevent erroneous deposits according to an embodiment of the present disclosure has been described. The operations related to the virtual asset transfer method for preventing incorrect deposits may be used independently, but the scope of the present disclosure is not limited thereto, and a plurality of operations may be used together.

Figure 6 is a hardware configuration diagram of a computing system that can be used as a component to perform a virtual asset transfer method to prevent erroneous deposits according to some embodiments of the present disclosure. The computing system 1000 shown in FIG. 6 may refer to, for example, the remitter terminal 100 or the recipient terminal 200 described with reference to FIG. 1 . The computing system 1000 includes one or more processors 1100, a system bus 1600, a communication interface 1200, a memory 1400 that loads a computer program 1500 executed by the processor 1100, and It may include a storage 1300 that stores a computer program 1500.

The processor 1100 controls the overall operation of each component of the simulation device 200. The processor 1100 may perform operations on at least one application or program to execute methods/operations according to various embodiments of the present disclosure. The memory 1400 stores various data, commands and/or information. The memory 1400 may load one or more computer programs 1500 from the storage 1300 to execute methods/operations according to various embodiments of the present disclosure. The bus 1600 provides communication between components of the simulation device 200. The communication interface 1200 supports Internet communication of the simulation device 200. Storage 1300 may non-temporarily store one or more computer programs 1500. The computer program 1500 may include one or more instructions implementing methods/operations according to various embodiments of the present disclosure. When the computer program 1500 is loaded into the memory 1400, the processor 1100 can perform methods/operations according to various embodiments of the present disclosure by executing the one or more instructions.

In some embodiments, the computing system described with reference to FIG. 6 may be configured using one or more physical servers included in a server farm based on cloud technology, such as a virtual machine. In this case, at least some of the processor 1100, memory 1400, and storage 1300 among the components shown in FIG. 6 may be virtual hardware, and the communication interface 1200 may also be a virtual switch. It may be composed of virtualized networking elements such as switches.

The computer program 1500 operates to receive a transaction password and a recipient wallet address coded using the transaction password from the recipient terminal through short-range wireless communication, and the recipient wallet address coded using the transaction password. Instructions for performing an operation to restore an address, an operation to create a transfer transaction with the recipient's wallet address as the recipient using the restored recipient's wallet address, and an operation to receive a transaction password from the user. may include.

So far, various embodiments of the present disclosure and effects according to the embodiments have been mentioned with reference to FIGS. 1 to 6 . The effects according to the technical idea of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description below.

The technical ideas of the present disclosure described so far can be implemented as computer-readable code on a computer-readable medium. The computer program recorded on the computer-readable recording medium can be transmitted to another computing device through a network such as the Internet, installed on the other computing device, and thus used on the other computing device.

Although operations are shown in the drawings in a specific order, it should not be understood that the operations must be performed in the specific order shown or sequential order or that all illustrated operations must be performed to obtain the desired results. In certain situations, multitasking and parallel processing may be advantageous. Although embodiments of the present disclosure have been described above with reference to the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical idea or essential features. I can understand that there is. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the technical ideas defined by this disclosure.

Claims (15)

1. In the method of virtual asset transfer performed by the sender's computing system,

   Using the transaction password generated for the virtual asset transfer and the transaction password, the recipient's wallet address coded at the time of generation of the transaction password is received using short-range wireless communication. Receiving directly from the user's terminal;

   Restoring the coded recipient wallet address using the transaction password; and

   Using the restored recipient wallet address, creating a transfer transaction with the sender's wallet address as the sender's wallet address and the recipient's wallet address as the recipient,

   The restored recipient's wallet address and the transaction password are not visually displayed on the display of the sender's terminal,

   How to transfer virtual assets to prevent incorrect deposits.
2. According to claim 1,

   The transaction password is a one-time password generated by the recipient terminal,

   How to transfer virtual assets to prevent incorrect deposits.
3. According to claim 1,

   The step of restoring the coded recipient wallet address using the transaction password is,

   determining whether the password entered into the sender's terminal matches the transaction password; and

   When the password entered into the sender's terminal matches the transaction password, restoring the coded recipient wallet address using the transaction password,

   How to transfer virtual assets to prevent incorrect deposits.
4. According to claim 1,

   The step of creating the transfer transaction is,

   In response to receiving a response signal indicating that the transaction has been successfully transmitted to the blockchain network, permanently deleting the restored recipient wallet address.

   How to transfer virtual assets to prevent incorrect deposits.
5. According to claim 1,

   transmitting the generated transfer transaction to the recipient terminal; and

   Further comprising the step of the recipient terminal transmitting the generated transfer transaction to a blockchain network,

   How to transfer virtual assets to prevent incorrect deposits.
6. According to clause 5,

   The step of transmitting the generated transfer transaction to the recipient terminal is,

   Comprising the step of transmitting the generated transfer transaction to the recipient terminal through the short-range wireless communication method,

   How to transfer virtual assets to prevent incorrect deposits.
7. According to clause 6,

   The step of transmitting the generated transfer transaction to the recipient terminal using the short-range wireless communication method,

   After restoring the coded recipient wallet address, before the predefined requirements are satisfied, the generated transfer transaction is performed only when the connection for the short-range wireless communication between the computing system and the recipient terminal is completed. Comprising the step of transmitting to the recipient terminal using the short-range wireless communication method,

   How to transfer virtual assets to prevent incorrect deposits.
8. According to clause 7,

   The predefined requirement is that a predefined time has elapsed since restoring the coded recipient wallet address.

   How to transfer virtual assets to prevent incorrect deposits.
9. In the method of virtual asset transfer performed by the sender's computing system,

   Using the transaction password generated for the virtual asset transfer, the recipient's wallet address coded at the time of generation of the transaction password is directly received from the recipient's terminal through short-range wireless communication. steps;

   Receiving a transaction password from the user;

   Restoring the coded recipient wallet address using the entered transaction password; and

   Using the restored recipient wallet address, creating a transfer transaction with the sender's wallet address as the sender's wallet address and the recipient's wallet address as the recipient,

   The restored recipient's wallet address and the transaction password are not visually displayed on the display of the sender's terminal,

   Cryptocurrency trading method by short-range wireless communication.
10. According to clause 9,

    The transaction password is a one-time password generated by the recipient terminal,

    Rationale Cryptocurrency trading method by wireless communication.
11. According to clause 9,

    The step of creating a transfer transaction with the recipient's wallet address as the recipient using the restored recipient's wallet address,

    determining whether the password entered into the sender's terminal matches the transaction password; and

    When the password entered into the sender's terminal matches the transaction password, restoring the coded recipient wallet address using the transaction password,

    Cryptocurrency trading method by short-range wireless communication.
12. According to clause 9,

    transmitting the generated transfer transaction to the recipient terminal; and

    Further comprising the step of the recipient terminal transmitting the generated transfer transaction to a blockchain network,

    Cryptocurrency trading method by short-range wireless communication.
13. According to claim 12,

    The step of transmitting the generated transfer transaction to the recipient terminal is,

    Comprising the step of transmitting the generated transfer transaction to the recipient terminal through the short-range wireless communication method,

    Cryptocurrency trading method by short-range wireless communication.
14. According to claim 13,

    The step of transmitting the generated transfer transaction to the recipient terminal using the short-range wireless communication method,

    After restoring the coded recipient wallet address, before the predefined requirements are satisfied, the generated transfer transaction is performed only when the connection for the short-range wireless communication between the computing system and the recipient terminal is completed. Comprising the step of transmitting to the recipient terminal using the short-range wireless communication method,

    Cryptocurrency trading method by short-range wireless communication.
15. According to claim 14,

    The predefined requirement is that a predefined time has elapsed since restoring the coded recipient wallet address.

    Cryptocurrency trading method by short-range wireless communication.

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