KR102501373B1 - The multi-function matrix hash function with solar ray generator of blockchain metering its system - Google Patents

Abstract

)인 대칭암호키를 생성하고, 양자메인보드는 의사난수생성기를 통해 MAC Address 데이터(

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 X 좌표 값을 생성하고, 양자메인보드는 의사난수생성기를 통해 PUF PIN 데이터(

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 Y 좌표 값을 생성하고, 양자메인보드는 의사난수생성기를 통해 TIME 데이터(

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 Z 좌표 값을 생성한다.
양자메인보드는 의사난수생성기를 통해 상기 해시함수의 X좌표 값 및 Y좌표 값을 비교하여 X좌표 값이 Y좌표 데이터 값보다 크면 1, 작으면 0으로 이진화하여 TIME 데이터를 포함하여 비대칭암호키를 생성하는 것을 특징으로 한다.The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,
The quantum main board receives random quantum random numbers from the quantum random number generator and generates a 3D matrix function (

), and the quantum main board uses a pseudorandom number generator to generate MAC Address data (

) as a symmetric encryption key (

), the hash function (

), and the quantum main board uses the pseudorandom number generator to generate the PUF PIN data (

) as a symmetric encryption key (

), the hash function (

), and the quantum main board generates TIME data (through a pseudorandom number generator)

) as a symmetric encryption key (

), the hash function (

) to generate the Z coordinate value.
The quantum main board compares the X-coordinate value and the Y-coordinate value of the hash function through a pseudorandom number generator, and binarizes the X-coordinate value to 1 if it is greater than the Y-coordinate data value and 0 if it is smaller to obtain an asymmetric encryption key including TIME data. characterized by the creation of

Description

Multi-function matrix hash function with solar ray generator of blockchain metering its system}

Physically unique encryption technology by electromagnetic method using PUF (Phisycally Unclonable Function) Chip as a physically unique authentication method and Quantum Security QRNG (Quantum Random Number Generator) Chip that blocks hacking from quantum computers And it is related to switchboard, broadcasting device, CCTV monitoring device, solar power generation device, street light, LED display board, and parking control device applying block chain verification means.

Quantum cryptography and QKD (Quantum Key Distribution) technology using quantum mechanical properties for secure communication. It is a technology that transmits qubits (quantum teleportation) rather than the transfer of physical particles. Information is recorded and transmitted in quantum states, and as soon as an attacker measures the quantum state for eavesdropping, the quantum state itself changes and is related to technology that makes eavesdropping impossible.

Therefore, the receiver can detect attempts to eavesdrop on the data and discard the received information, and accordingly, the information recorded in the quantum state is fundamentally impossible to eavesdrop.

Apparatus and method for generating an identification key for hardware security, technology for performing physical entity authentication by applying a device and method for generating an identification key by implementing a physically unclonable function (PUF) using a process deviation during semiconductor manufacturing to enhance security.

In general, IP cameras are also capable of software security, but since the software method is added after the hardware has already been formed, there is always a possibility of being tampered with.

Therefore, in order to fundamentally solve data security, it is necessary to consider data security from the start of designing hardware to process data.

The present invention is hardware-implemented physical security and has no memory burden and high processing speed.

After generating a PIN (Personal Identification Number) value through the PUF using the hardware PIN deviation that occurs in the production process of an IC (Integrated Circuit) chip, it is stored in the public authentication platform and includes the PIN value of the PUF installed in the terminal. When the requested authentication key is received from the public authentication platform and the PIN values match, the authentication procedure is performed.

If the PUF authenticates the physical terminal by hardware, generating an authentication request key (encryption key/decryption key) by generating a one-time quantum random number OTP (One Time Password) from the PIN value of the PUF is a quantum random number generator. It is characterized by creating through

The pure random number generator includes a random number source generator and a pseudorandom number generator, and the random number source generator generates an encryption key with a random number source generated using an unpredictable natural phenomenon.

As the unpredictable natural phenomenon, a quantum random number (QRN) is generated using natural light, a light emitting diode (LED), a laser diode (LD), radiation, thermal noise, noise, and the like.

A symmetric encryption key for mutual encryption communication is generated by using the encryption key as a pair of encryption keys.

Unlike the quantum random number as described above, a One Time Password (OTP) asymmetric encryption key is encrypted and generated through a pseudorandom number generator (PRNG).

The True Random Number Generator (TRNG) of the present invention generates a quantum random number (QRN) symmetric encryption key and a pseudorandom number (PRN) asymmetric encryption key, which generates a pair of symmetric encryption keys. Two-way communication and authentication are possible through

It is characterized in that the asymmetric encryption key can be decrypted through the symmetric encryption key by generating an asymmetric encryption key re-encrypted through a pseudorandom number generator to the quantum random symmetric encryption key.

The Internet of Thing, a system that connects objects in daily life through wired and wireless networks to share information, is becoming common.

The Internet of Things (IoT) is an object space network that forms intelligent relationships such as sensing, networking, and information processing in a mutually cooperative manner without explicit human intervention for three distributed environmental elements: humans, objects, and services.

Security threats are also increasing with the generalization of the Internet of Things, and for the security of the Internet of Things, continuous security is required for all sections from IoT devices to systems.

In particular, since it needs to communicate with devices with various functions and protocols, it is much exposed to security threats because it needs to use open standard technology.

On the other hand, the software-based random number generation technology not only uses a lot of resources, but also has a problem in that a random number generation pattern can be identified using advanced hacking technology.

Therefore, natural random numbers or true random numbers that extract random numbers from the randomness of natural phenomena are being requested for security between IoT devices, which have the advantage of not having a specific pattern and being unpredictable, but are large and very expensive and require an extraction device to be miniaturized. There is a problem that is difficult to apply to the device.

The Internet Security Protocol (IP Security Protocol: IPSec) is a protocol developed for security at the packet processing layer of network communication, and is used to protect data transmitted and received through a Virtual Private Network (VPN) from public network users. It is a protocol that

The local-based IPSec VPN service is a virtual private network service in which various communication locals can send and receive VPN traffic by accessing a VPN local connected to a public network and connecting to a remote private network without setting up a separate VPN.

In order to use the virtual private network service as described above, the VPN local performs an authentication step for creating an IPSec tunnel with a virtual private network gateway (VPN GateWay: VPN G/W) through the public network. In IPSec, key exchange for the authentication is performed. As a procedure, the IKE method is divided into step 1 (Main Mode or Aggressive Mode) and step 2 (Quick Mode).

The first step of the IKE is an ISAKMP (Internet Security Association and Key Management Protocol) step for exchanging encrypted data in a public network without security, and the VPN local and virtual private network gateway (VPN G / W) share each other in advance to This is the step of negotiating with each other about the pre-shared key, the ISAKMP encryption method, and the hash function.

Step 2 is a step of negotiating an encryption method for data to be transmitted and received through the actual IPSec tunnel and a type of traffic to be transmitted and received through the IPSec tunnel.

These local-based IPsec VPN services can be divided into wire-based and wireless-based.

In the wired basis, the above-mentioned VPN local accesses the virtual private network gateway (VPN G/W) through a wired network, and in the wireless basis, the above-mentioned VPN local accesses the virtual private network gateway (VPN G/W) through the wireless network. will be.

In a wire-based VPN service, for IKE 1-step authentication between the VPN local and the virtual private network gateway (VPN G/W), the VPN local is assigned a static IP address, and the VPN local and the virtual private network gateway (VPN G/W) After storing the pre-shared key set in advance, the virtual private network gateway (VPN G/W) checks whether the IP address of the VPN local having the pre-shared key is the statically assigned IP address. Authentication is performed in a way that confirms.

In this case, the actual user local located under the subscriber's VPN local can access the remote private network through the VPN local without a separate authentication procedure.

As the use of wired and wireless communications, including the Internet, is rapidly expanding, the security of communication networks is becoming more and more important in terms of protecting important confidential information in the country, corporations, and finance and personal privacy.

The asymmetric public key cryptosystem, developed in the 1970s and widely used in communication systems such as the Internet, encrypts information using a mathematical problem that is very difficult to solve as a public key and decrypts it using the solution as a secret key. It is based on mathematical "computational complexity".

Representatively, the RSA public key cryptosystem developed by Rivest, Shamir, and Adleman uses the fact that it is very difficult to factorize a very large number.

In other words, mathematically, the calculation time of the prime factorization problem increases exponentially as the size of the problem increases. Therefore, if the sender and the receiver use a sufficiently large number of prime factorization problems as public keys, it is practically impossible for an eavesdropper to decrypt the ciphertext. Take advantage of what would be impossible.

However, the security of cryptosystems based on such mathematical computational complexity is being questioned as more sophisticated algorithms are developed, and in 1994, Peter Shor of AT&T developed a prime factorization algorithm using a quantum computer to develop a quantum computer. The RSA cryptosystem has proven to be fundamentally crackable.

Quantum cryptography technology, which has emerged as an alternative to solve these security problems, has recently attracted great attention because its safety is based on the principle of quantum mechanics, which is a fundamental law of nature, not mathematical computational complexity. .

In other words, quantum cryptographic communication technology is a technology that distributes an encryption key (one-time random number table) between a sender and a receiver in real time absolutely safely based on the laws of quantum physics such as “quantum non-reproducibility” and is called “quantum key distribution technology (QKD). )" is also known as

The first quantum cryptographic protocol was developed in 1984 by IBM's C.H. Bennett and G. Brassard of the University of Montreal.

Named the BB84 protocol after its inventors, the protocol uses four quantum states (eg, the polarization state of a single photon) that form two basis.

However, according to the above prior art, in order to transmit and receive quantum cryptography, a transmission/reception device is required between the video localizer for communication and the server, and there is a limit in that the cost burden of the transmission/reception device between the video localizer and the server for communication increases.

Block chain, also called public transaction ledger, is a technology that prevents hacking that can occur when trading in virtual currency. In the case of existing financial companies, transaction records are stored in a centralized server, whereas blockchain is Transaction details are sent to all users, and each transaction is compared to prevent data forgery. Block chain is applied to Bitcoin, a representative online virtual currency. Bitcoin transparently records transaction details in a ledger that anyone can view. It is recorded, and several computers using Bitcoin verify this record once every 10 minutes to prevent hacking.

Competing with NB-IoT in the field of Low Power Wide Area Network (LPWAN), LoRA LPWAN is capable of providing Internet of Things (IoT) and M2M (Machine -to-Machine) wireless communication can be implemented and millions of wireless sensor nodes can be connected to the gateway. It can be easily connected with the LoRa Alliance infrastructure along with existing infrastructure, including both private LAN and public networks operated by telecommunication operators, and LPWAN (Low Power LoRA technology enables embedded applications to have higher scalability and cost-effectiveness compared to 3G and 4G cellular networks, and provides a bridge between greater coverage and lower power consumption. It is described as a way to solve the long-standing dilemma of choosing one or the other. By using LoRA technology, you can maximize both while reducing the cost of additional repeaters, operate reliably in harsh outdoor environments, and have extensive low-speed wireless monitoring and control. It is described as very suitable for design.

LTE (Long Term Evolution) is a wireless technology designed to increase the capacity and speed of mobile phone networks. LTE-A, Broadband LTE, LTE-R (Railway), Narrowband LTE, LTE-B (Beyond), LTE-H (Heterogeneous) and LTE-U (Unlicensed).

In particular, narrowband LTE uses narrow bands such as LTE-MTC (MarrowBand-LTE-Machine) and narrower NB-LTE-M (NarrowBand-LTE-Machine), so the speed is slow but power consumption is low, so LG U+ and KT is commercializing NB-LTE-M (NB-IoT).

MAC Address (media access control address) is an address used by the MAC layer of the data link layer in a local area network.

A hardware address assigned by a network card manufacturer is a universally administered address (UAA), and all network cards have a unique value, but the UAA can be changed for management purposes. This MAC address is called a locally administered address (LAA).

It is possible to give an early warning before a fire by detecting HCl and BHT gas generated by heat from the insulation coating that surrounds energized materials such as wires and bus bars before an electrical fire occurs.

Switchboards, broadcasting devices, CCTV monitoring devices, solar power generation devices, It is a task to solve street lights, LED display boards, and parking control devices.

HCl detection sensor that can prevent the spread of gas and fire by detecting the occurrence of electrical fire by detecting hydrogen chloride gas (HCl) generated in a fire accident and by detecting hydrogen chloride gas (HCl) generated from electrical insulators in the event of a fire. It has the distinction of providing an image of hydrogen chloride gas (HCl) generation through a CCTV surveillance camera that detects the wavelength absorbed when non-infrared radiation electromagnetic waves pass through hydrogen chloride gas (HCl).

That is, in generating an early fire occurrence event, it has a difference in that it is detected by an infrared CCTV surveillance camera and provided as a visualized image, rather than a method by a sensor that detects HCl, BHT gas, etc.

In a device and method for generating an identification key for hardware security that cannot be duplicated or hacked, an encryption key is generated by implementing a physically unclonable function (PUF) using a process deviation during semiconductor manufacturing.

A unique encryption symmetric key is generated by encrypting product information data with quantum random numbers generated through QRNG (Quantum Random Number Generator).

According to the binary hash function, a one-time OTP (One Time Password) asymmetric key is generated through a pseudo random number generator (PRNG).

In particular, it is characterized by a pseudorandom number generation process that generates a binary cryptographic code of a hash function through MAC address data, PUF PIN data, and a multi-dimensional matrix based on random quantum random numbers generated through a quantum random number generator.

Since each gas has its own absorption wavelength range, the type of gas can be identified by analyzing the absorption wavelength range.

We provide a commercial service that maximizes security by generating an asymmetric encryption key through a binarization process through a multi-dimensional matrix hash function based on a source security ankey using random quantum random numbers and a PUF Chip that performs physically unique authentication.

By providing images of HCl and BHT gas generation through CCTV surveillance cameras, early fire alarms and gas leaks are provided as visualization images before a fire occurs.

1 is an explanatory diagram of an asymmetric encryption key formula
2 to 12 are thermal decomposition gas chromatography of insulation

The present invention is embodied in the following technology as the main features.

1. Random quantum random number symmetric encryption key based on QRNG

2. Physical unique key extracted from PUF PIN data from PUF Chip

3. Public information data based on device-specific MAC ADDERS data

4. Data block public encryption key and private encryption key generated based on multidimensional matrix function

5. Asymmetric encryption key encrypted through hash function pseudorandom number generator

6. A block chain that chains successive data blocks with an asymmetric encryption key and verifies them using the OTP method

7. Provide synthetic images of HCl and BHT gases generated through special CCTV surveillance cameras that detect gases.

It will be described in detail below through an embodiment.

The server is composed of a quantum main board including a pure (natural) random number generator and a pseudo (programmed) random number generator, a server including an OTP memory, and one or more terminal devices.

The pure (natural) random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles as a random number source from at least one of a light-emitting diode (LED), a laser diode (LD), a radiation isotope, and a noise pulse.

The quantum detection diode is a quantum detection diode that detects quantum particles (random number source) generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects an event according to detection of quantum particles from the quantum detection diode and generates pulses (random pulses) corresponding to detection of quantum particles.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo (program) random number generator for generating a pseudo random number by a random number generating program, and generates a symmetric encryption key by receiving a quantum random number from the quantum random number control unit.

In addition, the quantum main board encrypts the symmetric encryption key with the pseudo-random number generated from the pseudo (program) random number generator to generate the following asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the terminal device.

The terminal device encrypts the ID address and data block data (ID, block chain data block, etc.) inside the terminal device with an asymmetric encryption key and transmits it to the quantum main board inside the server.

The quantum main board receives the data block data encrypted with the asymmetric encryption key, decrypts it with the symmetric encryption key, and stores it in the OTP memory as a current data block.

The quantum main board sequentially chains the previous data block and the current data block into data blocks, and mutually authenticates the chained block chain data between a set of terminal devices (first to N terminal devices) or between the server and the terminal device.

When mutual authentication (agreement) of blockchain data is completed, the server deletes the symmetric encryption key and the asymmetric encryption key, and then generates a new symmetric encryption key and asymmetric encryption key through a pure (natural) random number generator and a pseudo (program) random number generator. It is characterized by mutual re-authentication according to the block chain cycle.

For example, the server is a smart grid server, a broadcasting server, a local broadcasting server, a CCTV control server, a failure monitoring control server, a remote meter reading server, a dimming control server, and a remote control server.

For example, the terminal device is a smart block switchboard, TTS broadcasting device, premises video and audio broadcasting device, encrypted image storage CCTV monitoring device, NB-IoT failure monitoring black box type CCTV monitoring device, block chain metering solar power generation device, dimming control LED street light, solar power panel, LED display board, CCTV thermal imaging surveillance camera, image processing device, license plate number encryption parking control system, early fire monitoring CCTV surveillance camera.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a server including an OTP memory, and one or more terminal devices.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and generates an asymmetric encryption key by encrypting the symmetric encryption key with the pseudo random number generated from the pseudorandom number generator. A random quantum random number is received from the generator and a symmetric encryption key, which is a three-dimensional matrix function, is generated.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the MAC address data of the terminal device with the symmetric encryption key through the pseudorandom number generator.

The terminal device is composed of a PUF chip, and the quantum main board extracts PUF PIN data from the PUF chip through a pseudorandom number generator, and then the extracted PUF PIN data is encrypted with a symmetric encryption key, and the Y coordinate value of the hash function generate

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The Z value is used as data to distinguish the block chain authentication cycle, previous data block, and current data block.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the terminal device.

The terminal device encrypts the ID address and data block data inside the terminal device with an asymmetric encryption key and transmits them to the quantum main board inside the server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board is characterized in that the previous data block and the current data block are successively chained into data blocks, and the chained block chain data is transmitted to the terminal device for mutual authentication.

As an example,

It consists of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, an infrared emitter emitting infrared rays, and a main control unit including a microprocessor.

The main control unit compares the received infrared ray frequency received through the infrared sensor array unit of the sensing unit inside the imaging unit after the radiant infrared ray emitted from the infrared emitter is reflected, extracts the absorption frequency absorbed by the gas, and displays it as a color on the monitor for each gas type. Create image data.

The main control unit generates synthesized data obtained by combining the image data with the image data received from the image sensor array unit inside the imaging unit, and displays the synthesized data on the monitor.

The smart grid server includes a quantum main board (Q-MCU) including a quantum random number generator (QRNG) and a pseudo random number generator (PRNG), an OTP memory (OTP M/M), It consists of

It consists of the first to Nth smart block switchboard sets (N is a natural number greater than or equal to 2). (For example, the first smart block switchboard, the second smart block switchboard, the third smart block switchboard, the fifth smart block switchboard, and the fifth smart block switchboard. Smart block switchboard assembly)

A quantum random number generator (QRNG) is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles as a random number source from at least one of a light-emitting diode (LED), a laser diode (LD), a radiation isotope, and a noise pulse.

The quantum detection diode is a quantum detection diode that detects quantum particles (random number source) generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects an event according to detection of quantum particles from the quantum detection diode and generates pulses (random pulses) corresponding to detection of quantum particles.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board (Q-MCU) is configured to include a pseudo random number generator (PRNG) for generating a pseudo random number by a random number generating program, and generates a symmetric encryption key by receiving a quantum random number from the quantum random number control unit.

In addition, the quantum main board (Q-MCU) encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator (PRNG) to generate the following asymmetric encryption key.

The quantum main board (Q-MCU) stores the symmetric encryption key and the asymmetric encryption key in the OTP memory (OTP M/M) and transmits the asymmetric encryption key to the smart block switchboard.

The smart block switchboard encrypts the smart block switchboard ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the smart grid server.

The quantum main board (Q-MCU) receives the data block data that combines the smart block switchboard ID address and synthetic data encrypted with the asymmetric encryption key, decrypts it with the symmetric encryption key, and stores the current data block in the OTP memory (OTP M/M). Save.

The quantum main board (Q-MCU) continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to a set of smart block switchboards (1st to Nth smart block switchboards) or smart grid servers. Mutual authentication between smart block switchboards.

When the mutual authentication (agreement) of blockchain data is completed, the smart grid server deletes the symmetric encryption key and the asymmetric encryption key, and then generates a new symmetric encryption key and asymmetric encryption key through a quantum random number generator and a pseudorandom number generator, It is characterized by mutual re-authentication according to

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a smart grid server including an OTP memory, and a set of one or more smart block switchboards.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

In addition, an asymmetric encryption key is generated by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the smart block switchboard.

The smart block switchboard encrypts the smart block switchboard ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the smart grid server.

The quantum main board receives the encrypted smart block switchboard ID address and data block data with the asymmetric encryption key, decrypts them with the asymmetric encryption key, and stores them in the OTP memory as the current data block.

In addition, the previous data block and the current data block are continuously chained into data blocks, and the chained block chain data is transmitted to the smart block switchboard for mutual authentication. When mutual authentication is completed, the smart grid server uses the symmetric encryption key and the asymmetric encryption key. After deleting, a symmetric encryption key and an asymmetric encryption key are newly generated through a quantum random number generator and a pseudorandom number generator.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a smart grid server including an OTP memory, and one or more smart block switchboards.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the smart block switchboard through the pseudorandom number generator.

Quantum main board consists of smart block switchboard including PUF chip,

The quantum main board extracts the PUF PIN data from the PUF Chip through a pseudorandom number generator, and then generates the Y coordinate value of the hash function with the data value encrypted with the PUF PIN data with the symmetric encryption key.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The Z value is used as data to distinguish the block chain authentication cycle, previous data block, and current data block.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the smart block switchboard.

The smart block switchboard encrypts the ID address and data block data inside the smart block switchboard with an asymmetric encryption key and transmits them to the quantum main board inside the smart grid server.

The quantum main board receives the switchboard ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board is characterized in that the previous data block and the current data block are continuously chained into data blocks, and the chained block chain data is transmitted to the smart block switchboard for mutual authentication.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a smart grid server including an OTP memory, and one or more smart block switchboards.

In the quantum main board generating a symmetric encryption key by receiving quantum random numbers from a quantum random number generator and generating an asymmetric encryption key by encrypting the symmetric encryption key through a pseudorandom number generator,

The quantum main board generates a symmetric encryption key by receiving random quantum random numbers from the quantum random number generator.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the smart block switchboard through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the smart block switchboard through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value with a hash function, which is a binarization function of a pseudorandom number generator, and a hash function that binarizes the X coordinate value to 1 if the X coordinate value is greater than the Y coordinate data value and to 0 if it is smaller than the Y coordinate data value. Asymmetric encryption key

를 생성한다.

generate

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the smart block switchboard.

The smart block switchboard encrypts the ID address and data block data inside the smart block switchboard with an asymmetric encryption key and transmits them to the quantum main board inside the smart grid server.

The quantum main board receives the switchboard ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board is characterized in that the previous data block and the current data block are continuously chained into data blocks, and the chained block chain data is transmitted to the smart block switchboard for mutual authentication.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a smart grid server including an OTP memory, and a smart block switchboard.

In the quantum main board generating a symmetric encryption key by receiving quantum random numbers from a quantum random number generator and generating an asymmetric encryption key by encrypting the symmetric encryption key through a pseudorandom number generator,

The quantum main board generates a symmetric encryption key by receiving random quantum random numbers from the quantum random number generator.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the smart block switchboard through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the smart block switchboard through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value with a hash function, which is a binarization function of a pseudorandom number generator, and a hash function that binarizes the X coordinate value to 1 if the X coordinate value is greater than the Y coordinate data value and to 0 if it is smaller than the Y coordinate data value. Asymmetric encryption key

를 생성한다.

generate

The smart grid server is characterized in that it transmits the asymmetric encryption key to the smart block switchboard.

As an example,

An early fire detection CCTV surveillance camera is composed of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, an infrared emitter emitting infrared rays, and a main control unit including a microprocessor.

The main control unit compares the received infrared ray frequency received through the infrared sensor array unit of the sensing unit inside the imaging unit after the radiant infrared ray emitted from the infrared emitter is reflected, extracts the absorption frequency absorbed by the gas, and displays it as a color on the monitor for each gas type. Image data and early fire alarm event data are created.

The main control unit generates synthesized data obtained by combining the image data with the image data received from the image sensor array unit inside the imaging unit, and displays the synthesized data on the monitor.

Composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a broadcasting server including an OTP memory, and a set of one or more TTS broadcasting devices, the quantum random number generator includes a random number source generator, a quantum detection diode, and a quantum random pulse It consists of a generator and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo random number generator for generating a pseudo random number by a random number generating program, receives a quantum random number from the quantum random number controller to generate a symmetric encryption key, and the quantum main board generates a pseudo random number generated from the pseudo random number generator. An asymmetric encryption key is generated by encrypting the symmetric encryption key with a pseudorandom number.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the TTS broadcasting device.

The TTS broadcasting device encrypts the data block data that combines the ID address and synthesized data and early fire alarm event data inside the TTS broadcasting device with an asymmetric encryption key and transmits it to the quantum main board inside the broadcasting server.

The quantum main board receives the TTS broadcasting device ID address and data block data and stores them in the OTP memory as a current data block, and the quantum main board sequentially chains the previous data block and the current data block into data blocks, and the chained block Chain data is transmitted to one or more TTS broadcasting devices for mutual authentication, and when mutual authentication is completed and early fire alarm event data is received, TTS (Text To Speech) early fire alarm broadcast text encrypted with an asymmetric encryption key is broadcast. .

The broadcasting server deletes the symmetric encryption key and the asymmetric encryption key after the TTS (Text To Speech) broadcasting ends, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a broadcasting server including an OTP memory, and one or more TTS broadcasting devices (or as a set).

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the TTS broadcasting device.

The TTS broadcasting device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the broadcasting server.

The quantum main board receives the TTS broadcasting device ID address and data block data and stores them in the OTP memory as current data blocks.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to the TTS broadcasting device.

When the block chain data is mutually authenticated between the broadcasting server and the TTS broadcasting device or the block chain data is mutually authenticated between one or more TTS broadcasting devices, TTS (Text To Speech) broadcast text encrypted with an asymmetric encryption key is broadcast. do.

The broadcasting server deletes the symmetric encryption key and the asymmetric encryption key after the TTS (Text To Speech) broadcasting ends, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a broadcasting server including an OTP memory, and one or more TTS broadcasting devices.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the TTS broadcasting device through the pseudorandom number generator.

The quantum main board extracts the PUF PIN data of the PUF chip from the TTS broadcasting device including the PUF chip through the pseudorandom number generator and generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the TTS broadcasting device.

The TTS broadcasting device encrypts the ID address and data block data inside the TTS broadcasting device with an asymmetric encryption key and transmits them to the quantum main board inside the TTS broadcasting device.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and mutually authenticates the block chain data between the broadcasting server and the TTS broadcasting device or one or more TTS broadcasting devices for the chained block chain data. Blockchain data is mutually authenticated, and when mutual authentication is completed, TTS (Text To Speech) broadcast text encrypted with an asymmetric encryption key is broadcast.

The broadcasting server deletes the symmetric encryption key and the asymmetric encryption key after the TTS (Text To Speech) broadcasting ends, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a premises broadcasting server including an OTP memory, and an premises video and audio broadcasting device (or one or more premises video and audio broadcasting devices).

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the video and audio broadcasting device in the premises.

The video and audio broadcasting device encrypts the internal ID address and data block data (ID, block chain data, etc.) with an asymmetric encryption key and transmits them to the quantum main board inside the premises broadcasting server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board sequentially chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to one or more video and audio broadcasting devices in the premises for mutual authentication.

When the mutual authentication is completed, the quantum main board generates a watermark with an asymmetric encryption key and transmits the watermarked image and audio data with the watermark inserted into the image to the video and audio broadcasting device in the premises.

After displaying the watermarked image on a monitor and broadcasting voice data through a speaker, the intranet broadcasting server deletes the symmetric encryption key and the asymmetric encryption key, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator. It is characterized by doing.

As an example,

An early fire detection CCTV surveillance camera is composed of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, an infrared emitter emitting infrared rays, and a main control unit including a microprocessor.

The main control unit compares the received infrared ray frequency received through the infrared sensor array unit of the sensing unit inside the imaging unit after the radiant infrared ray emitted from the infrared emitter is reflected, extracts the absorption frequency absorbed by the gas, and displays it as a color on the monitor for each gas type. Create image data.

The main control unit generates synthesized data obtained by combining the image data with the image data received from the image sensor array unit inside the imaging unit, and displays the synthesized data on the monitor.

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a premises broadcasting server including an OTP memory, and a set of video and audio broadcasting devices.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the video and audio broadcasting device in the premises.

The video and audio broadcasting device encrypts the data block data that combines the internal ID address and synthesized data with an asymmetric encryption key and transmits it to the quantum main board inside the premises broadcasting server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board sequentially chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to one or more video and audio broadcasting devices in the premises for mutual authentication.

When the mutual authentication is completed, the quantum main board generates a watermark with an asymmetric encryption key and transmits the watermarked image and audio data with the watermark inserted into the synthesized data image to the video and audio broadcasting device in the premises.

After displaying the watermarked image on a monitor and broadcasting voice data through a speaker, the intranet broadcasting server deletes the symmetric encryption key and the asymmetric encryption key, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator. It is characterized by doing.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a premises broadcasting server including an OTP memory, and an premises video and audio broadcasting device.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the video and audio broadcasting device MAC address data through the pseudo random number generator.

The quantum main board generates the Y coordinate value of the hash function with a data value obtained by encrypting the PUF PIN data inside the premises video and audio broadcasting apparatus including the PUF through a pseudorandom number generator with a symmetric encryption key.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the video and local broadcasting broadcasting device.

The video and audio broadcasting device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the premises broadcasting server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board sequentially chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to one or more video and audio broadcasting devices in the premises for mutual authentication.

When the mutual authentication is completed, the quantum main board generates a watermark with an asymmetric encryption key and transmits the watermarked image and audio data with the watermark inserted into the image to the video and audio broadcasting device in the premises.

After displaying the watermarked image on a monitor and broadcasting voice data through a speaker, the intranet broadcasting server deletes the symmetric encryption key and the asymmetric encryption key, and newly generates a symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator. It is characterized by doing.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a CCTV control server including an OTP memory, and a set of one or more encrypted image storage CCTV monitoring devices.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the encrypted image storage CCTV monitoring device.

Encrypted image storage CCTV monitoring device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the CCTV control server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board sequentially chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to one or more encrypted image storage CCTV monitoring devices for mutual authentication.

When the mutual authentication is completed, the quantum main board

Encrypted image storage CCTV monitoring device The data received from the image capturing unit image sensor array unit inside the encrypted image storage CCTV monitoring device is transmitted to the encrypted image storage CCTV monitoring device.

The privacy photographed image is an image in which an administrator blinds an area photographed in a residential area among crime prevention CCTV captured images or encrypted image storage CCTV monitoring devices by designation of the administrator.

The CCTV control server stores the encrypted data in a memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a CCTV control server including an OTP memory, and a CCTV monitoring device for storing encrypted images.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the encrypted image storage CCTV monitoring device through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the encrypted image storage CCTV monitoring device including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the encrypted image storage CCTV monitoring device.

Encrypted image storage CCTV monitoring device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the CCTV control server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to the encrypted image storage CCTV monitoring device for mutual authentication.

When the mutual authentication is completed, the quantum main board transmits the data obtained by encrypting the privacy captured image obtained by blind processing the privacy area set by the administrator among the images captured by the CCTV monitoring device with an asymmetric encryption key to the encrypted image storage CCTV monitoring device.

The CCTV control server stores the encrypted data in a memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

The NB-IoT failure monitoring black box type CCTV monitoring device consists of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, an infrared emitter emitting infrared rays, and a main control unit including a microprocessor. The reflected infrared ray frequency received through the infrared sensor array unit of the sensing unit inside the imaging unit is compared to the received infrared ray frequency, and the absorption frequency absorbed by the gas is extracted to generate image data for displaying in color on the monitor for each gas type, and the main control unit captures the image. The image data received from the image sensor array unit inside the unit and the image data are synthesized to generate synthesized data, which is displayed on the monitor.

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a fault monitoring control server including an OTP memory, and a set of one or more NB-IoT fault monitoring black box type CCTV monitoring devices.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the NB-IoT failure monitoring black box type CCTV monitoring device.

The NB-IoT fault monitoring black box type CCTV surveillance device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the fault monitoring control server.

The quantum main board receives the ID address and data block data, updates them into current data blocks, and stores them in the OTP memory.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to one or more NB-IoT failure monitoring black box type CCTV monitoring devices for mutual block chain authentication.

Alternatively, mutual authentication is performed by any one or more of mutual authentication between the failure monitoring control server and the NB-IoT failure monitoring black box type CCTV monitoring device.

The quantum main board transmits the mutual (chained block chain data) to one or more NB-IoT failure monitoring black box type CCTV monitoring devices to provide mutual block chain authentication or between the failure monitoring control server and the NB-IoT failure monitoring black box type CCTV monitoring device. When at least one of the mutual authentication) authentication is completed, NB-IoT fault monitoring Black box type CCTV surveillance device fault status data (synthetic data) is encrypted with an asymmetric encryption key, and fault monitoring is performed through the NB-IoT network sent to the control server.

The failure monitoring control server stores the encrypted data in memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

Wireless communication of asymmetric encryption key, ID address and data block data, chained block chain data, and failure status data encrypted with an asymmetric encryption key between the failure monitoring control server and the NB-IoT failure monitoring black box type CCTV monitoring device The network is characterized in that it is a NB-IoT wireless network.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a fault monitoring control server including an OTP memory, and a black box type CCTV monitoring device for NB-IoT fault monitoring.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the NB-IoT failure monitoring black box type CCTV monitoring device through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the NB-IoT failure monitoring black box type CCTV monitoring device including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the NB-IoT failure monitoring black box type CCTV monitoring device through the NB-IoT wireless network.

NB-IoT fault monitoring The black box type CCTV monitoring device encrypts the internal ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the fault monitoring control server through the NB-IoT wireless network.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to the NB-IoT failure monitoring black box type CCTV monitoring device for mutual authentication.

When the mutual authentication is completed, the quantum main board transmits the data encrypted with an asymmetric encryption key to the failure presence/absence status data of the NB-IoT failure monitoring black box type CCTV monitoring device through the NB-IoT network to the failure monitoring control server. .

The failure monitoring control server stores the encrypted data in memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

Wireless communication of asymmetric encryption key, ID address and data block data, chained block chain data, and failure status data encrypted with an asymmetric encryption key between the failure monitoring control server and the NB-IoT failure monitoring black box type CCTV monitoring device The network is characterized in that it is a NB-IoT wireless network.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a remote meter reading server including an OTP memory, and a set of one or more blockchain metering solar power generation devices.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the block chain metering solar power generation device.

The blockchain metering solar power generator encrypts the internal ID address and remote meter reading data with an asymmetric encryption key and transmits them to the quantum main board inside the remote meter reading server.

The quantum main board receives the ID address and remote meter reading data and stores them in the OTP memory as a current remote meter reading data block.

The quantum main board sequentially chains the previous remote meter reading data block and the current remote meter reading data block into data blocks, and transmits the chained blockchain data to one or more blockchain metering solar power generation devices for mutual authentication;

When the mutual authentication is completed, the quantum main board transmits the data obtained by encrypting the updated remote inspection data of the blockchain metering solar power generation device with an asymmetric encryption key to the remote inspection server;

The remote inspection server stores the encrypted data in a memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a remote meter reading server including an OTP memory, and a block chain metering solar power generation device.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the blockchain metering photovoltaic device MAC address data through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the block chain metering solar power generation device including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the block chain metering solar power generation device.

The blockchain metering solar power generation device encrypts the internal ID address and remote meter reading data block data with an asymmetric encryption key and transmits it to the quantum main board inside the remote meter reading server.

The quantum main board receives the ID address and data block data and stores them in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to the block chain metering solar power generator to mutually authenticate the remote meter reading server and the block chain metering solar power generator. .

When the above mutual authentication is completed, the quantum main board transmits the updated remote meter reading data of the block chain metering solar power generator to the remote meter reading server with an asymmetric encryption key. The remote meter reading server and the block chain metering solar power generator

The remote inspection server stores the encrypted data in a memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a new symmetric encryption key and an asymmetric encryption key through a quantum random number generator and a pseudorandom number generator.

As an example,

It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a dimming control server including an OTP memory, and a set of one or more dimming control LED streetlights.

The dimming control LED street light includes a street light controller composed of a microprocessor including a PUF Chip.

The streetlight control unit receives dimming data from the dimming control server through mutual data communication with the dimming control server using an asymmetric encryption key, and controls the dimming (power-saving lighting) of the streetlight.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the dimming control LED street light.

The dimming control LED street light encrypts the PIN data extracted from the internal ID address and PUF chip with an asymmetric encryption key and transmits it to the quantum main board inside the dimming control server.

The quantum main board receives the PIN data extracted from the ID address and PUF chip and stores it in the OTP memory as a PIN data block extracted from the current PUF chip.

The quantum main board sequentially chains the previous PIN data block and the current PIN data block into data blocks, and transmits the chained block chain data to one or more dimming controlled LED streetlights for mutual authentication.

The quantum main board is characterized in that when the mutual authentication is completed, the dimming control data of the street light is encrypted with an asymmetric encryption key and transmitted.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a dimming control server including an OTP memory, and a dimming control LED street light.

The dimming control LED street light includes a street light controller composed of a microprocessor including a PUF Chip.

The streetlight control unit receives dimming data from the dimming control server through mutual data communication with the dimming control server using an asymmetric encryption key, and controls the dimming (power-saving lighting) of the streetlight.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the dimming control LED street light MAC address data through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the dimming control LED street light including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the dimming control LED street light.

The dimming control LED street light encrypts the PIN data block data extracted from the internal ID address and PUF chip with an asymmetric encryption key and transmits it to the quantum main board inside the dimming control server.

The quantum main board receives the ID address and PIN data block data and stores them in the OTP memory as a current PIN data block.

The quantum main board sequentially chains the previous PIN data block and the current PIN data block into data blocks, and transmits the chained block chain data to the dimming control LED street light for mutual authentication.

When the mutual authentication is completed, the quantum main board is characterized in that the dimming control data of the low light is encrypted with an asymmetric encryption key and transmitted.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a remote control server including an OTP memory, one or more solar power generation panels or one or more LED display panels, and one or more CCTV thermal imaging surveillance cameras.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the CCTV thermal imaging surveillance camera.

The CCTV thermal imaging surveillance camera encrypts the thermal imaging image data taken of the solar power generation panel or the LED display board with an asymmetric encryption key and transmits it to the quantum main board inside the remote control server.

The quantum main board is characterized by generating an event when the temperature rises above the administrator's input value in the deterioration image taken before the fire by decrypting it with a symmetric encryption key.

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudo random number generator, a remote control server including an OTP memory, a solar power generation panel or LED display board, and a CCTV thermal imaging surveillance camera.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,

The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted by the MAC address data of the CCTV thermal imaging surveillance camera with the symmetric encryption key through the pseudorandom number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data inside the CCTV thermal surveillance camera including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the CCTV thermal imaging surveillance camera.

The CCTV thermal imaging surveillance camera encrypts the thermal imaging image data taken of the solar power generation panel or the LED display board with an asymmetric encryption key and transmits it to the quantum main board inside the remote control server.

The quantum main board is decrypted with a symmetric encryption key, and a deterioration image event is generated when the temperature rises above the manager input value before a fire occurs.

As an example,

The see-through filter CCTV surveillance camera is composed of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, and a main control unit including a microprocessor to photograph vehicle license plates.

The main control unit receives the infrared black body radiation from the license plate of the vehicle through the infrared sensor array unit inside the imaging unit, and generates perspective image data that is not affected by fog, dust, and water droplets (rain).

The main control unit generates composite data obtained by synthesizing the perspective image data with the image data received from the image sensor array unit inside the imaging unit, and displays the synthesized data on the monitor.

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a parking control server including an OTP memory, and a set of one or more parking control devices.

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller.

The random number source generator is a random number source generator that emits quantum particles from one or more of LEDs, radiation isotopes, and noise pulses.

The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator.

The quantum random pulse generator is a quantum random pulse generator that detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle.

The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator.

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives the quantum random number from the quantum random number control unit, and generates a symmetric encryption key.

The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from the pseudorandom number generator.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the parking control device.

The parking control device encrypts the data block data that combines the parking control device ID address and synthesized data with an asymmetric encryption key and transmits it to the quantum main board inside the parking control server.

The quantum main board receives the parking control device data block data encrypted with the asymmetric encryption key, decrypts it with the symmetric encryption key, and stores it in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, transmits the chained block chain data to one or more parking control devices for mutual authentication, and mutual authentication is completed, and the parking control server displays on the monitor When the license plate of the synthesized data is a wanted vehicle, it is a multi-dimensional matrix hash function block chain license plate number encryption parking control device that combines quantum random numbers and pseudo-random numbers, characterized in that it transmits the license plate encrypted with an asymmetric encryption key to the integrated crime prevention center. .

As an example,

It consists of a quantum main board including a quantum random number generator and a pseudorandom number generator, a parking control server including an OTP memory, and a parking control device.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and generates an asymmetric encryption key by encrypting the symmetric encryption key with the pseudo random number generated from the pseudorandom number generator. A random quantum random number is received from the generator and a symmetric encryption key, which is a three-dimensional matrix function, is generated.

The quantum main board generates the X coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the MAC address data of the parking control device through the pseudo random number generator.

The quantum main board generates the Y coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the PUF PIN data extracted from the PUF chip inside the parking control device including the PUF chip through the pseudorandom number generator.

The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data through the pseudorandom number generator.

The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key.

The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the parking control device.

The parking control device encrypts the parking control device ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board inside the parking control server.

The quantum main board receives the parking control device data block data encrypted with the asymmetric encryption key, decrypts it with the symmetric encryption key, and stores it in the OTP memory as a current data block.

The quantum main board continuously chains the previous data block and the current data block into data blocks, transmits the chained block chain data to the parking control device for mutual authentication, and when mutual authentication is completed, the asymmetric encryption key and synthetic video are integrated. It is a multi-dimensional matrix hash function blockchain vehicle number encryption parking control device that combines quantum random numbers and pseudorandom numbers, characterized in that it is transmitted to the center.

As an example,

CCTV thermal imaging surveillance camera and fluoroscopic filter CCTV surveillance camera is characterized in that it is replaced with a fluoroscopic camera with an infrared filter (eg, Kaya Optics X-RAY filter (http://www.kaya-optics.com/)) inserted. do.

As an example,

)인 대칭암호키를 생성한다.A quantum computer receives a random quantum random number from a quantum random number generator and uses a 3D matrix function (

) to generate a symmetric encryption key.

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 X 좌표 값을 생성 및 PUF PIN 데이터(

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 Y 좌표 값을 생성 및 의사난수생성기를 통해 TIME 데이터(

)를 대칭암호키(

)로 암호화한 데이터 값으로 해시함수(

)의 Z 좌표 값을 생성한다.Quantum computer MAC Address data (

) as a symmetric encryption key (

), the hash function (

) and generate the PUF PIN data (

) as a symmetric encryption key (

), the hash function (

) and generate the Y coordinate value of the TIME data (through a pseudorandom number generator)

) as a symmetric encryption key (

), the hash function (

) to generate the Z coordinate value.

The quantum computer compares the X coordinate value and the Y coordinate value of the hash function and binarizes it to 1 if the X coordinate value is greater than the Y coordinate data value, and to 0 if it is smaller to generate an asymmetric encryption key including TIME data. .

Hereinafter, the coupling relationship between each component will be described in detail.

The terminal unit is a smart block switchboard, TTS broadcasting device, premises video and audio broadcasting device, encrypted image storage CCTV monitoring device, NB-IoT failure monitoring black box type CCTV monitoring device, block chain metering solar power generation device, dimming control LED street light, solar light It is composed of any one of the power generation panel and LED display panel deterioration monitoring CCTV thermal imaging surveillance camera image processing device and license plate number encryption parking control device.

The early fire detection CCTV surveillance camera is composed of an imaging unit composed of an infrared sensor array unit and an image sensor array unit, an infrared emitter emitting infrared rays, and a main control unit including a microprocessor, and is composed of a dimming control LED street light or block chain metering solar power generation device and Take a picture of the same terminal.

In the main controller, the radiation emitted from the infrared emitter is reflected on a terminal such as a dimming-controlled LED street light or a block-chain metering solar power generation device, and the receiving infrared frequency received through the infrared sensor array inside the imaging unit (ie, the emitted radiation and received infrared ray frequency) to extract the absorption frequency absorbed by the gas, and generate image data and early fire alarm event data to be displayed in color on the monitor for each gas type.

(Component)

1. Quantum Main Board: Composed of a Quantum Random Number Generator (QRNG) and a Pseudo Random Number Generator (PRNG)

2. Server: Composition including OTP memory (OTP M/M) and quantum main board (Q-MCU)

3. Terminal: Smart block switchboard, TTS broadcasting device, premises video and audio broadcasting device, encrypted image storage CCTV monitoring device, NB-IoT failure monitoring black box type CCTV monitoring device, block chain metering solar power generation device, dimming control LED street light It is composed of at least one of: , solar power generation panel and LED display board deterioration monitoring CCTV thermal imaging surveillance camera image processing device, license plate number encryption parking control device.

(Detailed components and coupling relationship)

1. Quantum Main Board

1-1. Pseudo Random Number Generator (PRNG)

1-2. Quantum Random Number Generator (QRNG)

1-2-3. Quantum random number generator (QRNG): consists of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller,

Random number source generator emits quantum particles → quantum detection diode detects quantum particles → quantum random pulse generator detects quantum particle events and generates random pulses → quantum random number control unit generates quantum random numbers as a random number source.

(detailed coupling relationship)

1. The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number controller

2. The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with a pseudorandom number generated from a pseudorandom number generator (PRNG).

3. The quantum main board transmits the asymmetric encryption key to the terminal after storing the symmetric encryption key and the asymmetric encryption key in the OTP memory (OTP M/M).

4. The terminal unit encrypts the terminal unit ID address and data block data with an asymmetric encryption key and transmits them to the quantum main board.

5. The quantum main board receives the terminal ID address and data block data encrypted with the asymmetric encryption key, decrypts them with the symmetric encryption key, and stores them in the OTP memory (OTP M/M) as the current data block.

6. The quantum main board (Q-MCU) continuously chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to two or more terminal sets for mutual authentication.

7. When mutual authentication is completed, the smart grid server deletes the symmetric encryption key and the asymmetric encryption key, and then generates a new symmetric encryption key and asymmetric encryption key through the quantum random number generator and pseudorandom number generator (One Time Password).

(key generation)

Asymmetric key (public key, encryption key, public key) to enhance security in a network of symmetric keys (private key, decryption key, private key) that can encrypt and decrypt with one key produce.

1. The quantum main board receives the quantum random number from the quantum random number generator and uses the quantum random number as a seed to generate a symmetric encryption key using a known method such as a fixed-length hash function.

) 암호화하여 비대칭암호키를 생성할 수 있지만, 본 발명에서는 아래와 같은 특징이 적용된다.2. Using a known method for the symmetric encryption key with a pseudorandom number generated from a pseudorandom number generator (eg, beta logical OR / EX-OR / + /

), an asymmetric encryption key can be generated by encryption, but the following features are applied in the present invention.

3. The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key, which is a three-dimensional matrix function.

4. The X coordinate value of the hash function (matrix) is generated with the data value encrypted with the symmetric encryption key of the MAC address data seed of the terminal through the quantum main board pseudorandom number generator.

5. The Y coordinate value of the hash function is generated with the data value encrypted with the symmetric encryption key of the PUF PIN data seed extracted from the PUF Chcip inside the terminal through the quantum main board pseudorandom number generator.

6. The quantum main board generates the Z coordinate value of the hash function with the data value encrypted with the symmetric encryption key of the TIME data seed through the pseudorandom number generator.

7. The X coordinate value and Y coordinate value of the hash function are compared through the quantum main board pseudorandom number generator, and if the X coordinate value is greater than the Y coordinate data value, it is binarized to 1 and to 0 if it is smaller, to obtain TIME data (Z coordinate value) Generate an asymmetric encryption key (matrix), including

Since MAC Address data seed, PUF PIN data seed, TIME data seed and binary function (operation) expression are known, a pair of symmetric key (private key/private key) and asymmetric key (public key) key/public key) is created,

The quantum main board is characterized in that the previous data block and the current data block are sequentially chained into data blocks by applying a known block chain technology, and mutual authentication is performed by transmitting the chained block chain data to the terminal unit.

Claims (3)

delete ◈Claim 2 was abandoned when the registration fee was paid.◈ A remote inspection server configured to include a quantum main board including a quantum random number generator and a pseudorandom number generator, and an OTP memory; and
Consists of one or more blockchain metering solar power generation devices,

The quantum random number generator is composed of a random number source generator, a quantum detection diode, a quantum random pulse generator, and a quantum random number controller;
The random number source generator is a random number source generator that emits quantum particles from any one or more of LEDs, radiation isotopes, and noise pulses;
The quantum detection diode is a quantum detection diode that detects quantum particles generated from the random number source generator;
The quantum random pulse generator detects a quantum particle event from the quantum detection diode and generates a random pulse corresponding to the detection of the quantum particle;
The quantum random number control unit is a quantum random number control unit composed of a microprocessor that generates a quantum random number with a random number source generated through the quantum random pulse generator;

The quantum main board is configured to include a pseudo-random number generator for generating a pseudo-random number by a random number generating program, receives a quantum random number from the quantum random number controller and generates a symmetric encryption key; and
The quantum main board generates an asymmetric encryption key by encrypting the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator;
The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the blockchain metering solar power generation device;
The block chain metering solar power generation device encrypts the ID address and remote meter reading data with an asymmetric encryption key and transmits them to the quantum main board inside the remote meter reading server;

The quantum main board receives the ID address and remote meter reading data encrypted with the asymmetric encryption key, decrypts them with the symmetric encryption key, and stores them in the OTP memory as the current remote meter reading data block; and
The quantum main board sequentially chains the previous remote meter reading data block and the current remote meter reading data block into data blocks, and transmits the chained blockchain data to one or more blockchain metering solar power generation devices for mutual authentication;
When the mutual authentication is completed, the quantum main board stores the updated remote meter reading data of the block chain metering photovoltaic device with an asymmetric encryption key in the OTP memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a quantum random number generator and a multidimensional matrix hash function block chain metering solar power generation device control system combining quantum random numbers and pseudorandom numbers, characterized in that a symmetric encryption key and an asymmetric encryption key are newly generated through a pseudorandom number generator.
It is composed of a quantum main board including a quantum random number generator and a pseudorandom number generator, a remote meter reading server including an OTP memory, and a blockchain metering solar power generation device.

The quantum main board generates a symmetric encryption key by receiving quantum random numbers from the quantum random number generator, and encrypts the symmetric encryption key with the pseudorandom number generated from the pseudorandom number generator to generate an asymmetric encryption key,
The quantum main board receives random quantum random numbers from the quantum random number generator and generates a symmetric encryption key that is a three-dimensional matrix function;
The quantum main board generates the X coordinate value of the hash function with a data value encrypted with a symmetric encryption key of the block chain metering photovoltaic device MAC address data through a pseudorandom number generator; and
The quantum main board generates the Y coordinate value of the hash function with a data value encrypted with a symmetric encryption key of the PUF PIN data inside the block chain metering solar power generation device including the PUF chip through a pseudorandom number generator; and
The quantum main board generates the Z coordinate value of the hash function with a data value obtained by encrypting the TIME data with a symmetric encryption key through a pseudorandom number generator; and
The quantum main board compares the X coordinate value and the Y coordinate value of the hash function through a pseudorandom number generator, and binarizes the X coordinate value to 1 if it is greater than the Y coordinate data value and 0 if it is smaller to include TIME data (Z coordinate value) to generate an asymmetric encryption key;
The quantum main board stores the symmetric encryption key and the asymmetric encryption key in the OTP memory and transmits the asymmetric encryption key to the blockchain metering solar power generation device;
The block chain metering solar power generation device encrypts the ID address and remote meter reading data block data with an asymmetric encryption key and transmits them to the quantum main board inside the remote meter reading server;

The quantum main board receives the ID address and remote meter reading data block data encrypted with the asymmetric encryption key, decrypts them with the symmetric encryption key, and stores them in the OTP memory as a current data block; and
The quantum main board sequentially chains the previous data block and the current data block into data blocks, and transmits the chained block chain data to the block chain metering solar power generation device for mutual authentication;
When the mutual authentication is completed, the quantum main board stores the updated remote meter reading data of the block chain metering photovoltaic device with an asymmetric encryption key in the OTP memory, deletes the symmetric encryption key and the asymmetric encryption key, and generates a quantum random number generator and a multidimensional matrix hash function block chain metering solar power generation device control system combining quantum random numbers and pseudorandom numbers, characterized in that a symmetric encryption key and an asymmetric encryption key are newly generated through a pseudorandom number generator.

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