KR20230060829A - Validation system of test report based on blockchain network for identity authentication - Google Patents

Abstract

In accordance with an embodiment, a system for validating a test report based on a blockchain network for identity authentication, includes: an app server issuing a manufacturer VC associated with an original test report of a manufacturer, and recording the issued manufacturer VC on a second blockchain network; and a second manufacturer terminal obtaining the manufacturer VC via the second blockchain network, and transmitting a two-dimensional code of a test report to be compared corresponding to the original test report, to the app server, wherein the app server extracts a second code value of the two-dimensional code received from the second manufacturer terminal, and transmits a validation request for the test report to be compared including the extracted second code value, onto the first blockchain network, and, the second manufacturer terminal can receive a validation result of the test report to be compared based on the second code value, which is performed via the first blockchain network, from the first blockchain network. Therefore, the present invention enables transparent information management.

Description

Validation system of test report based on blockchain network for identity authentication}

The present invention relates to a system for verifying the validity of a test report based on a blockchain network for identity authentication, and more specifically, to authenticate a manufacturer terminal using manufacturer VC information recorded through a blockchain network for identity authentication, It relates to a validation system for a test report based on a blockchain network for identity authentication, which aims to prevent forgery and falsification of a test report by ensuring that the requested test report is validated through a general blockchain network.

In accordance with the Environmental Testing and Inspection Act, the Food Sanitation Act, the Korea Food and Drug Administration and the Korea Centers for Disease Control and Prevention test request rules, the Safety Management Act, and the Framework Act on National Standards, to ensure the quality of all products that manufacturers deliver to suppliers, test subjects and test results etc. are required to be submitted to the supplier.

If these test results are forged or falsified by the manufacturer or a third party, negative results may be delivered not only to related organizations but also to general consumers.

The present invention has been derived from the above problems, and its purpose is to prevent forgery and falsification of test results through a blockchain network and to improve reliability.

In particular, the purpose of the present invention is to provide a separate blockchain network for DID-based identity authentication to further improve the accuracy and security performance of forgery and alteration search results of test reports.

Another object of the present invention is to enable transparent information management by allowing test progress or test results to be shared with each institution through a web server.

In addition, the purpose is to ensure that each institution can receive a user interface that is easy to operate through a web page in order to derive test progress or test results.

The validation system of the test report based on the blockchain network for identity authentication according to the embodiment issues the manufacturer VC related to the original test report of the manufacturer, and the app server records the issued manufacturer VC on the second blockchain network. ; and

A second manufacturer terminal that obtains the manufacturer VC through the second blockchain network and transmits a two-dimensional code of a test report to be compared to the original test report corresponding to the original test report to the app server;

The app server extracts the second code value of the two-dimensional code received from the second manufacturer terminal, and sends a request for validation of the comparison target test report including the extracted second code value to the first block chain. send over the network,

The second manufacturer terminal may receive, from the first blockchain network, a validation result of the test report to be compared based on the second code value performed through the first blockchain network.

The second manufacturer's terminal receives the main information of the original test report from the first blockchain network when it is judged to be valid as a result of the validity verification of the comparison target test report performed through the first blockchain network, and is not valid. If it is determined that it is not, an error message may be received from the first blockchain network.

The manufacturer VC may include at least one of a manufacturer DID, a test company DID, main information of the original test report, and a hash value.

The app server may further issue a connection DID for connecting the manufacturer DID and the tester DID.

a first manufacturer's terminal; and extracting a second hash value of the test report for comparison uploaded from the first manufacturer terminal, and sending a request for validation of the uploaded test report for comparison including the extracted second hash value to the first blockchain network. It further includes; a web server that transmits on

The first manufacturer terminal may receive, from the first blockchain network, a validation result of the uploaded test report to be compared based on the second hash value performed through the first blockchain network.

The first manufacturer terminal receives main information of the original test report from the first blockchain network when it is judged to be valid as a result of validating the uploaded comparison target test report performed through the first blockchain network, If it is determined that it is not valid, an error message may be received from the first blockchain network.

The web server may record at least one of a first hash value, a first code value, and main information of the original test report on the first blockchain network.

According to the present invention, forgery and falsification of test results through a blockchain network can be prevented and reliability can be improved.

In particular, the present invention allows transparent information management to be achieved by allowing test progress or test results to be shared with each institution through a web server.

In addition, each institution can be provided with a user interface that is easy to operate through a web page in order to derive test progress or test results.

1 is a block diagram of a test report validation system 1 based on a blockchain network according to an embodiment.
2 is a block diagram of a web server 30 according to an embodiment.
3 is a block diagram of an app server 40 according to an embodiment.
4 is a diagram illustrating an electronic wallet according to an embodiment.
5 is a flowchart for explaining a DID registration process according to an embodiment.
6 is a flowchart illustrating a process of issuing a Connection DID according to an embodiment.
7 is a flowchart illustrating a process of registering a test report and issuing a manufacturer VC during the operation of the test report validation system 1 based on a blockchain network according to an embodiment.
8 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validity verification system 1 based on a blockchain network according to an embodiment.
9 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validity verification system 1 based on a blockchain network according to another embodiment.
10 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validation system 1 based on a blockchain network according to another embodiment.
11 to 14 are diagrams referenced to explain operations through the first blockchain network N2.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in one embodiment in another embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Like reference numbers in the drawings indicate the same or similar function throughout the various aspects.

1 is a block diagram of a test report validation system 1 based on a blockchain network according to an embodiment.

As shown in FIG. 1, the test report validation system 1 based on the blockchain network according to the embodiment includes a first manufacturer terminal 10, a second manufacturer terminal 11, a tester terminal 20, a web It may consist of data transmission and reception between the server 30 and the app server 40 .

According to the embodiment, various implementations may be performed, such as some of the components being omitted or some of the components serving as other components.

The first manufacturer's terminal 10 is provided for the manufacturer to receive a test and receive a test report, and can communicate with the web server 30 .

The first manufacturer's terminal 10 may include all of various devices such as a desktop, PC, smart phone, and tablet capable of outputting a web page provided from the web server 30 .

The second manufacturer's terminal 11 is provided to acquire the two-dimensional code of the test report and can communicate with the app server 40 .

The second manufacturer's terminal 11 may include all of various devices such as smart phones and tablets that have a shooting function and can scan a two-dimensional code using an app.

The tester's terminal 20 is provided for the tester performing the test on the manufacturer's test subject to approve the manufacturer's test acceptance request and to register the issued test report with the web server 30, the web server (30) and communication can be performed.

The tester terminal 20 may include all of various devices such as a desktop, PC, smart phone, and tablet capable of outputting a web page provided from the web server 30 .

The web server 30 provides a web page to the first manufacturer terminal 10 and the test company terminal 20, manages test reception, and interlocks with the first blockchain network N2 to check the validity of the test report using the hash value. It can be provided to be verified.

The app server 40 is provided to verify the validity of the test report using the two-dimensional code value, and can be interlocked with the first blockchain network N2.

Meanwhile, the network according to the embodiment may include a general network N1, a first blockchain network N2, and a second blockchain network N3.

Here, the general network (N1) may be configured through various communication networks such as wired and wireless, for example, a local area network (LAN), a metropolitan area network (MAN), and a wide area network ( It can be composed of various communication networks such as WAN (Wide Area Network).

According to the embodiment, a plurality of blockchain nodes forming one or more P2P (Peer-to-Peer) network structures may be linked through the first blockchain network N2 and/or the second blockchain network N3. there is. For example, at least a part of the first manufacturer terminal 10, the second manufacturer terminal 11, the tester terminal 20, the web server 30, and the app server 40 are connected to the first blockchain network (N2 ) and/or the second blockchain network N3 to form a plurality of blockchain network structures, each of which can interact as a distributed blockchain node.

Each node linked through the first blockchain network (N2) stores the information of each node in the block ledger to create a block, and transmits the generated block to other related nodes connected to the block chain through consensus. By doing so, a plurality of remaining nodes can have the same block.

The second blockchain network N3 may be a blockchain platform created for identity authentication by establishing a DID. According to the embodiment, identity information of nodes participating in the network can be controlled and managed through a method of storing DID in a wallet of a client.

2 is a block diagram of a web server 30 according to an embodiment.

The web server 30 according to the embodiment may include a test report management unit 31, an extraction unit 32, a blockchain interlocking unit 33, and a VC issuance requesting unit 34.

The test report management unit 31 may manage registration of the original test report.

The test report management unit 31 receives a test acceptance request from the first manufacturer terminal 10, receives a test acceptance approval from the tester terminal 20, and registers the original test report based on the test acceptance approval result. can manage

The test report manager 31 may transmit a confirmation request signal for the registered original test report to the first manufacturer terminal 10 and receive a confirmation completion signal for the original test report from the first manufacturer terminal 10. .

The test report management unit 31 may insert a 2D code such as a QR code or barcode into the original test report that has been confirmed, and transmit the test report with the 2D code inserted to the tester terminal 20 .

The test report manager 31 may transmit the original test report in which the final confirmed two-dimensional code is inserted to the first manufacturer terminal 10 and/or the tester terminal 20 .

The extraction unit 32 may extract the hash value (first hash value) of the original test report.

The extraction unit 32 may extract the first hash value based on content data and/or metadata of the original test report.

The extraction unit 32 may extract the 2D code value (first code value) of the original test report.

The blockchain interlocking unit 33 may record information related to the original test report on the first blockchain network N2.

The blockchain interlocking unit 33 transmits the first hash value of the original test report, the main information of the original test report, the two-dimensional code value (first code value), and/or the unique value of the original test report to the first blockchain network. It can be recorded on (N2).

The extraction unit 32 may extract the hash value (second hash value) of the test report to be compared.

The extraction unit 32 may extract the second hash value based on the content data and/or metadata of the test report to be compared.

The VC issuance request unit 34 may transmit a manufacturer VC generation request signal to the app server 40 . According to the embodiment, the hash value (first hash value) of the original test report and the main information of the test report may be included in the manufacturer VC generation request signal and transmitted to the app server 40 .

According to the embodiment, the manufacturer VC may be created in the app server 40 to include the hash value (first hash value) of the original test report, main information of the test report, manufacturer DID, and/or test company DID.

The blockchain interlocking unit 33 may interwork with the first blockchain network N2 to inquire about forgery or alteration of the test report.

The blockchain interlocking unit 33 transmits a validity verification request of the test report to be compared including the extracted second hash value to the first blockchain network N2, and the second hash value and the second hash value from the blockchain network. A validation result through comparison of the first hash value may be received.

The blockchain interlocking unit 33 receives main information of the original test report from the blockchain network when it is determined to be valid as a result of comparing the second hash value and the first hash value by the blockchain network, If it is determined to be invalid, an error message may be received from the blockchain network.

3 is a block diagram of an app server 40 according to an embodiment.

The app server 40 according to the embodiment may include a DID management unit 41, a connection DID issuing unit 42, a VC issuing unit 43, a code value management unit 44, and a hash value management unit 45. .

The DID management unit 41 may issue a DID document (DID Doc) corresponding to the DID and then store it on the second blockchain network N3.

The connection DID issuing unit 42 may issue a connection DID for connecting the manufacturer DID and the tester DID.

The Connection DID issuing unit 42 may issue a Connection DID by referring to the connection request signal received from the second manufacturer terminal 11 and transmit the issued Connection DID to the second manufacturer terminal 11 .

The VC issuing unit 43 may issue a manufacturer VC.

The VC issuing unit 43 may include the hash value (first hash value) of the original test report, main information of the test report, the manufacturer DID, and/or the tester DID in the manufacturer VC.

The code value management unit 44 may extract the code value (second code value) of the two-dimensional code of the test report to be compared.

The code value management unit 44 may receive the 2D code from the second manufacturer terminal 11 and extract a code value (second code value) of the received 2D code.

The code value management unit 44 may interwork with the first blockchain network N2 to inquire about forgery or alteration of the test report.

The code value management unit 44 includes the extracted second code value in the validity verification request signal of the test report to be compared and transmits it to the first blockchain network N2, and from the blockchain network N2 to the second code value A validation result through comparison between the first code value and the first code value may be received.

According to the embodiment, when it is determined to be valid as a result of comparison between the second code value and the first code value by the first blockchain network N2, the code value management unit 44 sends the original code value from the first blockchain network N2. When the main information of the test report is received and the comparison result is determined to be invalid by the first blockchain network (N2), the code value management unit 44 receives an error message from the blockchain network (N2). can

The hash value management unit 45 may extract the second hash value of the test report to be compared.

The hash value management unit 45 may transmit the second hash value to the first blockchain network N2 by including the second hash value in the validity verification request signal of the test report to be compared.

According to the embodiment, when it is determined to be valid as a result of comparison between the second code value and the first code value by the first block chain network N2, the hash value management unit 45 determines the original value from the first block chain network N2. When the main information of the test report is received and the comparison result is determined to be invalid by the first blockchain network (N2), the hash value management unit 45 receives an error message from the blockchain network (N2). can

4 is a diagram illustrating an electronic wallet according to an embodiment; An electronic wallet according to an embodiment may include a decentralized ID (DID), a verified credential (VC), and a connection DID.

5 is a flowchart for explaining a DID registration process according to an embodiment.

As shown in FIG. 5 , the second manufacturer's terminal 11 may drive the electronic wallet app (s51) to check whether the DID has been previously issued and stored in the electronic wallet. If it is issued, it goes to step s52, and if it is not issued, it can be stored in the electronic wallet along with the private key after issuing the DID. According to an embodiment, the DID may include at least one of a manufacturer's corporate registration number and a corporate address.

DID is a user identifier based on decentralized identification service using blockchain technology. When DID is used as an authentication method, the identity verification system utilizes blockchain technology to prevent forgery and falsification of identity and qualification information and to ensure accuracy, and stores and manages data for verification in a distributed manner. DIDs for each manufacturer can be registered.

According to the embodiment, since the second manufacturer's terminal 11 autonomously generates and manages the DID, through the above process, information that is judged unnecessary or not desired to be exposed can be managed so as not to be included in public information. In addition, only some DID information (eg manufacturer corporation registration number) among all DID information can be selected, registered in the system, and authenticated to prove identity.

The second manufacturer terminal 11 may register the second manufacturer in the blockchain-based identity authentication service. In particular, through the app provided by the identity authentication service, the manufacturer authentication process can be performed and the signature can be transmitted to the identity authentication service.

Specifically, when the second manufacturer terminal 11 requests DID registration through the app server 40 (s52), the DID management unit 41 of the app server 40 generates a DID document (DID Doc) corresponding to the DID. After issuing, it can be stored on the second blockchain network (N3) (s52-1). According to the embodiment, the DID document may include information related to the manufacturer, a method for verifying the information, a public key of the DID, an authentication protocol, and a service endpoint. For reference, the second blockchain network (N3) may include a DID document and a Revocation Registry including information for revocation of various certificates. Thereafter, the DID document issuance completion information transmitted from the second blockchain network N3 through the app server 40 can be shared with the second manufacturer terminal 11 (s53, s53-1, s53-2).

6 is a flowchart illustrating a process of issuing a Connection DID according to an embodiment.

According to the embodiment, the connection DID is for connecting the manufacturer DID and the tester DID, and the app server 40 can transmit the manufacturer VC through the connection DID.

As shown in FIG. 6, the second manufacturer's terminal 11 can check whether the DID has already been issued by driving the electronic wallet app (s61). If it is issued, it goes to step s62, and if it is not issued, it can be stored in the electronic wallet along with the private key after issuing the DID.

According to the embodiment, the second manufacturer's terminal 11 may acquire a two-dimensional code (eg> bar code, QR code) for issuing a connection DID from the first manufacturer's terminal 10 (s62). Specifically, the second manufacturer's terminal 11 can be obtained by scanning the two-dimensional code output on the first manufacturer's terminal 10 using an app. However, this is just one embodiment, and the present invention can be equally/similarly applied to the case of obtaining a 2D code through another path, such as obtaining a 2D code by scanning a 2D code located on an offline paper document.

The second manufacturer terminal 11 may transmit a signal requesting a connection between the manufacturer DID and the tester DID to the app server 40 using the acquired 2D code (s63).

The connection DID issuing unit 42 of the app server 40 may refer to the connection request signal received from the second manufacturer terminal 11 to issue a connection DID and transmit the connection DID to the second manufacturer terminal 11 (s64 , s64-1). Then, the second manufacturer terminal 11 may store the connection DID in the electronic wallet. And, the app server 40 may record the connection DID on the second blockchain network N3 (s64-2). According to the embodiment, a separate database server (not shown) participates as a node in the second blockchain network (N3), and the manufacturer DID, tester DID, and/or connection DID are also stored and stored in the database server (not shown). It can be.

7 is a flowchart illustrating a process of registering a test report and issuing a manufacturer VC during the operation of the test report validation system 1 based on a blockchain network according to an embodiment.

As shown in FIG. 7 , the first manufacturer's terminal 10 may receive a test acceptance request from the user and transmit the request to the web server 30 (S71). Specifically, a manufacturer requiring a test report may request a test application by transmitting a test reception request signal to the web server 30 through the first manufacturer terminal 10 . For reference, in the present invention, a test may mean a test for performance or quality of a product.

When the tester terminal 20 that has received the test reception request through the web server 30 reviews the requirements of the first manufacturer's terminal 10 and/or the suitability of the test request details, etc., and satisfies predetermined conditions An approval signal for taking the test may be transmitted to the web server 30 (s72).

According to the embodiment, the tester's terminal 20 transmits a request signal for transmission of matters necessary for the test, such as test subjects, test environments, and important matters such as the scope of application of the test, as submissions to the first manufacturer's terminal through the web server 30. (10) can be sent. Correspondingly, the first manufacturer terminal 10 may submit submissions through the web server 30 . Submissions according to embodiments may include test environments such as codes, compilers, and operating systems, or test cases for test execution.

Examiners can design test plans, conduct tests, and analyze test results in consideration of submissions, size or complexity of test subjects, and test schedules. In addition, the tester terminal 20 may issue an original test report based on a result of analyzing the test result.

According to the embodiment, the original test report may be stored as document data to form a document in electronic form. For example, it may include content data such as text/image to be displayed to the viewer, and metadata related to the test report although not displayed to the viewer (eg> date and time of issue of the test report, issuing subject information, etc.).

According to the embodiment, the test report may include all of various forms stored in the form of a file, and may be issued in the form of a document having a format such as PDF, HWP, or WORD, for example.

When the original test report issued by the tester terminal 20 is registered with the web server 30 (s73), the web server 30 sends a confirmation request signal for the registered original test report to the first manufacturer terminal 10. and the first manufacturer terminal 10 may transmit a confirmation completion signal for the original test report to the web server 30 (s74, s75).

According to the embodiment, the test report management unit 31 of the web server 30 may insert a two-dimensional code such as a QR code or a barcode into the original test report that has been confirmed (s76). According to an embodiment, the two-dimensional code may include information such as test company DID, manufacturer DID, and product serial number.

The web server 30 transmits the original test report with the two-dimensional code inserted to the tester terminal 20 (s76-1), and the tester's terminal 20 transmits the original test report with the received two-dimensional code inserted. A final confirmation completion signal may be transmitted to the web server 30 (s77).

Then, the web server 30 may transmit the original test report in which the final confirmed two-dimensional code is inserted to the first manufacturer's terminal 10 and/or the tester's terminal 20 (s77-1).

Also, according to an embodiment, the web server 30 may generate a first hash value based on content data and/or metadata of the original test report. The generation of the first hash value can be generated by various known algorithms such as SHA (Secure Hash Algorithm).

The blockchain interlocking unit 33 of the web server 30 provides the hash value (first hash value) of the original test report, the main information of the test report, the two-dimensional code value (first code value), and/or the uniqueness of the original test report. The value can be recorded on the first block chain network (N2) (s78).

For example, referring to FIGS. 11 to 14, each node of the first block chain network (N2) stores the information of each node in a block ledger to create a block, and other associated blocks connected to the block chain. By transmitting the generated block through consensus among nodes, a plurality of remaining nodes can have the same block.

Each block according to the embodiment is composed of a header, body data, and metadata, and the header includes a block number, a hash value of the previous block header, a hash value of the current block header, etc., and the body data is the hash value of the original test report. , unique value of original test report, 2D code value, main information, etc., and metadata may include ID, block writing time, author's signature, etc. In particular, according to the embodiment, the main information of the test report included in the body data may include at least one of the test report field, test report number, issuance date, test manager, technical manager, test specification, and product name.

According to the present invention, in this way, the first manufacturer's terminal 10 and the tester's terminal 20 go through the process of receiving a test and registering a test report through the web server 30, so that each terminal through the website The operation of the user interface is easier, and each result can be checked and managed with reliability.

The VC issuance request unit 34 of the web server 30 may transmit a manufacturer VC generation request signal to the app server 40 (s79). According to the embodiment, the hash value (first hash value) of the original test report and the main information of the test report may be included in the manufacturer VC generation request signal and transmitted to the app server 40 . Then, the VC issuing unit 43 of the app server 40 may issue the manufacturer VC according to the request. According to another embodiment, the manufacturer VC may be issued by directly receiving the manufacturer VC creation request signal from the first manufacturer terminal 10 in the app server 40 .

According to the embodiment, the manufacturer VC may be prepared to include the hash value (first hash value) of the original test report, main information of the test report, manufacturer DID, and/or test company DID.

According to the embodiment, the first hash value and the main information of the test report are received from the web server 30, the manufacturer DID refers to the DID document generated through the process of FIG. Manufacturer VC can be created using what is stored in .

The VC issuing unit 43 records the issued manufacturer VC on the second blockchain network N3 using the connection DID issued through the process of FIG. 6 (s79-1), and accordingly, the second manufacturer terminal ( 11) can also store the manufacturer VC in the electronic wallet, and as shown in FIG. 4, the manufacturer DID, connection DID, and manufacturer VC can be stored together in the electronic wallet.

According to the embodiment, the VC issuing unit 43 may further record the VC ID corresponding to the issued manufacturer VC on the second blockchain network N3. Then, the node on the second blockchain network (N3) can verify the signature of the VC ID storage request transaction, record the VC ID in the blockchain to correspond to the manufacturer DID, and TXID (transaction ID) corresponding to the VC ID may be transmitted to the app server 40. According to the embodiment, the corresponding TXID can be used later to determine whether or not the VC ID has been stored in the second blockchain network (N3) or to search for the VC ID in the second blockchain network (N3).

8 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validity verification system 1 based on a blockchain network according to an embodiment.

As shown in FIG. 8 , the second manufacturer's terminal 11 can acquire a two-dimensional code of a test report (hereinafter referred to as a test report to be compared) to be inquired from the first manufacturer's terminal 10. (s81).

For reference, in FIG. 8 , the test report to be compared can be defined as being subject to validation in response to the issued original test report.

According to the embodiment, the second manufacturer's terminal 11 can be acquired by scanning the two-dimensional code of the test report to be compared on the web page output on the first manufacturer's terminal 10 using an app.

Specifically, the first manufacturer's terminal 10 may receive the original test report in which the two-dimensional code is inserted from the web server 30 through the process s77-1 of FIG. The test report to be compared, which is the subject of verification, is output on the web page, and the second manufacturer's terminal 11 scans the 2D code of the test report to be compared, thereby acquiring the 2D code.

Meanwhile, according to another embodiment, the second manufacturer's terminal 11 may acquire a two-dimensional code by scanning a test report to be compared, in which an original test report is printed and becomes a subject of validity verification.

The second manufacturer's terminal 11 may include the acquired two-dimensional code in a validity verification request signal for the test report to be compared and transmit it to the app server 40 (s82).

Upon receiving the validation request signal from the second manufacturer terminal 11, the code value management unit 44 of the app server 40 may extract the code value (second code value) of the received 2D code (s83 ).

Specifically, the app server 40 may determine whether the second manufacturer's terminal 11 is a verified user, and extract a second code value when it is determined that the second manufacturer's terminal 11 is a verified user.

According to an embodiment, whether the user is verified may be determined by determining whether the user has the manufacturer VC described above in FIG. 7 .

For reference, FIG. 8 illustrates that the second code value is generated by the app server 40. According to another embodiment, when the first manufacturer terminal 10 and/or the second manufacturer terminal 11 generate the second code value, the app server 40 may receive the second code value therefrom.

The code value management unit 44 may include the second code value in the validity verification request signal of the test report to be compared and transmit it to the first blockchain network N2 (s84).

Then, the first block chain network N2 may compare the first code value recorded in the block with the received second code value (s85).

Specifically, referring to FIG. 13, in the first blockchain network N2, the first code value of the original test report corresponding to the test report to be compared included in the validation request signal can be derived and compared with the second code value. there is.

If it is determined that they are the same as a result of code value comparison, it is determined that the test report to be compared is valid, and main information of the test report recorded in the block can be transmitted to the second manufacturer terminal 11 (s86). On the other hand, if it is determined that they are not identical as a result of the comparison, it is determined that the test report to be compared is forged and falsified, and an error message indicating that the test report has not been issued by the test company can be transmitted to the second manufacturer terminal 11 (s86-1).

Meanwhile, in FIG. 8, the validation result is directly transmitted from the first blockchain network N2 to the second manufacturer terminal 11, but according to another embodiment, the validation result is sent to the app server 40 first. and may be transmitted from the app server 40 to the second manufacturer terminal 11.

9 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validity verification system 1 based on a blockchain network according to another embodiment.

As shown in FIG. 9 , the first manufacturer's terminal 10 may transmit the comparison target test report to the second manufacturer's terminal 11 (s91).

For reference, in FIG. 9 , the test report to be compared can be defined as being subject to validation in response to the issued original test report.

Specifically, the first manufacturer terminal 10 may receive the original test report from the web server 30 through the process s77-1 of FIG. The test report may be transmitted to the second manufacturer terminal 11 .

Meanwhile, according to another embodiment, the second manufacturer's terminal 11 may acquire the original test report by scanning a test report to be compared, which has been printed and is subject to validity verification.

The second manufacturer terminal 11 may include the comparison target test report in the validity verification request signal and transmit it to the app server 40 (s92).

Upon receiving the validation request signal from the second manufacturer terminal 11, the hash value management unit 45 of the app server 40 may extract the second hash value of the received test report to be compared (s93).

Specifically, the app server 40 may determine whether the second manufacturer's terminal 11 is a verified user, and extract a second hash value when it is determined that the second manufacturer's terminal 11 is a verified user.

According to an embodiment, whether the user is verified may be determined by determining whether the user has the manufacturer VC described above in FIG. 7 .

For reference, FIG. 9 illustrates that the second hash value is generated by the app server 40. According to another embodiment, when the second hash value is generated in the first manufacturer terminal 10 and/or the second manufacturer terminal 11, the second hash value may be received from the app server 40.

The hash value management unit 45 may transmit the second hash value to the first blockchain network N2 by including the second hash value in the validity verification request signal of the test report to be compared (s94).

Then, the first blockchain network N2 may compare the first hash value recorded in the block with the received second hash value (s95).

Specifically, referring to FIG. 13, in the first blockchain network N2, the first hash value of the original test report corresponding to the test report to be compared included in the validation request signal can be derived and compared with the second hash value. there is.

If it is determined that they are the same as a result of hash value comparison, it is determined that the test report to be compared is valid, and main information of the test report recorded in the block can be transmitted to the second manufacturer terminal 11 (s96). On the other hand, if it is determined that they are not identical as a result of the comparison, it is determined that the test report to be compared is forged and falsified, and an error message indicating that the test report has not been issued by the test company can be transmitted to the second manufacturer terminal 11 (s96-1).

Meanwhile, FIG. 9 illustrates that the validation result is directly transmitted from the first blockchain network N2 to the second manufacturer terminal 11, but according to another embodiment, the validation result is sent to the app server 40 first. and may be transmitted from the app server 40 to the second manufacturer terminal 11.

10 is a flowchart illustrating a test report forgery/falsification inquiry process during the operation of the test report validity verification system 1 based on a blockchain network according to another embodiment.

As shown in FIG. 10, the first manufacturer's terminal 10 and/or the tester's terminal 20 include the test report to be inquired (hereinafter, described as a test report to be compared) in the validity verification request, and the web It can be uploaded to the server 30 (s101).

For reference, in FIG. 10 , the test report to be compared may be defined as being uploaded for validation in response to the issued original test report.

The extraction unit 32 of the web server 30 may extract the hash value (second hash value) of the test report to be compared (s102).

According to an embodiment, the extraction unit 32 may generate a second hash value based on content data and/or metadata of a test report to be compared. The generation of the second hash value can be generated by various known algorithms such as SHA (Secure Hash Algorithm).

For reference, although FIG. 10 illustrates that the second hash value is generated by the web server 30, according to another embodiment, the second hash value is generated by the first manufacturer terminal 10 and/or the tester terminal 20. After generating, when the test report to be compared is uploaded to the web server 30, a second hash value may be extracted therefrom.

The blockchain interlocking unit 33 of the web server 30 may transmit the second hash value to the first blockchain network N2 by including the second hash value in the validity verification request signal of the test report to be compared (s103).

Then, the first blockchain network N2 may compare the first hash value recorded in the block with the received second hash value (s104).

Specifically, referring to FIG. 12, in the first blockchain network N2, the first hash value of the original test report corresponding to the test report to be compared included in the validation request signal can be derived and compared with the second hash value. there is.

If, as a result of hash value comparison, it is determined that they are the same, it is determined that the test report to be compared is valid and the main information of the test report recorded in the block can be transmitted to the first manufacturer terminal 10 and/or the tester terminal 20 (s105 ). On the other hand, if it is determined that they are not identical as a result of the comparison, it is determined that the test report to be compared is forged and falsified, and an error message indicating that the test report has not been issued by the test company is sent to the first manufacturer's terminal 10 and/or the test company's terminal 20. It can be transmitted (s105-1).

Meanwhile, in FIG. 10, the validation result is directly transmitted from the first blockchain network N2 to the first manufacturer terminal 10 and/or tester terminal 20, but according to another embodiment, validation The result is first transmitted to the web server 30, and may be transmitted from the web server 30 to the first manufacturer terminal 10 and/or the tester terminal 20 (s55-1).

According to the embodiment of the present invention, as shown in FIG. 8, the test report forgery inquiry using the two-dimensional code value is performed through the first blockchain network (N2) via the app server 40, and the hash value as shown in FIG. Forgery and alteration inquiry using the test report is performed through the web server 30 and the first blockchain network N2, so that the accuracy of the test report forgery inquiry result is higher and the security performance is further improved.

14 is a configuration diagram of a first blockchain network N2 according to an embodiment.

according to the embodiment. As shown in FIG. 14, the minimum number of nodes included in one first blockchain network N2 may be set and implemented. For example, the minimum number of nodes may be set to 4, but the scope of the present invention is not limited thereto.

Also, the number of active nodes and the number of standby nodes may be set in advance. For example, the number of active nodes may be set to three and the standby node may be set to one, but the scope of the present invention is not limited thereto.

In the case of FIG. 14, only 3 active nodes usually process the consensus process while creating a block ledger, and the remaining 1 standby node is in a standby state. If some of the active nodes fail, they immediately agree on behalf of the failed node. You can participate in the processing of the process.

Features, structures, effects, etc. described in the embodiments above are included in one embodiment of the present invention, and are not necessarily limited to only one embodiment. Furthermore, the features, structures, and effects illustrated in each embodiment can be combined or modified with respect to other embodiments by those skilled in the art in the field to which the embodiments belong. Therefore, contents related to these combinations and variations should be construed as being included in the scope of the present invention.

In addition, although the above has been described with a focus on the embodiments, these are only examples and do not limit the present invention, and those skilled in the art to which the present invention belongs can exemplify the above to the extent that does not deviate from the essential characteristics of the present embodiment. It will be seen that various variations and applications that have not been made are possible. For example, each component specifically shown in the embodiment can be modified and implemented. And differences related to these modifications and applications should be construed as being included in the scope of the present invention as defined in the appended claims.

Claims (7)

An app server that issues a manufacturer VC related to the manufacturer's original test report and records the issued manufacturer VC on a second blockchain network; and
A second manufacturer terminal that obtains the manufacturer VC through the second blockchain network and transmits a two-dimensional code of a test report to be compared to the original test report corresponding to the original test report to the app server;
The app server extracts the second code value of the two-dimensional code received from the second manufacturer terminal, and sends a request for validation of the comparison target test report including the extracted second code value to the first block chain. send over the network,
The second manufacturer terminal receives, from the first blockchain network, a validation result of the test report to be compared based on the second code value performed through the first blockchain network.
Validation system for test report based on blockchain network for identity authentication.
According to claim 1,
The second manufacturer's terminal,
If it is determined that the validity of the comparison target test report performed through the first blockchain network is valid, the main information of the original test report is received from the first blockchain network, and if it is determined to be invalid, an error message is sent. Received from the first blockchain network,
Validation system for test report based on blockchain network for identity authentication.
According to claim 1,
The manufacturer VC includes at least one of a manufacturer DID, a tester DID, main information of the original test report, and a hash value.
Validation system for test report based on blockchain network for identity authentication.
According to claim 3,
The app server further issues a connection DID for connecting the manufacturer DID and the tester DID.
Validation system for test report based on blockchain network for identity authentication.
According to claim 1,
a first manufacturer's terminal; and
A second hash value of the test report to be compared uploaded from the first manufacturer terminal is extracted, and a validity verification request of the uploaded test report to be compared including the extracted second hash value is sent to the first blockchain network. It further includes; a web server that transmits to
The first manufacturer terminal receives, from the first blockchain network, a validation result of the uploaded test report to be compared based on the second hash value performed through the first blockchain network.
Validation system for test report based on blockchain network for identity authentication.
According to claim 5,
The first manufacturer's terminal,
If it is judged to be valid as a result of the validity verification of the uploaded comparison target test report performed through the first blockchain network, the main information of the original test report is received from the first blockchain network, and if it is determined to be invalid, an error occurs. Receiving a message from the first blockchain network,
Validation system for test report based on blockchain network for identity authentication.
According to claim 6,
The web server,
Recording at least one of the first hash value, the first code value, and the main information of the original test report on the first blockchain network,
Validation system for test report based on blockchain network for identity authentication.

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