KR102299743B1 - System, Apparatus and Method for Blockchain-based User Customized Infectious Disease Notification - Google Patents

Abstract

The present invention collects personal information by using a blockchain network to prevent spread of infectious diseases and provides a customized disaster notification message to contact people who have come in contact with an infected person, thereby effectively protecting the personal information of the infected person.

Description

Blockchain-based User Customized Infectious Disease Notification System, Apparatus and Method for Blockchain-based User Customized Infectious Disease Notification}

The present invention relates to a blockchain-based user-customized infectious disease notification system, apparatus and method.

In recent years, the need for personal information of infected people, such as movement routes and time zones of infected people, is increasing due to the spread of COVID-19 worldwide.

When figuring out the movement of an infected person, the state agency first acquires information on the place and time visited according to the memory of the infected person. can't

Therefore, there is a difficulty in providing a customized foundation notification message to high-risk contacts and low-risk contacts based on the movement of the infected person.

Accordingly, a general method of including location information of an infected person of a contagious virus in a warning message and sharing it with all users is used.

However, this general method spreads to an unspecified number of people, and has limitations in unnecessary resource consumption and specific information delivery.

In addition, there is a serious problem that the personal information of the infected person may be exposed when all the movements of the infected person are disclosed to an unspecified number of people. Specifically, when a centralized general system is used by a national institution, there is a weakness in the security of the movement of the confirmed patient. In addition, it is difficult to guarantee the anonymity of each individual and because the participation rate in collecting user's time location information without a fair price for handling personal information data is insufficient, it is difficult to handle the accurate time location information of the infected person.

Therefore, in order to prevent the spread of infectious diseases, it is necessary to safely protect the personal information of the infected and to prevent the spread of the infectious disease by sending a warning message only to the contact who overlaps the infected person.

Republic of Korea Patent Publication No. 10-2020-0014530

The present invention for solving the above problems can provide a customized disaster notification message to contacts who have come in contact with an infected person by collecting personal information by utilizing a block chain network for preventing the spread of infectious diseases.

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

In the blockchain-based user-customized infectious disease notification method performed by a computing device according to the present invention for solving the above-mentioned problems, the steps of providing an application for the block-chain-based user-customized disaster notification to be installed for each of a plurality of terminals; Obtaining time location information for each of the plurality of terminals through the application installed in the plurality of terminals, encrypting the time location information, and storing the encrypted time location information in a block in the blockchain network , when the infectious disease management server informs the user of the first terminal among the plurality of terminals as an infected person, the encrypted first time location information of the first terminal stored in the corresponding block of the first terminal among the blocks in the block chain network Based on the step of identifying the movement line of the first terminal, based on the identified movement line, at least one second terminal that overlaps the movement line in the same location and time zone as the first terminal among the plurality of terminals High-risk terminal based on the encrypted second time location information of the second terminal stored in the corresponding block of the second terminal among the blocks in the block chain network, the moving line overlaps at the same location and time zone as the second terminal The method may include determining at least one third terminal as a low-risk terminal, and transmitting a message indicating contact with an infected person to the second terminal and the third terminal, respectively.

In addition, the message transmitted to the second terminal may include information notifying that the user of the second terminal is a close contact with the infected person, information notifying a test request for the infectious disease, and information notifying a test location for the infectious disease. .

In addition, the message transmitted to the third terminal may include information indicating that the user of the second terminal is in close contact with the infected person and information requesting to check whether the user of the second terminal is infected with the infectious disease. can

In addition, the infectious disease management server may pay cryptocurrency according to the amount of data of the time location information for each of the plurality of terminals.

In addition, in the storing step, one node that broadcasts the time location information for each terminal among the nodes in the block chain network and receives the first node is selected as the preemption node, and the first selection notification signal is transmitted from the preemption node. One node, which is broadcast and received first, may be selected as a helper node.

In addition, the storage step includes transmitting a first selection notification signal from the preemption node in the block chain network to at least one adjacent node, and sending a second selection notification signal from the helper node to the at least one of the preemption nodes excluding the preemption node At least one neighboring node is selected as an evaluation node in the order of broadcasting and receiving to neighboring nodes, and the evaluation node transmits confirmation signals corresponding to the first selection notification signal and the second selection notification signal to the preemption node, the It can be transmitted to the helper node and the at least one adjacent node.

Also, in the storing, a node excluding the evaluation node among the at least one adjacent node may be determined as a faulty node.

In addition, the evaluation node may generate a suitability evaluation signal for the time location information and transmit it to the preemption node, the helper node, and at least one adjacent node.

In addition, the evaluation node, after transmitting the suitability evaluation signal, may generate an approval signal or a rejection signal for the time location information and transmit it to the preemption node and the helper node.

In addition, the assistance node, when receiving the approval signal from the evaluation node, may generate a review notification signal based on the approval signal and transmit it to the preemption node.

In addition, the storing may include storing the time location information in the block in the block chain network based on the review notification signal in the preemption node that has received the review notification signal.

In addition, in the encryption step, user identification information, user time information, and user location information included in the time location information for each of the plurality of terminals may be encrypted based on an encryption algorithm.

In addition, in the block chain-based user-customized disaster infectious disease notification system according to the present invention for solving the above-mentioned problems, a plurality of terminals in which applications for a block-chain-based user-customized disaster notification are installed, and the applications installed in the plurality of terminals According to the data amount of time location information for each terminal and a computing device that acquires time location information for each of the plurality of terminals through and generates a message for a user-customized disaster notification based on a block chain based on the time location information It may include an infectious disease management server that pays cryptocurrency.

Here, the computing device provides the application for the block-chain-based user-customized disaster notification to be installed for each of the plurality of terminals, and obtains time location information for each of the plurality of terminals through the application installed on the plurality of terminals and encrypting the time location information, storing the encrypted time location information in a block in the block chain network, and when the infectious disease management server informs the user of the first terminal among the plurality of terminals as an infected person, Based on the encrypted first time location information of the first terminal stored in the corresponding block of the first terminal among the blocks in the block chain network, the movement line of the first terminal is identified, and based on the identified movement line, Among the plurality of terminals, at least one second terminal whose copper lines overlap in the same location and time zone as the first terminal is determined as a high-risk terminal, and the second terminal stored in the corresponding block of the second terminal among the blocks in the block chain network. Based on the encrypted second time location information of the terminal, it is determined that at least one third terminal overlapping in the same location and time zone as the second terminal is a low-risk terminal, and the second terminal and the third terminal A message indicating contact with an infected person can be transmitted respectively.

In addition, the message transmitted to the second terminal may include information in which the user of the second terminal informs the infected person and a close contact, information informing a test request for the infectious disease, and information informing a test location for the infectious disease. .

In addition, the message transmitted to the third terminal may include information in which the user of the second terminal informs the infected person and a close contact and information requesting to check whether the user of the second terminal is infected with the infectious disease. can

In addition, the computing device broadcasts the time location information for each terminal among the nodes in the block chain network and selects one node that is first received as a preemption node, and sends a first selection notification signal from the preemption node One node, which is broadcast and received first, may be selected as a helper node.

In addition, the computing device transmits a first selection notification signal from the preemption node in the block chain network to at least one adjacent node, and transmits a second selection notification signal from the helper node to the at least one of the preemption nodes except for the preemption node At least one neighboring node is selected as an evaluation node in the order of broadcasting and receiving to neighboring nodes, and the evaluation node transmits confirmation signals corresponding to the first selection notification signal and the second selection notification signal to the preemption node, the It can be transmitted to the helper node and the at least one adjacent node.

Also, the computing device may determine a node other than the evaluation node among the at least one adjacent node as a failed node.

In addition, the evaluation node may generate a suitability evaluation signal for the time location information and transmit it to the preemption node, the helper node, and at least one adjacent node.

In addition, the evaluation node, after transmitting the suitability evaluation signal, may generate an approval signal or a rejection signal for the time location information and transmit it to the preemption node and the helper node.

In addition, the assistance node, when receiving the approval signal from the evaluation node, may generate a review notification signal based on the approval signal and transmit it to the preemption node.

In addition, the computing device may store the time location information in the block in the block chain network based on the review notification signal in the preemption node that has received the review notification signal.

Also, the computing device may encrypt user identification information, user time information, and user location information included in the time location information for each of the plurality of terminals based on an encryption algorithm.

In addition to this, other methods for implementing the present invention, other apparatuses, other systems, and computer-readable recording media for recording a computer program for executing the method may be further provided.

According to the present invention as described above, it is possible to efficiently protect the personal information of the infected person by collecting personal information by using the block chain network for preventing the spread of infectious diseases and providing a customized disaster notification message to the contacts who have come in contact with the infected person. there is

Specifically, according to the present invention, it is possible to reduce unnecessary exposure of personal information of an infected person by providing a customized disaster notification message only to contacts who have directly or indirectly contacted the infected person.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a diagram for explaining a system for providing a user-customized infectious disease notification service based on a block chain according to the present invention.
2 is a block diagram schematically illustrating a computing device for providing a blockchain-based user-customized infectious disease notification service according to the present invention.
3 is a block diagram schematically showing a terminal receiving a block-chain-based user-customized infectious disease notification service according to the present invention.
4 is a diagram showing the contents of the library of the disaster prevention block chain network of the block chain-based user-customized disaster infectious disease notification system according to the present invention, the Solidity library running and the main code contents.
5 is an exemplary diagram for explaining the selection of a preemption node among a plurality of nodes in the block chain network when time location information is stored in the block chain network according to the present invention.
6 is an exemplary diagram for explaining the selection of a helper node among a plurality of nodes in the block chain network when time location information is stored in the block chain network according to the present invention.
7 is an exemplary diagram for explaining selection of an evaluation node among a plurality of nodes in a block chain network when time location information is stored in a block chain network according to the present invention.
8 is an exemplary diagram for explaining a process of attesting to time location information when storing time location information in a block chain network according to the present invention.
9 is a screen on which an application providing a user-customized infectious disease notification service based on a block chain according to the present invention is displayed.
10 is a flowchart illustrating a block chain-based user-customized infectious disease notification process according to the present invention.
11 is a flowchart illustrating a process of verifying time location information when storing time location information in a block chain network 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 may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and those of ordinary skill in the art to which the present invention pertains. It is provided to fully understand the scope of the present invention to those skilled in the art, 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. As used herein, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, “comprises” and/or “comprising” does not exclude the presence or addition of one or more other components in addition to the stated components. Like reference numerals refer to like elements throughout, and "and/or" includes each and every combination of one or more of the recited elements. Although "first", "second", etc. are used to describe various elements, these elements are not limited by these terms, of course. These terms are only used to distinguish one component from another. Accordingly, it goes without saying that the first component mentioned below may be the second component within the spirit of the present invention.

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

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Before the description, the meaning of the terms used herein will be briefly described. However, it should be noted that the description of terms is for the purpose of helping the understanding of the present specification, and is not used in the meaning of limiting the technical idea of the present invention unless explicitly described as limiting the present invention.

1 is a diagram for explaining a system 1 for providing a user-customized infectious disease notification service based on a block chain according to the present invention.

2 is a block diagram schematically illustrating a computing device 10 for providing a blockchain-based user-customized infectious disease notification service according to the present invention.

3 is a block diagram schematically showing a terminal 20 that is provided with a blockchain-based user-customized infectious disease notification service according to the present invention.

4 is a diagram showing the contents of the library of the disaster prevention block chain network of the block chain-based user-customized disaster infectious disease notification system according to the present invention, the Solidity library running and the main code contents.

5 is an exemplary diagram for explaining the selection of a preemption node among a plurality of nodes in the block chain network when time location information is stored in the block chain network according to the present invention.

6 is an exemplary diagram for explaining the selection of a helper node among a plurality of nodes in the block chain network when time location information is stored in the block chain network according to the present invention.

7 is an exemplary diagram for explaining selection of an evaluation node among a plurality of nodes in a block chain network when time location information is stored in a block chain network according to the present invention.

8 is an exemplary diagram for explaining a process of attesting to time location information when storing time location information in a block chain network according to the present invention.

9 is a screen on which an application providing a user-customized infectious disease notification service based on a block chain according to the present invention is displayed.

Hereinafter, with reference to FIGS. 1 to 9 , a system 1 for providing a user-customized infectious disease notification service based on a block chain according to the present invention will be described.

The system (1) collects personal information by using a block chain network to prevent the spread of infectious diseases and provides a customized disaster notification message to contacts who have come in contact with the infected person, thereby effectively protecting the personal information of the infected person. have.

Specifically, the system 1 can have the effect of reducing unnecessary exposure of the infected person's personal information by providing a customized disaster notification message only to contacts who have directly or indirectly contacted the infected person.

The system 1 includes a computing device 10 that provides a blockchain-based user-customized infectious disease notification service, a plurality of terminals 20 running applications that provide a blockchain-based user-customized infectious disease notification service, and the government to manage infectious diseases. It may be configured to include the established infectious disease management server 30 , the corporate server 40 , the cryptocurrency transaction server 50 , the block chain network 60 , and a communication network (not shown). Here, the system 1 may include fewer or more components than the components shown in FIG. 1 .

The computing device 10 provides the application for the block chain-based user-customized disaster notification to be installed for each of the plurality of terminals 20, and time location information for each of the plurality of terminals through the application installed on the plurality of terminals 20 can be obtained. Here, the computing device 10 may encrypt the time location information and store the encrypted time location information in a block in the block chain network 60 .

At this time, when the infectious disease management server 30 informs the user of the first terminal 201 among the plurality of terminals 20 as an infected person, the computing device 10 detects the second block in the block chain network 60 . Based on the encrypted first time location information of the first terminal 201 stored in the corresponding block of the first terminal 201, the movement of the first terminal 201 may be determined.

Here, the computing device 10 selects at least one second terminal 202 that overlaps the movement line at the same location and time zone as the first terminal 201 among the plurality of terminals 20 based on the identified movement line. It can be determined as a high-risk terminal.

In addition, the computing device 10 is based on the encrypted second time location information of the second terminal 202 stored in the corresponding block of the second terminal 202 among the blocks in the block chain network 60, At least one third terminal 203 that overlaps with the second terminal 202 in the same location and time zone may be determined as a low-risk terminal.

Accordingly, the computing device 10 may transmit a message indicating contact with an infected person to the second terminal 202 and the third terminal 203 , respectively.

The computing device 10 may include a first communication unit 110 , a first memory 120 , and a first processor 130 . Here, the computing device 10 may include fewer or more components than the components illustrated in FIG. 2 .

The first communication unit 110 is connected between the computing device 10 and the wireless communication system, between the computing device 10 and the plurality of terminals 20 , between the computing device 10 and the infectious disease management server 30 , and the computing device 10 . ) and the enterprise server 40 , between the computing device 10 and the cryptocurrency transaction server 50 , or between the computing device 10 and the blockchain network 60 . can

In addition, the first communication unit 110 may include one or more modules for connecting the computing device 10 to one or more networks.

The first memory 120 may store data supporting various functions of the computing device 10 . The first memory 120 may store a plurality of application programs (or applications) driven in the computing device 10 , data for operation of the computing device 10 , and instructions. At least some of these application programs may exist for basic functions of the computing device 10 . Meanwhile, the application program is stored in the first memory 120 , installed on the computing device 10 , and driven to perform an operation (or function) of the computing device 10 by the first processor 130 . can be

In addition to the operation related to the application program, the first processor 130 may generally control the overall operation of the computing device 10 . The first processor 130 provides or processes appropriate information or functions to the user by processing signals, data, information, etc. input or output through the above-described components or by driving an application program stored in the first memory 120 . can do.

In addition, the first processor 130 may control at least some of the components discussed with reference to FIG. 2 in order to drive an application program stored in the first memory 120 . Furthermore, in order to drive the application program, the first processor 130 may operate at least two or more of the components included in the computing device 10 in combination with each other.

The first processor 130 may provide an application for the block-chain-based user-customized disaster notification to be installed for each of the plurality of terminals 20 .

The first processor 130 may acquire time location information for each of the plurality of terminals through the applications installed in the plurality of terminals 20 .

The first processor 130 may encrypt the time location information.

Referring to FIG. 4 , the first processor 130 may encrypt user identification information, user time information, and user location information included in the time location information for each of the plurality of terminals 20 based on an encryption algorithm.

Here, the first processor 130 may first create a library (storage) to encrypt the user identification information, user time information, and user location information included in the time location information according to the encryption algorithm. Thereafter, the first processor 130 may call the library and create a new contract (eg, store the time location information in the creator (User_Info)). Here, the generator User_Info may be an address type storage space to store the time location information at once. Also, here, the name of the new contract may be HateCovid.

Specifically, the first processor 130 may generate the library (eg, MyLocationTIme library) that initializes the user's time location information using Solidity. The first processor 130 stores a personal identification code in a 512-bit size of a positive integer in the structure of the library, stores personal time information in a 512-bit size of a positive integer in the structure of the library, and You can store private location information in a structure with a size of 512 bits of a positive integer.

The first processor 130 may load the library using Solidity and create a new contract for storage in the blockchain network using the library. That is, the first processor 130 may generate a generator (User_Info) that owns the contract and can store user personal information, and stores a user identification number, user time information, and user location information in the generator. Here, the first processor 130 may permanently reflect the creator to the blockchain network.

The first processor 130 may store the encrypted time location information in a block in the block chain network.

Specifically, referring to FIGS. 5 to 7 , the first processor 130 broadcasts time location information for each of the plurality of terminals 20 among the nodes in the block chain network and preempts one node that is received first. (501) can be selected. A blockchain network may be configured by connecting a plurality of nodes (servers). Specifically, blockchain allows individual servers participating in transactions to gather and maintain and manage the network without storing and managing transaction records in a centralized server. Here, an individual server, that is, a participant can be referred to as a node.

For example, when the terminal 20 broadcasts the time location information, the preemption node 501 that first receives the time location information may be a server (computer) with good performance and good communication status.

The first processor 130 may broadcast the first selection notification signal from the preemption node 501 to select one node that is first received as the helper node 601 . Here, when the preemption node 501 broadcasts the first selection notification signal, the assistance node 601 that first receives the first selection notification signal may be a server (computer) with good performance and good communication status have.

The first processor 130 may cause the preemption node 501 in the block chain network to transmit a first selection notification signal to at least one neighboring node.

The first processor 130 evaluates at least one neighboring node in the order in which the assistance node 601 broadcasts the second selection notification signal to the at least one neighboring node excluding the preemption node 501 . node can be selected.

As an example, the first processor 130 selects an adjacent node that first receives the second selection notification signal as the first evaluation node 701 when the assistance node 601 broadcasts the second selection notification signal, and , then a neighboring node receiving the second selection notification signal may be selected as the second evaluation node 702 .

Here, referring to FIGS. 6 to 7 , although two evaluation nodes 701 and 702 are illustrated, the present invention is not limited thereto, and at least two evaluation nodes may be selected.

The first processor 130 transmits a confirmation signal corresponding to the first selection notification signal and the second selection notification signal from the first evaluation node 701 and the second evaluation node 702 to the preemption node 501, It can be transmitted to the helper node 601 and the at least one adjacent node.

Here, the first processor 130 may determine a node other than the evaluation node among the at least one adjacent node as the failure node 801 .

The first processor 130 generates a suitability evaluation signal for the time location information in the first evaluation node 701 and the second evaluation node 702, respectively, to the preemption node 501 and the assistance node 601, respectively. and at least one adjacent node.

After transmitting the suitability evaluation signal from the first evaluation node 701 and the second evaluation node 702, the first processor 130 generates an approval signal or a rejection signal for the time location information to generate the preemption node 501. And it can be transmitted to the assistance node (601).

When the first processor 130 receives the approval signal from the first evaluation node 701 and the second evaluation node 702 in the assistance node 601 , it generates a review notification signal based on the approval signal to transmit to the preemption node 501 .

On the other hand, when the first processor 130 receives the rejection signal from the first evaluation node 701 and the second evaluation node 702 in the assistance node 601 , a review notification signal based on the rejection signal can be generated and transmitted to the preemption node 501 .

The first processor 130 may cause the preemption node 501 that has received the review notification signal to store the time location information in the block in the block chain network based on the review notification signal.

That is, when the first processor 130 receives the review notification signal generated based on the approval signal from the preemption node 501, the first processor 130 may store the time location information in the block in the block chain network. have.

On the other hand, when the first processor 130 receives the review notification symbol generated based on the rejection signal from the preemption node 501, the first processor 130 determines that the time location information has been forged or manipulated, and is within the block chain network. You can choose not to store it in the above block.

When a user of the first terminal 201 among the plurality of terminals 20 is notified from the infectious disease management server 30 as an infected person, the first processor 130 determines the first block in the block chain network 60 . Based on the encrypted first time location information of the first terminal 201 stored in the corresponding block of the terminal 201, the movement of the first terminal 201 may be determined.

The first processor 130 determines, among the plurality of terminals, as a high-risk terminal, based on the identified movement line, at least one second terminal 202 that overlaps the movement line at the same location and time zone as the first terminal 201 . can do.

Based on the encrypted second time location information of the second terminal 202 stored in the corresponding block of the second terminal 202 among the blocks in the block chain network, the first processor 130 determines the second terminal ( 202) and at least one third terminal 203 having overlapping moving lines in the same location and time zone may be determined as a low-risk terminal.

The first processor 130 may transmit a message indicating contact with an infected person to the second terminal 202 and the third terminal 203 , respectively.

Here, the message transmitted to the second terminal 202 includes information notifying that the user of the second terminal 202 is a close contact with the infected person, information notifying a test request for the infectious disease, and information notifying a test location for the infectious disease may include.

In addition, the message transmitted to the third terminal 203 includes information indicating that the user of the second terminal 202 is a close contact with the infected person and whether the user of the second terminal 202 is infected with the infectious disease. It may contain information you request to be confirmed.

The plurality of terminals 20 may download and execute an application provided by the computing device 10 directly through the computing device 10 or may download and execute an application provided by the computing device 10 from a download server (not shown). Here, when the download server (not shown) receives the application download request from the plurality of terminals 20 , it may provide the requested application to the plurality of terminals 20 .

The plurality of terminals 20 may execute a membership registration procedure for subscribing to the application and a login procedure after membership registration.

More specifically, the plurality of terminals 20 may perform identity authentication by inputting at least one of a name, a date of birth, and a mobile phone number for the membership registration procedure.

The plurality of terminals 20 may generate login information including an ID and password for a login procedure after performing user authentication.

Referring to FIG. 9 , a screen 901 displayed on the plurality of terminals 20 is a screen displayed after each user performs a login procedure through the application, and a user ID 902 , the amount of user coins in the application (903) may be indicated.

In addition, the screen 901 may include a map 904 displayed at the top, an activation and deactivation button 905 for providing user location information, a cryptocurrency transaction button 906 and a notification message button 907 at the bottom. .

As an example, when the user inputs the user location information provision activation and deactivation button 905 at the bottom through the application of the terminal 20 once, the state of the terminal 20 is changed to an activated state providing location information. can On the other hand, when the user inputs the user location information provision activation and deactivation button 905 at the bottom through the application of the terminal 20 twice, the state of the terminal 20 changes to an inactive state that does not provide location information can be

As another example, when the user inputs the cryptocurrency transaction button 906 at the bottom through the application of the terminal 20, it may be switched to a screen for cryptocurrency transaction.

As another example, when the user inputs the notification message button 907 of the terminal 20 , the screen may be switched to a screen for confirming a message indicating contact with an infected person.

The terminal 20 may be connected to the server 30 through a network such as a mobile phone, a smart phone, a PDA (Personal Digital Assistant), a PMP (Portable Multimedia Player), a tablet PC, etc. It may be any type of handheld-based wireless communication device capable of input/output of information.

Here, the terminal 20 may include a second communication unit 210 , an input/output unit 220 , a second memory 230 , and a second processor 240 . Here, the terminal 20 may include a smaller number of components or more components than the components shown in FIG. 3 .

The second communication unit 210 is connected between the terminal 20 and each of the wireless communication systems, between the terminal 20 and the computing device 10 , between the terminal 20 and the infectious disease management server 30 , and between the terminal 20 and the enterprise. It may include one or more modules that enable wireless communication between the server 40 , between the terminal 20 and the cryptocurrency transaction server 50 , or between the terminal 20 and the blockchain network 60 .

The input/output unit 220 may include a touch key, a mechanical key, etc.) for receiving information from a user, and a display module for generating an output related to a visual, auditory or tactile sense to the user. (not shown), a sound output module (not shown), a haptic module (not shown), and an optical output module (not shown).

Here, the display module may be implemented as a touch screen that forms a layer structure with the touch sensor or is integrally formed. Such a touch screen may provide an input interface between the terminal 20 and the user and an output interface between the terminal 20 and the user.

The second memory 230 may store data supporting various functions of the terminal 20 . The second memory 230 may store a plurality of application programs (or applications) driven in the terminal 20 , data for operation of the terminal 20 , and commands. At least some of these application programs may be downloaded from an external server (not shown) through wireless communication.

In addition, at least some of these application programs may exist for a basic function of the terminal 20 . Meanwhile, the application program may be stored in the second memory 230 , installed on the terminal 20 , and driven to perform an operation (or function) of the terminal 20 by the second processor 240 . .

The second memory 230 may store an application provided by the computing device 10 . More specifically, the second memory 230 may store application execution data for selling returned food in real time to the terminal 20 .

In addition to the operation related to the application program, the second processor 240 may generally control the overall operation of the terminal 20 . The second processor 240 processes signals, data, information, etc. input or output through the above-described components or by driving an application program stored in the second memory 230 to provide or process appropriate information or functions to the user. can do.

In addition, the second processor 240 may control at least some of the components described with reference to FIG. 3 in order to drive an application program stored in the second memory 230 . Furthermore, in order to drive the application program, the second processor 240 may operate at least two or more of the components included in the terminal 20 in combination with each other.

The infectious disease management server 30 may be a server built by the government for infectious disease management.

The corporate server 40 may be a server built by a company that wants to obtain time and location information from a user in order to provide services such as infectious disease-related drugs, masks, and products.

The cryptocurrency transaction server 50 is a server that provides a service for cashing out cryptocurrency paid according to the amount of time location information data acquired for each user's terminal 20 from the infectious disease management server 30 or the corporate server 40 can

The blockchain network 60 can store distributed data that stores data in blocks, connects them in a chain form, and replicates and stores them in numerous nodes (servers or computers) at the same time. The blockchain network 60 sends transaction details to all users participating in the transaction without storing transaction records on a centralized server, and every transaction participant shares information and collates it to prevent data forgery or falsification. it is impossible to Here, the transaction details according to the present invention may be time location information of the user.

A communication network (not shown) may transmit/receive various information between the computing device 10 , the plurality of terminals 20 , the infectious disease management server 30 , the corporate server 40 , and the cryptocurrency transaction server 50 . A communication network (not shown) may use various types of communication networks, for example, WLAN (Wireless LAN), Wi-Fi, Wibro, Wimax, HSDPA (High Speed Downlink Packet Access), etc. of wireless communication method or wired communication method such as Ethernet, xDSL (ADSL, VDSL), HFC (Hybrid Fiber Coax), FTTC (Fiber to The Curb), FTTH (Fiber To The Home) can be used.

On the other hand, the communication network (not shown) is not limited to the communication method presented above, and may include all types of communication methods which are well known or to be developed in the future in addition to the above-described communication methods.

10 is a flowchart illustrating a block chain-based user-customized infectious disease notification process according to the present invention.

11 is a flowchart illustrating a process of verifying time location information when storing time location information in a block chain network according to the present invention.

Hereinafter, a block-chain-based user-customized infectious disease notification process in the first processor 130 will be described in detail with reference to FIGS. 10 to 11 . Here, the operation of the first processor 130 may be performed in the same manner in the computing device 10 .

The first processor 130 may provide an application for the block chain-based user-customized disaster notification to be installed for each terminal (S1001).

The first processor 130 may acquire time location information for each of the plurality of terminals through the application installed in the plurality of terminals (S1002).

The first processor 130 may encrypt the time location information (S1003).

In more detail, the first processor 130 may encrypt user identification information, user time information, and user location information included in the time location information for each of the plurality of terminals 20 based on an encryption algorithm.

The first processor 130 may store the encrypted time location information in a block in the block chain network (S1004).

Here, referring to FIG. 11 , the first processor 130 broadcasts the time location information for each of the plurality of terminals among the nodes in the block chain network and selects one node that is first received as the preemption node (S1101) .

Here, when the terminal 20 broadcasts the time location information, the preemption node 501 that first receives the time location information may be a server (computer) with good performance and good communication status.

The first processor 130 may broadcast a first selection notification signal from the preemption node and select one node that is first received as a helper node (S1102).

Here, when the preemption node 501 broadcasts the first selection notification signal, the assistance node 601 that first receives the first selection notification signal may be a server (computer) with good performance and good communication status have.

The first processor 130 may cause the preemption node in the block chain network to transmit a first selection notification signal to at least one neighboring node (S1103).

At least one neighboring node may be selected as an evaluation node in the order of broadcasting and receiving the second selection notification signal from the assistance node to the at least one neighboring node excluding the preemption node (S1104).

Here, the first processor 130 selects a neighboring node that first receives the second selection notification signal when the assistance node 601 broadcasts the second selection notification signal as the first evaluation node 701, Next, a neighboring node receiving the second selection notification signal may be selected as the second evaluation node 702 .

The first processor 130 may transmit a confirmation signal corresponding to the first selection notification signal and the second selection notification signal from the evaluation node to the preemption node, the helper node, and the at least one adjacent node. (S1105).

Here, the first processor 130 may determine a node other than the evaluation node among the at least one adjacent node as the failure node 801 .

The first processor 130 generates a suitability evaluation signal for the time location information in the first evaluation node 701 and the second evaluation node 702, respectively, to the preemption node 501 and the assistance node 601, respectively. and at least one adjacent node. (S1106).

After transmitting the suitability evaluation signal from the first evaluation node 701 and the second evaluation node 702, the first processor 130 generates an approval signal or a rejection signal for the time location information to generate the preemption node 501. And it can be transmitted to the assistance node 601 (S1107).

When the first processor 130 receives the approval signal from the first evaluation node 701 and the second evaluation node 702 in the assistance node 601 , it generates a review notification signal based on the approval signal to transmit to the preemption node 501 (S1108).

On the other hand, when the first processor 130 receives the rejection signal from the first evaluation node 701 and the second evaluation node 702 in the assistance node 601 , a review notification signal based on the rejection signal can be generated and transmitted to the preemption node 501 .

The first processor 130 may cause the preemption node 501 that has received the review notification signal to store the time location information in the block in the block chain network based on the review notification signal (S1109).

That is, when the first processor 130 receives the review notification signal generated based on the approval signal from the preemption node 501, the first processor 130 may store the time location information in the block in the block chain network. have.

On the other hand, when the first processor 130 receives the review notification symbol generated based on the rejection signal from the preemption node 501, the first processor 130 determines that the time location information has been forged or manipulated, and is within the block chain network. You can choose not to store it in the above block.

When a user of the first terminal among the plurality of terminals is notified by the infectious disease management server as an infected person, the first processor 130 encrypts the first terminal stored in the corresponding block of the first terminal among blocks in the block chain network. Based on the first time location information, it is possible to determine the movement of the first terminal (S1005).

The first processor 130 may determine, among the plurality of terminals, as a high-risk terminal based on the identified movement line (S1006). .

Based on the encrypted second time location information of the second terminal stored in the corresponding block of the second terminal among the blocks in the block chain network, the first processor 130 moves in the same location and time zone as the second terminal. At least one overlapping third terminal may be determined as a low-risk terminal (S1007).

The first processor 130 may transmit a message notifying that an infected person is in contact with the second terminal and the third terminal, respectively (S1008).

Here, the message transmitted to the second terminal 202 includes information notifying that the user of the second terminal 202 is a close contact with the infected person, information notifying a test request for the infectious disease, and information notifying a test location for the infectious disease may include.

In addition, the message transmitted to the third terminal 203 includes information indicating that the user of the second terminal 202 is a close contact with the infected person and whether the user of the second terminal 202 is infected with the infectious disease. It may contain information you request to be confirmed.

10 to 11 are described as sequentially executing a plurality of steps, but this is merely illustrative of the technical idea of this embodiment, and those of ordinary skill in the art to which this embodiment belongs 10 to 11 are time series, since various modifications and variations may be applied by changing the order described in FIGS. 10 to 11 or executing one or more steps of a plurality of steps in parallel without departing from the essential characteristics of the example It is not limited to the sequential order.

The method according to an embodiment of the present invention described above may be implemented as a program (or application) to be executed in combination with a server, which is hardware, and stored in a medium.

The above-described program is C, C++, JAVA, machine language, etc. that a processor (CPU) of the computer can read through a device interface of the computer in order for the computer to read the program and execute the methods implemented as a program It may include code (Code) coded in the computer language of Such code may include functional code related to functions defining functions necessary for executing the methods, etc. can do. In addition, the code may further include additional information necessary for the processor of the computer to execute the functions or code related to memory reference for which location (address address) in the internal or external memory of the computer to be referenced. have. In addition, when the processor of the computer needs to communicate with any other computer or server located remotely in order to execute the above functions, the code uses the communication module of the computer to determine how to communicate with any other computer or server remotely. It may further include a communication-related code for whether to communicate and what information or media to transmit and receive during communication.

The steps of a method or algorithm described in relation to an embodiment of the present invention may be implemented directly in hardware, as a software module executed by hardware, or by a combination thereof. A software module may contain random access memory (RAM), read only memory (ROM), erasable programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), flash memory, hard disk, removable disk, CD-ROM, or It may reside in any type of computer-readable recording medium well known in the art to which the present invention pertains.

As mentioned above, although embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can realize that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: computing device
110: first communication unit
120: first memory
130: first processor
20: terminal
210: second communication unit
220: input/output unit
230: second memory
240: second processor
30: Infectious disease management server
40: Enterprise Server
50: cryptocurrency trading server
60: Blockchain Network

Claims (21)

In a blockchain-based user-customized infectious disease notification method performed by a computing device,
providing an application for the block-chain-based user-customized disaster notification to be installed for each terminal;
obtaining time location information for each of the plurality of terminals through the application installed on the plurality of terminals;
encrypting the time location information;
storing the encrypted time location information in a block in the blockchain network;
When a user of the first terminal among the plurality of terminals is notified by the infectious disease management server as an infected person, the encrypted first time location information of the first terminal stored in the corresponding block of the first terminal among blocks in the block chain network is retrieved. based on the step of identifying the movement of the first terminal;
determining, among the plurality of terminals, as a high-risk terminal based on the identified movement line;
Based on the encrypted second time location information of the second terminal stored in the corresponding block of the second terminal among the blocks in the block chain network, at least one third that overlaps the moving line at the same location and time zone as that of the second terminal determining the terminal as a low-risk terminal; and
Transmitting a message indicating contact with an infected person to the second terminal and the third terminal, respectively;
The storage step is
Among the nodes in the blockchain network, one node that broadcasts the time location information for each terminal and receives first is selected as the preemption node,
Broadcasting the first selection notification signal from the preemption node, selecting one node that is first received as a helper node. According to claim 1,
The message transmitted to the second terminal includes information notifying that the user of the second terminal is a close contact with the infected person, information notifying a test request for the infectious disease, and information notifying a test location for the infectious disease,
The message transmitted to the third terminal includes information notifying that the user of the second terminal is a close contact with the infected person and information requesting to check whether the user of the second terminal is infected with the infectious disease . According to claim 1,
The infectious disease management server,
A method of paying cryptocurrency according to the data amount of time location information for each of the plurality of terminals. delete According to claim 1,
The storage step is
Transmitting a first selection notification signal from the preemption node in the block chain network to at least one neighboring node,
Selecting at least one neighboring node as an evaluation node in the order of broadcasting and receiving a second selection notification signal from the assistance node to the at least one neighboring node excluding the preemption node,
The evaluation node transmits a confirmation signal corresponding to the first selection notification signal and the second selection notification signal to the preemption node, the helper node, and the at least one adjacent node from the evaluation node. 6. The method of claim 5,
The storage step is
Determining a node excluding the evaluation node among the at least one neighboring node as a failure node. 7. The method of claim 6,
The evaluation node is
A method of generating a suitability evaluation signal for the time location information and transmitting it to the preemption node, the helper node, and at least one adjacent node. 8. The method of claim 7,
The evaluation node is
After transmitting the suitability evaluation signal, an approval signal or a rejection signal for the time location information is generated and transmitted to the preemption node and the assistance node. 9. The method of claim 8,
The help node is
When the acknowledgment signal is received from the evaluation node, a review notification signal is generated based on the acknowledgment signal and transmitted to the preemption node. 10. The method of claim 9,
The storage step is
The method of storing the time location information in the block in the blockchain network based on the review notification signal in the preemption node that has received the review notification signal. According to claim 1,
The encryption step is
The method of encrypting user identification information, user time information, and user location information included in the time location information for each of the plurality of terminals based on an encryption algorithm. In a blockchain-based user-customized disaster and infectious disease notification system,
A plurality of terminals in which an application for a blockchain-based user-customized disaster notification is installed;
a computing device for obtaining time location information for each of the plurality of terminals through the application installed on the plurality of terminals, and generating a message for a block-chain-based customized disaster notification based on the time location information; and
an infectious disease management server that pays cryptocurrency according to the amount of data of time location information for each of the plurality of terminals;
The computing device is
providing that the application for the block-chain-based user-customized disaster notification is installed for each of the plurality of terminals;
Obtaining time location information for each of the plurality of terminals through the application installed in the plurality of terminals,
Encrypt the time location information,
Storing the encrypted time location information in a block in the blockchain network,
When the infectious disease management server notifies the user of the first terminal among the plurality of terminals as an infected person, the encrypted first time location information of the first terminal stored in the corresponding block of the first terminal among blocks in the block chain network Based on the, identify the movement of the first terminal,
Based on the identified movement line, it is determined that at least one second terminal in which the movement line overlaps in the same location and time zone as the first terminal among the plurality of terminals is a high-risk terminal,
Based on the encrypted second time location information of the second terminal stored in the corresponding block of the second terminal among the blocks in the block chain network, at least one third that overlaps the moving line at the same location and time zone as that of the second terminal Determining the terminal as a low-risk terminal,
transmitting a message indicating contact with an infected person to the second terminal and the third terminal, respectively;
The computing device is
Among the nodes in the blockchain network, one node that broadcasts the time location information for each terminal and receives first is selected as the preemption node,
Broadcasting the first selection notification signal from the preemption node, selecting one node that is first received as a helper node, the system. 13. The method of claim 12,
The message transmitted to the second terminal includes information in which the user of the second terminal informs the infected person and a close contact, information notifying a test request for the infectious disease, and information notifying a test location for the infectious disease,
The message transmitted to the third terminal includes information for a user of the second terminal to notify the infected person and a close contact, and information for requesting whether the user of the second terminal is infected with the infectious disease. . delete 13. The method of claim 12,
The computing device is
Transmitting a first selection notification signal from the preemption node in the block chain network to at least one neighboring node,
Selecting at least one neighboring node as an evaluation node in the order of broadcasting and receiving a second selection notification signal from the assistance node to the at least one neighboring node excluding the preemption node,
In the evaluation node, a confirmation signal corresponding to the first selection notification signal and the second selection notification signal is transmitted to the preemption node, the assistance node, and the at least one adjacent node. 16. The method of claim 15,
The computing device is
Determining a node other than the evaluation node among the at least one neighboring node as a failed node. 17. The method of claim 16,
The evaluation node is
A system for generating a suitability evaluation signal for the time location information and transmitting it to the preemption node, the helper node, and at least one adjacent node. 18. The method of claim 17,
The evaluation node is
After transmitting the suitability evaluation signal, an approval signal or a rejection signal for the time location information is generated and transmitted to the preemption node and the assistance node. 19. The method of claim 18,
The help node is
When the approval signal is received from the evaluation node, a review notification signal is generated based on the approval signal and transmitted to the preemption node. 20. The method of claim 19,
The computing device is
In the preemption node receiving the review notification signal, the time location information is stored in the block in the blockchain network based on the review notification signal. 13. The method of claim 12,
The computing device is
For each of the plurality of terminals, user identification information, user time information, and user location information included in the time location information are encrypted based on an encryption algorithm, the system.

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