KR102183582B1 - Block Chain Solution Providing System to Ensure Data Integrity of Private Data-set, and Process Method thereof - Google Patents

Abstract

The present invention relates to a system for providing a blockchain solution for guaranteeing data integrity of a private data set, and a processing method thereof. The present invention includes a first step of transmitting, by the IoT device 100, sensor data as IoT data when a preset event occurs or periodically to the IoT gateway 300; A second step of calculating a hash of the IoT data previously received by the IoT gateway 300 upon receiving data from the IoT device 100; Sensor data delivered to the IoT gateway 300 by itself by transmitting the hash of the IoT data transmitted by the IoT device 100 to the smart contract module 200 at a predetermined time A third step of providing a transmission report for IoT data transmission that may correspond to; A fourth step in which the smart contract module 200 notifies the IoT gateway 300 that a transmission report sent to itself is stored; And the IoT gateway 300 checks the transmission report, and if the hash of the IoT data on the transmission report and the hash of the IoT data calculated in the second step are the same, the IoT data is placed in a process queue. A fifth step of allowing additional data filtering to be performed by putting it in It characterized in that it comprises a.
Thereby, persistent supply chain data logging to ensure the integrity of IoT data arriving indeed from IoT devices and being processed by AI machines. Provides possible effects. In addition, the present invention provides a remediation service by detecting a failure of an IoT device and an IoT gateway, and provides an effect of preventing DDoS attacks occurring in the IoT device and IoT gateway.

Description

Block Chain Solution Providing System to Ensure Data Integrity of Private Data-set, and Process Method thereof}

The present invention relates to a system for providing a blockchain solution for ensuring data integrity of private data sets, and a processing method thereof, and more specifically, that IoT data from an IoT device arrives indeed and is processed in an AI machine. Blockchain solution provision system to ensure data integrity of private datasets to enable persistent supply chain data logging to ensure the integrity of the data, and its objection. It relates to the treatment method.

The advent of decentralized transaction systems such as Bitcoin provided the Internet with a reliable and secure protocol for recording ownership through digital values known as blockchains. The system is based on a private key that enables a person to exercise such digital values. However, when such keys are stored digitally, and especially when such keys are transacted, these keys are susceptible to theft, which can cause substantial loss. The industry has anticipated the need for high guaranteed operation in endpoint devices over the years. Hardware security that has already been utilized can be used to enhance the security and privacy of interactions between people and the blockchain.

Korean Patent Application Application No. 10-2017-0014325

The present invention is to solve the above problem, in order to ensure the integrity of IoT data from IoT devices to arrive indeed and processed in AI machines, a persistent supply chain ( supply chain) It is to provide a system for providing a blockchain solution to ensure data integrity of private datasets to enable data logging, and a processing method thereof.

In addition, the present invention can provide a remediation service by detecting a failure of an IoT device and an IoT gateway, and ensure data integrity of a private dataset to prevent DDoS attacks occurring in the IoT device and IoT gateway. It is to provide a system for providing a blockchain solution for and a method of handling it.

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

In order to achieve the above object, the method of processing a block chain for guaranteeing data integrity of a private data set according to an embodiment of the present invention, when the IoT device 100 generates an event set in advance as the IoT gateway 300 or A first step of periodically transmitting sensor data as IoT data; A second step of calculating a hash of the IoT data previously received by the IoT gateway 300 upon receiving data from the IoT device 100; Sensor data delivered to the IoT gateway 300 by itself by transmitting the hash of the IoT data transmitted by the IoT device 100 to the smart contract module 200 at a predetermined time A third step of providing a transmission report for IoT data transmission that may correspond to; A fourth step in which the smart contract module 200 notifies the IoT gateway 300 that a transmission report sent to itself is stored; And the IoT gateway 300 checks the transmission report, and if the hash of the IoT data on the transmission report and the hash of the IoT data calculated in the second step are the same, the IoT data is placed in a process queue. A fifth step of allowing additional data filtering to be performed by putting it in It characterized in that it comprises a.

At this time, after the fifth step, the IoT gateway 300 transmits the queue_id of the data put in the processor queue in the fifth step to the smart contract module 200 , A sixth step of indicating that IoT data is ready to be filtered by the IoT gateway 300; It characterized in that it further comprises.

In addition, the transmission report in the third step is characterized in that it includes time information (timer) to indicate the expiry period (expiry).

Blockchain solution providing system for guaranteeing data integrity of private datasets according to an embodiment of the present invention, and a processing method thereof, is the integrity of IoT data arriving from IoT devices as indeed and being processed by AI machines ( In order to ensure integrity, persistent supply chain data logging is possible.

In addition, the system for providing a blockchain solution for guaranteeing data integrity of a private data set according to another embodiment of the present invention, and a processing method thereof, detects a failure of an IoT device and an IoT gateway to provide a remediation service. It provides an effect to prevent DDoS attacks occurring in IoT devices and IoT gateways.

FIG. 1 is a diagram illustrating an Architectural Data Flow of AI System, which is the basis of a system for providing a blockchain solution (1) for ensuring data integrity of a private data set according to an embodiment of the present invention.
2 is a diagram illustrating a system 1 for providing a blockchain solution for guaranteeing data integrity of a private data set according to an embodiment of the present invention.
3 is a block diagram showing a data store unit of a block chain registered in a smart contract module 200 in the system 1 for ensuring data integrity of a private data set according to an embodiment of the present invention. It is a drawing.
4 is an example of an IoT data set supply chain registered in a smart contract module 200 in the blockchain solution providing system 1 for ensuring data integrity of a public data set according to an embodiment of the present invention. It is a drawing showing.
5 is a flowchart illustrating a block chain processing method for ensuring data integrity of a private data set according to an embodiment of the present invention.

Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In the present specification, when one component'transmits' data or a signal to another component, the component can directly transmit the data or signal to another component, and through at least one other component It means that data or signals can be transmitted to other components.

FIG. 1 is a diagram illustrating an Architectural Data Flow of AI System, which is the basis of a system for providing a blockchain solution (1) for ensuring data integrity of a private data set according to an embodiment of the present invention. Referring to FIG. 1, a dataset in the present invention may include public datasets such as YouTube, Facebook, and government data, and private datasets, which are personal data manually collected from various IoT devices.

Accordingly, the data collector module 400 in the blockchain solution providing system 1 for guaranteeing the data integrity of the private data set according to the embodiment of the present invention is the IoT gateway 300 for the private data set. Through this, data normalization and distribution of training tasks can be provided to an AI system, and a dataset can be provided to batch process training data in parallel with an AI system corresponding to the data center.

2 is a diagram illustrating a system 1 for providing a blockchain solution for guaranteeing data integrity of a private data set according to an embodiment of the present invention. 3 is a block diagram showing a data store unit of a block chain registered in a smart contract module 200 in the system 1 for ensuring data integrity of a private data set according to an embodiment of the present invention. It is a drawing. 4 is an example of an IoT data set supply chain registered in a smart contract module 200 in the blockchain solution providing system 1 for ensuring data integrity of a public data set according to an embodiment of the present invention. It is a drawing showing.

Referring to FIG. 2, a blockchain solution providing system 1 for ensuring data integrity of a private data set includes an IoT device 100, a smart contract module 200, an IoT gateway ( 300) and a data collector module 400.

The IoT device 100 transmits sensor data as IoT data when a preset event occurs or periodically to the IoT gateway 300, thereby providing data from the IoT device 100 by the IoT gateway 300. Upon reception, a hash of IoT data can be calculated.

In addition, at a given time set in advance, the IoT device 100 transmits the hash of the transmitted IoT data to the smart contract module 200, thereby delivering it to the IoT gateway 300. It is possible to provide a transmission report for IoT data transmission that may correspond to sensor data, and it is preferable that the transmission report include time information to indicate an expiry.

Data (Permissioned-ledger) registered in the smart contract module 200 corresponding to the blockchain network is IoT_device_public key, IoT_gateway_public key (public key), as shown in FIG. key), data collection module public key, queue_id, training_id, training_id_timestamp, IoT_data_hash, IoT_filtering_data_hash It may include.

IoT_device_public key is the public key of the IoT device in the system, IoT_gateway_public key is the public key of the IoT gateway in the system,

The data collection module public key is the public key of the AI-based data collection module 400 that relays communication to the training machine in the data center, and the queue_id is IoT. It is an identifier (id) used to indicate that the data has been well received from the gateway and is ready to be filtered/aggregated for future data processing, and the training_id is the batch training process. For this purpose, it is an identifier (id) used to notify that data has already been sent to the AI-based data collection module 400, and the training_id_timestamp is the time when the queue_id is inserted into the blockchain. Is a timestamp of, IoT_data_hash is a hash of data sent from IoT devices to IoT gateway, and IoT_filtering_data_hash is filtered/collected sent to the data collection module 400 It means a hash of aggregated IoT data.

And, examples of the IoT dataset supply chain registered in the smart contract module 200 are IoT_data_hash, queue_id, oT_filtering_data_hash, and training_id. Can be expressed as shown in FIG. 4.

On the other hand, the smart contract module 200 is transmitted by the IoT gateway 300 by notifying that the transmission report that has been sent to the IoT gateway 300 is stored. Check the report, and if the hash of the IoT data in the transmission report and the hash of the IoT data calculated by the IoT gateway 300 are the same, additional data filtering by putting the IoT data in the process queue To be able to perform.

Accordingly, the IoT gateway 300 transmits the queue_id of the data put in the processor queue to the smart contract module 200 to indicate that IoT data is ready to be filtered. can do.

On the other hand, if the hash of the IoT data on the transmission report and the hash of the IoT data calculated by the IoT gateway 300 are not the same, the IoT gateway 300 does not need to respond to the report. This is because the IoT device 100 can automatically recognize that the report has been rejected when the timer of the transmission report transmitted from the smart contract module 200 ends.

Next, the IoT gateway 300 may filter IoT data received from the IoT device 100 and then transmit the filtered IoT data to the data collector module 400.

Accordingly, when the data collector module 400, which is an end point, calculates the hash of the received filtered IoT data, within the predetermined time, the IoT gateway 300 May report the hash of the filtered IoT data transmitted to the data collector module 400 to the smart contract module 200.

Accordingly, when the data collector module 400 receives notification about the report from the smart contract module 200, the hash of the filtered IoT data calculated by itself and the IoT gateway ( The report transmitted from the IoT gateway) 300 may be checked by comparing the hash of the filtered IoT data on the report received through the smart contact module 200.

If the hash is correct, the data collector module 400 inserts training_id into the filtered IoT data on the smart contact module 200. This indicates that the data collector module 400 has received data from the IoT device 100 and is ready for batch training. If the hash is wrong, the data collector module 400 does not need to respond, and the IoT gateway 300 includes timer information on the report, so when You can automatically know if this will expire.

Through this configuration, persistent supply chain data recording in order to ensure the integrity of IoT data arriving indeed from IoT device 100 and being processed by AI machine. Logging can provide possible effects.

Through such a system, it is possible to detect failures of the IoT device 100 and IoT gateway 300 in the future and provide a remediation service, and to prevent DDoS attacks occurring in the IoT device 100 and IoT gateway 300. I can.

5 is a flowchart illustrating a block chain processing method for ensuring data integrity of a private data set according to an embodiment of the present invention. Referring to FIG. 5, the IoT device 100 transmits sensor data as IoT data when a preset event occurs or periodically to the IoT gateway 300 (S11).

After step S11, upon receiving data from the IoT device 100, the IoT gateway 300 calculates a hash of the previously received IoT data (S12).

After step (S12), at a given time set in advance, the IoT device 100 transmits the hash of the transmitted IoT data to the smart contract module 200, so that it is an IoT gateway 300 A transmission report is provided for IoT data transmission that may correspond to the sensor data delivered to) (S13). It is preferable that the transmission report in step S13 includes time information to indicate the expiry.

After the step (S13), the smart contract module (Smart contract module) 200 performs a notification that the transmission report sent to the IoT gateway (IoT gateway) 300 is stored (S14).

After step S14, the IoT gateway 300 checks the transmission report, and if the hash of the IoT data on the transmission report and the hash of the IoT data calculated in step S12 are the same, process the IoT data. It is put in a queue (process queue) so that additional data filtering can be performed (S15).

After step S15, the IoT gateway 300 transmits the queue_id of the data put into the processor queue in step S15 to the smart contract module 200 (S16). ). Step S16 indicates that IoT data is ready to be filtered by the IoT gateway 300.

Meanwhile, if the hashes are not the same in step S15, the IoT gateway 300 does not need to respond to the report. The IoT device 100 may automatically recognize that the report has been rejected when the timer of the transmission report transmitted from the smart contract module 200 in step S13 is terminated.

After step S16, the IoT gateway 300 filters the IoT data received from the IoT device 100 and then transmits the filtered IoT data to the data collector module 400. Do (S17).

After step S17, the data collector module 400, which is an end point, calculates a hash of the received filtered IoT data (S18).

At a given time set in advance in step S13, the IoT gateway 300 converts the hash of the filtered IoT data transmitted to the data collector module 400 into a smart contract module. ) Report to (200) (S19). This report is similar to the process of step S13.

After the step (S19), the smart contract module (Smart contract module) 200 notifies the data collection module (Data collector module) 400 about the report of the step (S19) (S20).

After step S20, the data collector module 400 checks the report by comparing the hash of step S18 and step S19 (S21).

If the hash is correct, the data collector module 400 inserts training_id into the filtered IoT data on the smart contact module 200. This indicates that the data collector module 400 has received data from the IoT device 100 and is ready for batch training. If the hash is wrong, the data collector module 400 does not need to respond, and the IoT gateway 300 is similar to the above-described in step S16. timer), so you can automatically know when the report will time out.

The present invention can also be implemented as a computer-readable code on a computer-readable recording medium. The computer-readable recording medium includes all types of recording devices that store data that can be read by a computer system.

Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices, and are implemented in the form of carrier waves (for example, transmission through the Internet). Also includes.

In addition, the computer-readable recording medium is distributed over a computer system connected through a network, so that computer-readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers in the technical field to which the present invention belongs.

As described above, in the present specification and drawings, a preferred embodiment of the present invention has been disclosed, and although specific terms are used, this is only used in a general meaning to easily explain the technical content of the present invention and to aid understanding of the invention. , It is not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those of ordinary skill in the art that other modified examples based on the technical idea of the present invention may be implemented.

1: Blockchain solution providing system to ensure data integrity of private datasets
100: IoT device 100
200: Smart contract module
300: IoT gateway
400: Data collector module

Claims (3)

A first step of, by the IoT device 100, transmitting sensor data as IoT data when a preset event occurs or periodically to the IoT gateway 300;
A second step of calculating a hash of the IoT data previously received by the IoT gateway 300 upon receiving data from the IoT device 100;
Sensor data delivered to the IoT gateway 300 by itself by transmitting the hash of the IoT data transmitted by the IoT device 100 to the smart contract module 200 at a predetermined time A third step of providing a transmission report for IoT data transmission that may correspond to;
A fourth step in which the smart contract module 200 notifies the IoT gateway 300 that a transmission report sent to itself is stored; And
The IoT gateway 300 checks the transmission report, and if the hash of the IoT data on the transmission report and the hash of the IoT data calculated in the second step are the same, the IoT data is placed in a process queue. A fifth step of allowing additional data filtering to be performed;
After the fifth step,
The IoT gateway 300 transmits the queue_id of the data put in the processor queue in the fifth step to the smart contract module 200, and thus the IoT gateway ( A sixth step of indicating that IoT data is ready to be filtered by 300); Blockchain processing method for ensuring data integrity of a private dataset, characterized in that it further comprises.
delete The method according to claim 1,
The transmission report in the third step includes a timer to indicate an expiry. Blockchain processing method for guaranteeing data integrity of a private data set.

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