WO2023234629A1 - Quantum random number encryption key generation method - Google Patents

Abstract

The present invention relates to a quantum random number encryption key generation method, and more specifically to a quantum random number encryption key generation method characterized by comprising: a calling unit for transmitting a random signal so that a user can call data and an encryption key enabling access to the data; a service unit which detects the signal of the calling unit and provides, to the calling unit, the data and the encryption access key enabling access thereto that have been requested by the user; and a basic quantum random number generation unit for generating the encryption access key via a quantum random number system method, and providing the key to the service unit.

Description

Quantum random number encryption key generation method

The present invention relates to a method of generating a quantum random number encryption key, and more specifically, to a caller that transmits a random signal so that the user can call data and an encryption key to access the data, and to detect the signal of the caller and Characterized by comprising a service unit that provides the calling unit with an encryption access key for accessing data requested by the user, and a basic quantum random number generator that generates the encryption access key by a quantum random number system method and provides the encryption access key to the service unit. This relates to a method of generating a quantum random number encryption key.

The content described in this section simply provides background information about the present invention and does not constitute prior art.

Looking at conventional web security technology, HTTPS is used to secure mutual communication contents, and a system access authentication security token is generated using a computer algorithm. At this time, if the computer algorithm or code is exposed to the outside or leaked from within, hackers or third parties without legitimate access rights can intrude through token creation.

In other words, web security technology is not always free from the risk of hacking, and if a hacker hijacks authority and enters public services, there is a risk of personal information being leaked, signal system disruption, and various safety accidents occurring.

For example, looking at a case of hacking targeting devices, in July 2015, a hacker hacked the infotainment system of a Jeep Cherokee and demonstrated that it was possible to remotely control the car's engine and brake lights while driving at a high speed of 110 km. In one case, a Chrysler model was exposed to the risk of hacking and a whopping 1.4 million units were recalled.

Looking at hacking cases targeting service platforms, there was a case where the outdoor emergency siren malfunctioned 156 times at night (11:40pm to 1:20am) due to a hacking of the warning system of the Office of Emergency Management in Dallas around April 2017. Examples of civil confusion include 4,400 calls to the emergency hotline (911).

Furthermore, looking at a case of hacking targeting a service platform via a device, around March 2016, the concentration of sodium hydroxide was reset from 100ppm to 11,100ppm by hacking a PC of an employee who had access to the Florida water supply SCADA system.

Meanwhile, in March 2018, more than 30% of public administration services, such as utility bill payment and local court services, were paralyzed due to a ransomware infection in the city of Atlanta, and a budget of 9 million dollars was invested to repair the damage, and the city's functions were disrupted due to hacking. Damage to the point of paralysis can occur.

In addition, in 2017, the database of the US hospital network Atrium Health was hacked, and the personal information of 2.56 million people was leaked. In 2018, about 5,000 people suffered damage from illegal filming due to hacking of IP cameras sold in Korea.

As a result, given the current situation of increasing dependence on the web, the needs of consumers regarding the safety of web security technology are gradually expanding day by day.

Therefore, there is a need for the development of web security technology that can solve the problems of the prior art as described above.

The problem to be solved by the present invention is to complement the shortcomings of the prior art mentioned above, and the purpose of the present invention is as follows.

First, by using quantum random numbers when generating authentication security tokens, we aim to prevent code leakage to external or third parties or intrusion attempts by insiders, and provide a quantum random number encryption key generation method that theoretically makes the system unhackable.

Second, the basic quantum random number generated by quantum technology is used as the basic framework, but twin quantum random numbers synthesized to the basic quantum random number are added, and various types of random numbers such as random numbers that satisfy certain rules are created based on the arrangement of quantum random numbers. By generating and combining, we aim to provide a quantum random number encryption key generation method that can have relatively more diverse random numbers and expected values than using a single random number.

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

According to the present invention, a caller that transmits a random signal so that the user can call data and an encryption key to access the data, detects the signal of the caller and generates an encryption access key for accessing the data requested by the user. A quantum random number encryption key generation method is provided, comprising a service unit providing the call unit, and a basic quantum random number generation unit generating the encryption access key using a quantum random number system method and providing the encryption access key to the service unit.

At this time, the basic quantum random number generator can generate an arbitrary N number of basic quantum random numbers, such as number_1, number_2 to number_m, through a flat detection method or a binarization method using ground glass.

In addition, it may include a twin quantum random number generator that generates a random N number of twin quantum random numbers, such as twin_1, twin_2 to twin_n, and at least one of number_1 or number_n of the basic quantum random number formed by the basic quantum random number generator. It may include a quantum random number processing unit that combines the quantum random numbers twin_1, twin_2 to twin_n formed by the twin quantum random number generation unit.

Furthermore, the N number of twin_n may be less than half of the N number of number_n.

Meanwhile, the quantum random number processing unit may simultaneously combine twin quantum random numbers twin_1, twin_2 to twin_n formed by the twin quantum random number generator to the number_1 and the number_n.

A quantum random number encryption key generation method according to another embodiment of the present invention generates a random N number of random numbers, such as intentional_1, intentional_2 to intentional_n, placed between each twin quantum random number generated from the twin quantum random number generator. It includes a random number generator, wherein when the values of consecutive twin quantum random numbers are the same (e.g., twin_1=twin_2), the random number has a different value from the two twin quantum random numbers (e.g., , intentional_1≠twin_1 and twin_2), if the values of consecutive twin quantum random numbers are different (e.g., twin_1≠twin_2), the random number may have the value of any one of the two twin quantum random numbers.

At this time, it may include a reset unit that receives a reset signal every time a basic quantum random number is generated by the basic quantum random number generator and provided to the service unit, and the reset unit receives the reset signal according to the first setting set by the user. When accumulating value numbers,

The basic quantum random number is not generated by the basic quantum random number generator, but can be replaced once for the first time by a twin quantum random number generated by the twin quantum random number generator, and the reset signal is set to the second setting set by the user. When accumulating value numbers, the basic quantum random number may not be generated by the basic quantum random number generator, but may be replaced the first time by a random number generated by the random number generator.

Additional solutions of the present invention will be partially explained in the description that follows below, and may be partially easily identified from the description or learned by practice of the present invention.

Both the foregoing general description and the following detailed description are exemplary and explanatory only and do not limit the invention as set forth in the claims.

The effects of the present invention configured as above will be explained as follows.

First, by using quantum random numbers when generating authentication security tokens, it is possible to theoretically prevent hacking in the system by preventing code leakage to external or third parties or intrusion attempts by insiders.

Second, the basic quantum random number generated by quantum technology is used as the basic framework, but twin quantum random numbers synthesized to the basic quantum random number are added, and various types of random numbers such as random numbers that satisfy certain rules are created based on the arrangement of quantum random numbers. By generating and combining, you can have relatively more diverse random numbers and expected values than using a single random number.

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

1 is a conceptual diagram of a conventional encryption key generation method.

Figure 2 is a conceptual diagram of a method for generating a quantum random number encryption key according to an embodiment of the present invention.

Figure 3 is a flow chart of a method for generating a quantum random number encryption key according to an embodiment of the present invention.

Figures 4 to 6 are diagrams showing applicable fields of the quantum random number encryption key generation method according to an embodiment of the present invention.

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

However, when describing a specific embodiment of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The above-described objects, features and advantages of the present invention will become more apparent through the following detailed description in conjunction with the accompanying drawings. However, since the present invention can make various changes and include various embodiments, specific embodiments will be illustrated in the drawings and described in detail below.

If it is determined that a detailed description of a known function or configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Additionally, numbers used in the description process of this specification are merely identifiers to distinguish one component from another component.

In addition, the suffix “part” for the components used in the following description is merely used or used interchangeably to facilitate the preparation of the specification, and does not have a distinct meaning or role in itself.

1 is a conceptual diagram of a conventional encryption key generation method.

Figure 2 is a conceptual diagram of a method for generating a quantum random number encryption key according to an embodiment of the present invention.

Looking at conventional web security technology, as shown in Figure 1, HTTPS is used to secure the contents of mutual communication, and when a user requests access, the system generates a system access authentication security token using a computer algorithm and provides it to the user. .

On the other hand, the quantum random number encryption key generation method according to an embodiment of the present invention includes a call unit 10, a service unit 20, a basic quantum random number generator, a twin quantum random number generator (S2), and a quantum random number processing unit ( S3) and a random number generator (S4).

The call unit 10 can transmit an arbitrary signal so that the user can call data and an encryption key to access the data.

The service unit 20 may detect a signal from the call unit 10 and provide the call unit 10 with the data requested by the user and an encryption access key for access.

The basic quantum random number generator S1 may generate the encryption access key using a quantum random number system and provide the encryption access key to the service unit 20.

Figure 3 is a flow chart of a method for generating a quantum random number encryption key according to an embodiment of the present invention.

The quantum random number encryption key generation method according to an embodiment of the present invention can generate an encryption key using a quantum system. At this time, the security of the encryption key can be further improved through additional processing by the basic quantum random number generator, the twin quantum random number generator (S2), the random number generator (S4), and the quantum random number processor (S3). .

More specifically, the basic quantum random number generator (S1) can generate an arbitrary N number of basic quantum random numbers, such as number_1, number_2 to number_n, through a flat detection method or a binarization method using ground glass.

The twin quantum random number generator (S2) can generate any N number of twin quantum random numbers, such as twin_1, twin_2 to twin_n, that can be combined with the basic quantum random number.

The N number of twin_n may be less than half of the N number of number_b.

The quantum random number processing unit (S3) is configured to match at least one of number_1 or number_n of the basic quantum random number formed by the basic quantum random number generating unit (S1) to the quantum random numbers twin_1, twin_2 to twin_2 formed by the twin quantum random number generating unit (S2). twin_n can be combined.

In contrast, the quantum random number processing unit (S3) may simultaneously combine the number_1 and the number_n with twin quantum random numbers twin_1, twin_2 to twin_n formed by the twin quantum random number generator (S2).

The random number generator (S4) can generate a random N number of random numbers, such as intentional_1, intentional_2 to intentional_n, placed between each twin quantum random number generated from the twin quantum random number generator (S2).

The random number generator (S4) determines that when the values of consecutive twin quantum random numbers are the same (e.g., twin_1=twin_2), the random number has a different value from the two twin quantum random numbers (e.g., intentional_1≠ twin_1 and twin_2), if the values of consecutive twin quantum random numbers are different (e.g., twin_1≠twin_2), the random number may have the value of any one of the two twin quantum random numbers.

It may include a reset unit that receives a reset signal every time a basic quantum random number is generated in the basic quantum random number generator (S1) and provided to the service unit 20, and the reset unit receives the reset signal according to a setting set by the user. When accumulating numbers of the first set value, the basic quantum random number is not generated by the basic quantum random number generator (S1), but is first replaced once by a twin quantum random number generated by the twin quantum random number generator (S2). You can.

Furthermore, when the reset signal accumulates the number of second set values set by the user, the basic quantum random number is not generated by the basic quantum random number generator (S1), but is generated by the random number generator (S4). It may be replaced once for the first time by a random number.

The first set value and the second set value may have arbitrary natural number values, such as 5 times, 10 times, etc., and the first set value and the second set value may be set differently by a random selection method. In contrast, the first set value and the second set value are intertwined with arbitrary functions (for example, nth-order equations such as linear functions or quadratic functions, or various known functions such as trigonometric functions), so there is a correlation. may be in

Figures 4 to 6 are diagrams showing applicable fields of the quantum random number encryption key generation method according to an embodiment of the present invention.

The quantum random number encryption key generation method according to an embodiment of the present invention can be applied to manipulate traffic signals by reflecting real-time traffic information to build a security network safe from third party hacking threats. Additionally, it can be adopted as a security method for services with a wide range of transmission channels, for example, information provision services such as personal mobility, self-driving shuttle, car sharing, etc.

The quantum random number encryption key generation method according to an embodiment of the present invention can be applied to a single node or distributed node.

When applying a single node, after setting up the QRNG hardware and workstation, a program to extract bits from the hardware can be developed, and the extracted raw data can be converted to a bytes array.

Furthermore, it can be used to create Entropy data in 1MB units, build Hbase with Entropy data storage, and build service web apps, account management, and authentication servers. Meanwhile, it is also applied to the development of token and UUID distributors, and Apache Hbase can be used to support ultra-fast, large-capacity Entropy Pool.

When applying a distributed node, it can be applied to the sub system in preparation for the expansion of concurrent users of public services, and the QRNG extraction node can be separately pushed. Meanwhile, it can be used to develop a storage function in the Entropy pool by building a Kafka Streaming server and implementing a Kafka receiver in the sub system. The remaining implementation elements of the sub system can be applied in the same way as the single node system. In other words, Kafka can be used to implement a high-capacity push distributed node service.

This embodiment is merely an illustrative explanation of the technical idea of the present invention, and those skilled in the art may make various modifications and variations of this embodiment without departing from the essential characteristics of the present invention. It would be possible.

This embodiment is not intended to limit the technical idea of the present invention, but rather to explain it, and therefore the scope of the present invention is not limited by this embodiment.

The scope of protection of the present invention should be interpreted in accordance with the claims, and all technical ideas that are equivalent or equivalent thereto should be construed as being included in the scope of rights of the present invention.

10 - Call book

20 - Service Department

S1 - Basic quantum random number generator

S2 - Twin quantum random number generator

S3 - Quantum random number processing unit

S4 - Random number generation unit

Claims (7)

1. A calling unit that transmits a random signal so that the user can call the data and an encryption key to access the data;

   A service unit that detects the signal from the calling unit and provides the calling unit with the data requested by the user and an encryption access key for accessing it, and

   A basic quantum random number generator that generates the encryption access key by a quantum random number system method and provides it to the service department.

   A quantum random number encryption key generation method comprising:
2. In paragraph 1

   The basic quantum random number generator

   A quantum random number encryption key generation method characterized by generating an arbitrary N number of basic quantum random numbers such as number_1, number_2 to number_n through a flat detection method or a binarization method using ground glass.
3. In paragraph 2

   A twin quantum random number generator that generates a random N number of twin quantum random numbers, such as twin_1, twin_2 to twin_n.

   Includes,

   A quantum random number processing unit that combines the quantum random numbers twin_1, twin_2 to twin_n formed by the twin quantum random number generator with at least one of number_1 or number_n of the basic quantum random number formed by the basic quantum random number generator.

   A quantum random number encryption key generation method comprising:
4. In paragraph 3

   Quantum random number encryption key generation method, characterized in that the N number of twin_n is less than half of the N number of number_n.
5. In paragraph 4

   The quantum random number processing unit

   A method of generating a quantum random number encryption key, characterized in that the twin quantum random numbers twin_1, twin_2 to twin_n formed by the twin quantum random number generator are simultaneously combined with the number_1 and the number_n.
6. In paragraph 5

   A random number generator that generates a random N number of random numbers, such as intentional_1, intentional_2 to intentional_n, placed between each twin quantum random number generated from the twin quantum random number generator.

   Includes,

   The random number generator

   If the values of consecutive twin quantum random numbers are the same (e.g., twin_1=twin_2), the random number has a different value from the two twin quantum random numbers (e.g., intentional_1≠twin_1 and twin_2), and the consecutive twin quantum random numbers have different values. A method of generating a quantum random number encryption key, wherein when the values of the random numbers are different (e.g., twin_1≠twin_2), the random number has the value of one of two twin quantum random numbers.
7. In paragraph 6

   A reset unit that receives a reset signal every time a basic quantum random number is generated by the basic quantum random number generator and provided to the service unit.

   Includes,

   The reset unit

   When the reset signal accumulates the number of first set values set by the user, the twin quantum random number generated by the twin quantum random number generator replaces a new basic quantum random number once, and the reset signal is converted to the second set value set by the user. A quantum random number encryption key generation method, characterized in that when the set value number is accumulated, the random number generated by the random number generator replaces a new basic quantum random number the first time.

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