KR102564375B1 - BLOCKCHAIN BASED DISTRIBUTED QUANTUM NETWORK SYSTEM AND METHOD FOR IoT NETWORK - Google Patents

Abstract

The present invention relates to a blockchain-based distributed quantum network system for an IoT network, comprising: at least one client terminal for collecting data and generating a data processing request message including the data; an edge server that verifies the client terminal by inputting terminal information of the client terminal that generated the data processing request message and the data processing request message to a previously prepared block chain; and a quantum server that analyzes the data processing request message and performs a data processing request when the edge server completes verification of the client terminal. Through this, the blockchain-based distributed quantum network system for the IoT network provides desirable computational power and improved security in the IoT network environment.

Description

Blockchain-based distributed quantum network system and method for IoT network {BLOCKCHAIN BASED DISTRIBUTED QUANTUM NETWORK SYSTEM AND METHOD FOR IoT NETWORK}

The present invention relates to a blockchain-based distributed quantum network system and method for an IoT network, and more particularly, an IoT network for providing security measures and a secure server solution desired by the IoT network and performing efficient calculations on data. It is about a blockchain-based distributed quantum network system and method for

The field of the Internet of Things (IoT), a heterogeneous environment of interconnected objects, has grown exponentially due to the advent of 5G networks, artificial intelligence (AI) and blockchain technology.

These IoT devices of the IoT network are used in various industrial fields such as smart healthcare, smart industry, smart transportation and smart city, and industrial fields that use IoT devices collect data using IoT devices and use technology for data. to provide practical services to users.

For example, smart healthcare services use IoT wearable devices to collect biometric data and motion information about users in real time, and smart transportation services use IoT to support fast and efficient communication between vehicles.

However, IoT devices often have limited resources, so there are problems in that calculation and battery capacity are insufficient, and they are vulnerable to cyber attacks, and through these problems, personal information protection and confidentiality problems arise.

In addition, as the number of IoT devices gradually increases, the amount of data generated by the IoT devices also increases rapidly, resulting in a problem in that it is difficult to maintain resources of a cloud server storing data generated by the IoT devices.

In addition, the data storage of the cloud server continuously stores large amounts of data that require fast and efficient calculations, but there is not enough storage space to resource such large amounts of data, so there is a problem that storage-related failures will occur in the data storage in the near future. do.

Therefore, quantum information technology and quantum computers are perfect solutions to these problems. They maintain safe calculations quickly and efficiently to improve the Quality of Service and Quality of Experience, and to improve the security of IoT devices. and personal information collected by IoT devices.

There is a problem that implementation of such a quantum computer is possible only in a university laboratory and a laboratory of a specialized institution, and a problem in that cost increases exponentially due to complicated calculation and low maintainability.

Therefore, it is necessary to research and develop a system in which IoT devices can easily access the quantum cloud without a quantum machine and perform all types of calculations required by authorized clients in the quantum cloud.

(Korea) Patent Registration No. 10-2315725

The present invention has been made to solve the above problems, and an object of the present invention is a block chain for an IoT network that provides desirable computing power and improved security in an IoT network environment through a block chain, a virtual quantum machine, and an edge layer. It is to provide a based distributed quantum network system and method.

A blockchain-based distributed quantum network system for an IoT network according to an embodiment of the present invention for achieving the above object includes at least one client terminal for collecting data and generating a data processing request message including the data; an edge server that verifies the client terminal by inputting terminal information of the client terminal that generated the data processing request message and the data processing request message to a previously prepared block chain; and a quantum server that analyzes the data processing request message and performs a data processing request when the edge server completes verification of the client terminal.

In this regard, the edge server sets any one client terminal among the at least one client terminal existing in the blockchain as a verification authority node, and transmits the terminal information to the verification authority node to determine the client terminal However, if it is determined that the client terminal is a terminal authenticated in advance, a root role is assigned to the verification authority node to perform message broadcasting until a previously set round, and the verification authority node performs message broadcasting through the message broadcast. The client terminal may be verified by comparing different results displayed by .

In addition, when the verification of the client terminal is completed, the edge server inputs the data processing request message to a virtual quantum machine prepared in advance to convert it into qubits, and Q-OTP to the data processing request message converted into qubits Quantum-based encryption can be performed by applying .

Accordingly, the quantum server may access the data processing request message delivered by the edge server through delegated quantum computing, and perform and store the data processing request of the terminal of the client calculated through the access.

On the other hand, a blockchain-based distributed quantum network method according to another embodiment of the present invention is performed in a blockchain-based distributed quantum network system for an IoT network, wherein at least one client terminal collects data and includes the data generating a data processing request message; verifying the client terminal by inputting, by an edge server, terminal information of the client terminal that generated the data processing request message and the data processing request message to a previously prepared block chain; and performing, by the quantum server, a data processing request by analyzing the data processing request message when verification of the client terminal is completed in the edge server.

According to one aspect of the present invention described above, by providing a blockchain-based distributed quantum network system and method for an IoT network, it is possible to improve computational power and security in an IoT environment.

In addition, by providing a blockchain-based distributed quantum network system and method for an IoT network, it is possible to reduce the need to have a quantum machine on the client terminal side and provide secure access between the client terminal and the cloud server.

In addition, by providing a blockchain-based distributed quantum network system and method for IoT networks, complex requests from client terminals can be calculated while maintaining data and security.

1 is an exemplary diagram of a blockchain-based distributed quantum network system for an IoT network according to an embodiment of the present invention.
2 is an exemplary diagram of a process in which the edge server of FIG. 1 performs authentication of a client terminal using a blockchain.
FIG. 3 is an exemplary diagram of a virtual quantum machine provided in the edge server of FIG. 1 .
FIG. 4 is a diagram of instructions for the virtual quantum machine of FIG. 3 to convert data into qubits and encode them into gates.
5 to 11 are gate protocol diagrams of FIG. 4 .
12 is an exemplary diagram visualizing Q-OTP.
13 is an algorithm diagram of a process in which the edge server of FIG. 2 performs authentication of a client device.
14 and 15 are algorithm diagrams of a process of encoding to a gate by the virtual quantum machine of FIG. 3 .
16 is a flow diagram of a blockchain-based distributed quantum network method according to another embodiment of the present invention.

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 another embodiment without departing from the spirit and scope of the invention in connection with one embodiment. 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.

In addition, the features and advantages of the present invention will become more clear with the detailed description based on the accompanying drawings, and the terms or words used in this specification and claims are conventional and should not be interpreted in a dictionary sense, and the inventors Based on the principle that the concept of terminology can be properly defined in order to explain one's invention in the best way, it should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

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

1 is an exemplary diagram of a blockchain-based distributed quantum network system for an IoT network according to an embodiment of the present invention, and FIGS. 2 and 3 show the edge server of FIG. 1 performing authentication of a client terminal using a blockchain. It is an example diagram of a virtual quantum machine provided in the process and edge server, and FIG. 4 is a diagram of instructions for the virtual quantum machine of FIG. 3 to convert data into qubits and encode them in gates.

5 to 11 are diagrams of the gate protocol of FIG. 4 , and FIGS. 13 to 15 are diagrams of algorithms performed in the blockchain-based distributed quantum network system for the IoT network of FIG. 1 .

Referring to FIG. 1, a blockchain-based distributed quantum network system 10 for an IoT network includes a terminal layer 11 in which at least one client terminal 111 is provided, and at least one existing in a preset distance interval. Consists of an edge layer 13 provided with a plurality of edge servers 131 communicating with the client terminal 111 and a cloud layer 15 provided with a quantum server 155 communicating with the plurality of edge servers 131 do.

These at least one client terminal 111 and the edge server 131 and the quantum server 155 may communicate through a network. A network refers to a connection structure capable of exchanging information between nodes such as terminals and servers, and these networks include the Internet, Wireless LAN (Wireless Local Area Network), WAN (Wide Area Network), and PAN. (Personal Area Network), 3G, 5G, LTE (Long Term Evolution), WiFi (Wireless Fidelity), WiMAX (World Interoperability for Microwave Access), WiGig (Wireless gigabit), etc. are included, but are not limited thereto.

On the other hand, at least one client terminal 111 may be provided with a wireless communication device, an unmanned aerial vehicle (UAV), a closed-circuit television (CCTV) of a smart factory, and the like, which ensure portability and mobility, and such a wireless communication device PCS(Personal Communication System), GSM(Global System for Mobile communications), PDC(Personal Digital Celluar), PHS(Personal Handyphone System), PDA(Personal Digital Assistant), IMT(International Mobile Telecommunication)-2000, CDMA(Code Division) Multiple Access)-2000, W-CDMA (W-Code Division Multiple Access), Wibro (Wireless Broadband Internet) terminal, smartphone, smartpad, tablet PC, VR (Virtual Reality) device, HMD ( All types of handheld-based wireless communication devices such as Head Mounted Display) may be included, but are not limited thereto, and each other depending on the field to which the blockchain-based distributed quantum network system 10 for the IoT network is applied. It may be provided with other wireless communication devices or devices capable of communication such as UAVs and CCTVs.

In this regard, the blockchain-based distributed quantum network system 10 for the IoT network may set at least one client terminal 111 existing at a preset distance interval as one cluster.

In addition, the blockchain-based distributed quantum network system 10 for the IoT network exists in a cluster, and a base station, that is, a base station, is provided to any one client terminal 111 that has been authenticated as a reliable client terminal 111 in advance. It is possible to manage different client terminals 111 existing in the cluster by assigning a role of .

In addition, the blockchain-based distributed quantum network system 10 for the IoT network combines and inputs the client terminal 111 assigned to the base station in each cluster to the blockchain provided in the edge server 131, so that each client Authentication of the terminal 111 may be performed or communication with the client terminal 111 may be performed.

Such at least one client terminal 111 collects data and generates a data processing request message including the data.

Here, the data collected by at least one client terminal 111 is information or records collected by each client terminal 111 according to a user's command, and this information or record is IoT raw data, which is very sensitive and personalized. Data that requires higher security measures to generate information.

Accordingly, at least one client terminal 111 may generate a data processing request message including its own terminal information and collected data, and transmit the generated data processing request message to the edge server 131 .

Referring to FIG. 2 , the edge server 131 transmits a data processing request message from any one client terminal 111 present in a cluster managed by the edge server 131, and the client terminal 111 that generated the data processing request message The client terminal 111 is verified by inputting the terminal information and the data processing request message to a previously prepared block chain.

More specifically, the edge server 131 may transmit terminal information to a verification authority node existing in the blockchain 1311 to verify whether the client terminal 111 is a safe and verified terminal. Here, the verification authority node refers to the client terminal 111 assigned the base station role of managing the above-described different client terminals 111, and will be described below as a verification authority node.

The edge server 131 may check whether the client terminal 111 that has transmitted the data processing request message through the blockchain-based Practical Byzantine Fault Tolerance algorithm is the client terminal 111 connected to the blockchain 1311 in advance.

Subsequently, when any one client device 111 present in the cluster generates and transmits a data processing request message, the edge server 131 sends the terminal of the client device 111 to the confirmation authority node that verifies the client device 111. You can send a confirmation request containing information.

At this time, the verification authority node verifies the corresponding client terminal 111 through the client ID stored in the terminal information of the client terminal 111, and if the client ID is the same as the client terminal 111 that generated the data processing request message, the confirmation An authentication message for the request may be delivered to the edge server 131 .

Accordingly, the edge server 131 checks the identity of the client terminal 111 that generated and delivered the data processing request message through the authentication message transmitted from the verification authority node and the client ID included in the terminal information, and when the verification is completed, In this case, the root role can be further assigned to the verification authority node that has delivered the authentication message, and message broadcasting can be performed up to a preset round.

Here, the verification authority node delivers the message to all client terminals 111 connected to the verification authority node up to a preset round, and among all client terminals 111, the client terminal 111 that generated the data processing request message sends the message A result message may be transmitted up to a preset round.

Through this, when the confirmation authority node reaches a pre-set round, it can be transformed into a commit state and display the result generated through message broadcasting as the number of messages delivered to all client terminals 111 .

In addition, the verification authority node counts the number of result messages transmitted by the client terminal 111 that generated the data processing request message up to round 2f + 1, and the result generated by broadcasting the number of messages and the commit status as a result of the counting The number of messages may be transmitted to the edge server 131.

Through this, the edge server 131 compares the number of result messages transmitted from the verification authority node with the number of messages generated by broadcasting the commit status of the repository of the verification authority node, and transfers the data processing request message to the client terminal 111 ) can verify whether the client terminal 111 exists in the previously prepared block chain. At this time, the edge server 131 may omit the data processing request message transmitted from the client terminal 111 when the number of different messages is not the same through comparison.

As a result, the blockchain-based quantum network system 10 for the IoT network is safe, and only the authenticated client terminal 111 is set as part of the system to provide the protection desired by the user using the client terminal 111, Only honest, verified users can use the system, enhancing security within the IoT network.

On the other hand, referring to FIGS. 3 and 4, the edge server 131 inputs the data processing request message to the virtual quantum machine 133 prepared in advance when the verification of the client terminal 111 that has transmitted the data processing request message is completed. can be converted into qubits.

Here, a qubit is a basic unit that a quantum computer calculates, and is a bit that has a state of 0 and 1 at the same time, and the virtual quantum machine 133 is intermediate between the existing client terminal 111 and the quantum server 155 in the cloud layer 15. It is a QMT (Quantum Machine Termial) used as a medium between

These QMTs are provided with encoding gates and compilers to reduce the need for a quantum computer in a cloud environment or smart city environment, and to perform quantum-based encryption to enhance communication security between the client terminal 111 and the quantum server 155. .

More specifically, the QMT provided in the edge server 131 may convert a data processing request message generated with classical bits into qubits using an encoding gate.

In addition, the QMT may encode the data processing request message converted into qubits using an encoding gate. At this time, the QMT is a plurality of gates 135 communicating with the quantum server 155, and may transfer qubits by distributing Rx, Ry, and Rz Quantum Logical Gates in advance. here , and is defined as in [Equation 1] to [Equation 3] below.

In addition, the edge server 131 may use Rx, Ry, and Rz as gates 135 to transfer data to the quantum server 155, but may further include a CNOT gate to transfer data.

Through this, the edge server 131 converts the data processing request message prepared with classical bits into a plurality of qubits using QMT, and converts the converted qubits into Rx, Ry, and Rz. It can be encoded in the gate 135 and transmitted to the quantum server 155.

On the other hand, the edge server 131 may further provide Quantum Secure Direct Communication (QSDC) in order to improve the calculation point of view and error accuracy occurring in the process of transferring qubits to the quantum server 155.

The edge server 131 may transmit a secure message without generating a separate shared secret key using QSDC when an emergency occurs in the process of transferring qubits to the quantum server 155.

In addition, the edge server 131 may further use QSDC in order to use the QMT as a device for communicating with at least one verified client terminal 111 .

At this time, when the at least one client terminal 111 is verified through the block chain 1311 in the edge server 131, it may separately encrypt the data processing request message and transmit it to the QMT through photons.

Here, photons can be polarized based on one of four main states |H>, |V>, |u> and |d>.

In addition, the edge server 131 receives the encrypted data processing request message through the QMT, randomly selects a set of photons to be measured, and determines whether an eavesdropper exists based on the error rate concept.

Accordingly, the edge server 131 may determine that the communication channel is safe if the error rate is low and maintain communication, and may stop communication by determining that an eavesdropper exists in the communication channel if the error rate is high.

On the other hand, the edge server 131 applies Q-OTP to the data processing request message converted to qubits before forwarding the data processing request message converted to qubits to the quantum server 155, further quantum-based encryption can be done

More specifically, the edge server 131 may apply the Q-OTP (Quantum One-Time Pad) shown in FIG. 12 to the data processing request message converted into qubits, where the Q-OTP is standard-based arithmetic It is an encryption technique that performs encryption by simultaneously using the X operation suitable for , and the Z operation used in Hadamard-based encryption.

At this time, the edge server 131 uses a 2-bit primary key for each qubit of the message processing request message converted into a plurality of qubits in order to apply the Q-OTP using the X operation and the Z operation to the data processing request message. can be further distributed.

Here, [Equation 4] is an equation representing encryption performed by applying Q-OTP to a data processing request message converted into qubits, and [Equation 5] is an encryption data processing request through [Equation 4]. A mathematical expression representing the decryption of a message.

Here, e is an encryption function, X is an operation for standard basic encryption, Z is an operation used in Hadamard-based encryption, k is a key value, and m is a variable in a message. At this time, both X and Z operations are operations used to encrypt arbitrary qubits.

The Q-OTP defined by [Equation 4] and [Equation 5] can perform encryption with the values shown in FIG. 12 .

Through this, the edge server 131 encodes the qubits of the data processing request message for which encryption has been performed through Q-OTP on the prepared gate 135 among the plurality of gates 135 prepared as Rx, Ry, and Rz, It can be passed to the server 155.

The edge server 131 verifies at least one client terminal 111 by performing the algorithms shown in FIGS. 13 to 15, converts the data processing request message of the verified client terminal 111 into qubits, , Encryption is performed by applying Q-OTP to the converted qubits, and the qubits of the encrypted data processing request message are encoded on the prepared gate 135 among the plurality of gates 135 provided with Rx, Ry, and Rz. can

On the other hand, the quantum server 155 performs a data processing request by analyzing the data processing request message when the verification of the client terminal 111 is completed in the edge server 131.

More specifically, the quantum server 155 transmits the qubit of the encrypted data processing request message through the prepared gate 135 among the plurality of gates 135 prepared by the edge server 131 as Rx, Ry, and Rz , It is possible to access the data processing request message through delegation quantum computing, and perform and store the data processing request of the client terminal calculated through the access. Here, delegated quantum computing may be provided to maximize the use of quantum computing performance while protecting user data and computing security.

Accordingly, the quantum server 155 uses the gate protocol sequence shown in FIGS. 5 to 11 to perform data processing according to the data processing request message and calculation work for storing the message using delegation quantum computing. It is possible to construct a quantum circuit consisting of a set of measurement angles in Here, the {X, Z, H, P, CNOT, R} gate protocol shown in Figures 5 to 11 can be used to perform the process of preparing auxiliary qubits together with measurements based on single qubit computations. can

Through this, the quantum server 155 accesses only the prepared gate 135 among the plurality of gates 135 provided with Rx, Ry, and Rz in which the edge server 131 has encoded the qubits of the encrypted data processing request message, Data may be processed by analyzing the data processing request message, and qubits of the encrypted data processing request message may be stored in an internal storage space.

As a result, the blockchain-based distributed quantum network system 10 for the IoT network improves computational power and security in the IoT environment, and reduces the need to have a quantum machine on the client terminal 111 side, so that the client terminal 111 It is possible to provide secure access between the quantum server 155 and to provide an effect of performing complex calculations requested by the client terminal 111 while maintaining security for data stored in the quantum server 155.

On the other hand, FIG. 16 is a flow diagram of a blockchain-based distributed quantum network method according to an embodiment of the present invention. The blockchain-based distributed quantum network method according to an embodiment of the present invention uses the IoT network shown in FIGS. 1 to 15 Since it proceeds on the same configuration as the blockchain-based distributed quantum network system 10 for the IoT network of FIGS. 1 to 15, the same reference numerals are assigned, and repeated descriptions are omitted. do.

Referring to FIG. 16, a distributed quantum network method (hereinafter, method) according to an embodiment of the present invention is a method performed in a blockchain-based quantum network system 10 for an IoT network, and includes at least one client terminal 111 ), an edge server 131 and a quantum server 155.

First, at least one client terminal 111 performs step 1610 of collecting data and generating a data processing request message including the data.

Here, the data collected by at least one client terminal 111 is information or records collected by each client terminal 111 according to a user's command, and this information or record is IoT raw data, which is very sensitive and personalized. Data that requires higher security measures to generate information.

Accordingly, at least one client terminal 111 may generate a data processing request message including its own terminal information and collected data, and transmit the generated data processing request message to the edge server 131 .

In this regard, the edge server 131 inputs the terminal information and the data processing request message of the client terminal 111 that generated the data processing request message to the blockchain 1311 prepared in advance to verify the client terminal 111. Step 1630 is performed.

The edge server 131 checks whether the client terminal 111 that sent the data processing request message is the client terminal 111 connected to the blockchain in advance and verifies the safety of the client terminal 111 based on the blockchain. It can perform the Practical Byzantine Fault Tolerance algorithm.

In addition, when the verification of the client terminal 111 that has transmitted the data processing request message is completed, the edge server 131 inputs the data processing request message prepared in classical bits to the virtual quantum machine 133 prepared in advance to convert it into qubits, , quantum-based encryption can be performed by applying Q-OTP to the data processing request message converted into qubits.

In addition, the edge server 131 encodes the qubits of the data processing request message for which quantum-based encryption has been performed on the prepared gate 135 among the plurality of gates 135 connected to the quantum server 155 in advance, and then the quantum server 155 ) can be passed on.

Accordingly, when the verification of the client terminal 111 is completed in the edge server 131, the quantum server 155 analyzes the data processing request message and performs step 1650 of performing the data processing request.

More specifically, when the quantum server 155 encodes the qubits of the data processing request message for which quantum-based encryption has been performed in the edge server 131 to the prepared gate 135 among the plurality of gates 135 connected in advance, , It is possible to access a corresponding gate through delegation quantum computing, perform a data processing request of the client terminal 111 calculated through the access, and store it in a separate internal storage space.

As such, the method can provide secure access between the client terminal 111 and the quantum server 155 by improving computational power and security in the IoT environment and reducing the need to have a quantum machine on the client terminal 111 side. In addition, it is possible to provide an effect of performing complex calculations requested by the client terminal 111 while maintaining security for data stored in the quantum server 155.

Such a method may be implemented as an application or implemented in the form of program instructions that can be executed through various computer components and recorded on a computer-readable recording medium. The computer readable recording medium may include program instructions, data files, data structures, etc. alone or in combination.

Program instructions recorded on the computer-readable recording medium may be those specially designed and configured for the present invention, or those known and usable to those skilled in the art of computer software.

Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floptical disks. media), and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like.

Examples of program instructions include high-level language codes that can be executed by a computer using an interpreter or the like as well as machine language codes such as those produced by a compiler. The hardware device may be configured to act as one or more software modules to perform processing according to the present invention and vice versa.

Although the above has been described with reference to embodiments, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the claims below. You will understand.

10: Blockchain-based distributed quantum network system for IoT networks
11: terminal layer
111: client terminal
13: Edge layer
131: edge server
1311: Blockchain
133 Virtual quantum machine
135: gate
15: Cloud Tier
155: quantum server

Claims (5)

At least one client terminal for collecting data and generating a data processing request message including the data;
an edge server that verifies the client terminal by inputting terminal information of the client terminal that generated the data processing request message and the data processing request message to a previously prepared block chain; and
When the verification of the client terminal is completed in the edge server, a quantum server that analyzes the data processing request message and performs a data processing request; A blockchain-based distributed quantum network system for an IoT network including.
According to claim 1,
The edge server,
Any one of the at least one client terminal existing in the blockchain is set as a verification authority node, and the terminal information is transmitted to the verification authority node to confirm the client terminal, but the client terminal If it is confirmed that the terminal is authenticated, a root role is assigned to the verification authority node to perform a message broadcast until a preset round, and the different results displayed by the verification authority node are compared through the message broadcast. A blockchain-based distributed quantum network system for an IoT network that verifies the client terminal.
According to claim 2,
The edge server,
When the verification of the client terminal is completed, the data processing request message is input to a virtual quantum machine prepared in advance to be converted into qubits, and quantum-based encryption is performed by applying Q-OTP to the data processing request message converted into qubits. A blockchain-based distributed quantum network system for IoT networks.
According to claim 3,
The quantum server,
A blockchain-based distributed quantum network system for an IoT network that accesses the data processing request message transmitted by the edge server through delegated quantum computing, and performs and stores the data processing request of the terminal of the client calculated through the access.
In the blockchain-based distributed quantum network method performed in the blockchain-based distributed quantum network system for the IoT network,
Collecting data by at least one client terminal and generating a data processing request message including the data;
verifying the client terminal by inputting, by an edge server, terminal information of the client terminal that generated the data processing request message and the data processing request message to a previously prepared block chain; and
When the quantum server completes the verification of the client terminal in the edge server, performing a data processing request by analyzing the data processing request message; Blockchain-based distributed quantum network method for an IoT network, including.