KR101880935B1 - Photographing apparatus for generating digital image which can be verified by block-chain, digital image generating method using the same, and method for verifying image generated by the same - Google Patents

Abstract

A photographing apparatus connected to a block-chain network including a plurality of nodes, the photographing apparatus comprising: a photographing section having a lens to acquire image information; A storage unit storing a device ID of the photographing apparatus, a private key, and a public key forming a key pair with the private key; An image generating unit for generating a digital image using image information obtained by the photographing unit; Wherein the first unit hash value is calculated by a hash algorithm when the digital image is generated by the image generator, and the first unit hash value calculated first by the hash algorithm is N Th Nth unit hash value is calculated by the hash algorithm and the last calculated unit hash value is calculated as the final unit A sundial calculator for processing the time value; A first hash signature value obtained by digitally signing the first unit hash value with the private key, and a second hash signature value obtained by digitally signing the unit hash value, A second hash signature value indicating a time at which the generation of the digital image is terminated, and a final hash signature value obtained by digitally signing the final hash value with the private key, And a transaction generation unit for generating a transaction including the final hash signature value; And a transfer unit for transferring the transaction to the block-chain network, wherein the storage unit stores the digital image file to which the transaction is added to the digital image, A forgery verification method of the digital image generated by the method is provided.

Description

[0001] The present invention relates to a photographing apparatus for generating a digital image capable of performing forgery verification using a block chain, a digital image generating method using the same, and a verification method of the digital image generated thereby, digital image generating method using the same, and method for verifying image generated by the same}

The present invention relates to a photographing apparatus for generating a digital image capable of forgery verification using a block chain, a digital image generating method using the same, and a digital image verification method generated thereby. More specifically, A transaction is generated and transmitted to a block chain network to distribute the data in a block chain manner to each node, and a digital image file to which the transaction is added is generated, The present invention relates to a photographing apparatus for generating a digital image capable of performing forgery verification by comparing transactions distributed and stored in a digital camera, and a digital image generating method and a digital image generating method.

Recently, with the increase of violent crime, CCTV system is installed and used for the purpose of crime prevention and arresting criminals in case of crime.

Therefore, the images acquired through such CCTV systems provide crucial clues to solve crime incidents.

In addition, since such an image device provides a clue to solution of the event, most of vehicles have installed a black box for vehicles in recent years, and the images secured by the black box for vehicles are illegally interrupted, hit and run, It is a great help to judge the illegal act in the road traffic law including violation.

However, recently, there has been a problem in that it causes great confusion in the judgment of important crime such as forgery of the image of the black box for the vehicle, making the estimation of the victim difficult, destroying and destroying the original image, Are continuously occurring.

In addition, in the case of the images acquired through the CCTV system, the problem of forgery and falsification must be solved in order to solve the crime case clearly.

On the other hand, a block chain is stored in a link-based distributed data storage environment in which a small amount of data, called a block, is managed based on a peer-to-peer (P2P) It is a data forgery prevention technology based on distributed computing technology that can not be arbitrarily modified by anyone but can be viewed by anyone.

It is fundamentally a form of distributed data storage technology, which is a change list that records continuously changing data in all participating nodes, and is designed to be impossible to arbitrarily manipulate by the operator of the distributed node.

Accordingly, it is required to develop a technique capable of preventing forgery and falsification of images by combining such a block chain with a photographing device for generating digital images, a digital image generating method, and a digital image verification method.

Korean Patent No. 10-1665199 (October 10, 2016)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a photographing apparatus for generating a digital image capable of forgery verification using a block chain, a digital image generating method using the same, and a digital image verification method It is for that purpose.

A photographing apparatus according to the present invention is a photographing apparatus connected to a block-chain network including a plurality of nodes, comprising: a photographing unit having a lens to acquire image information; A storage unit storing a device ID of the photographing apparatus, a private key, and a public key forming a key pair with the private key; An image generating unit for generating a digital image using image information obtained by the photographing unit; Wherein the first unit hash value is calculated by a hash algorithm when the digital image is generated by the image generator, and the first unit hash value calculated first by the hash algorithm is N Th Nth unit hash value is calculated by the hash algorithm and the last calculated unit hash value is calculated as the final unit A sundial calculator for processing the time value; A first hash signature value obtained by digitally signing the first unit hash value with the private key, and a second hash signature value obtained by digitally signing the unit hash value, A second hash signature value indicating a time at which the generation of the digital image is terminated, and a final hash signature value obtained by digitally signing the final hash value with the private key, And a transaction generation unit for generating a transaction including the final hash signature value; And a transfer unit for transferring the transaction to the block-chain network, wherein the storage unit stores the digital image file to which the transaction is added.

In the photographing apparatus according to the present invention, the storage unit may include a key storage unit, and the private key may be stored in the key storage unit.

In the photographing apparatus according to the present invention, the key storage unit may be provided as a secure element.

In the photographing apparatus according to the present invention, the key storage unit may be provided in a removable form such as a USIM, a SIM, a micro SD, a memory card, and the like.

In the photographing apparatus according to the present invention, the digital image may be a moving image, and the sum calculator may calculate a unit time value for each frame of the digital image.

In the photographing apparatus according to the present invention, the storing unit stores a block chain address indicating a virtual position on the block chain network of the photographing apparatus, and the transaction generating unit may generate a transaction further including the block chain address .

In the photographing apparatus according to the present invention, the block-chain address may be generated using the public key.

In the photographing apparatus according to the present invention, the transaction generating unit may generate a transaction further including the first timestamp value and the second timestamp value.

In the photographing apparatus according to the present invention, the sum calculator can calculate the unit hash value using the SHA-256 hash algorithm.

A digital image generating method according to the present invention is a digital image generating method for generating digital images by using image information obtained by an image pickup unit having a lens and calculating a unit time value in units of a predetermined capacity when the digital image is generated, The calculated first unit hash value is calculated by a hash algorithm, and the Nth unit hash value calculated as the N-th unit hash value is calculated as the (N-1) th N-1 unit hash value And calculating the Nth unit capacity data by a hash algorithm; A first time stamp value indicating a time at which generation of the digital image is started and a first hash signature value obtained by electronically signing the first unit hash value with a private key, A second time stamp value indicating a time at which the generation of the digital image is terminated, and a final hash signature value in which the last unit hash value, which is the last calculated unit hash value, A hash signature value generation step of generating a hash signature value; Generating a transaction including the device identity, the first hash signature value, and the final hash signature value; A transaction transfer step of transferring the transaction to a block-chain network; And an image storing step of storing the digital image file to which the transaction is added in the digital image.

The method of generating a digital image according to the present invention may further include a key pair generation step of generating a private key and a public key forming a key pair with the private key before the digital image generation step.

In the digital image generation method according to the present invention, in the key pair generation step, the private key may be stored in a secure element.

In the digital image generation method according to the present invention, the secure element may be a removable form such as a USIM, a SIM, a micro SD, a memory card, or the like.

The digital image generating method according to the present invention may further include a block chain address generating step of generating a block chain address indicating a virtual position of the photographing apparatus on the block chain network using the public key after the key pair generating step have.

In the digital image generation method according to the present invention, the transaction generation step may be a step of generating a transaction further including the block chain address.

In the digital image generation method according to the present invention, the transaction generation step may be a step of generating a transaction further including the first timestamp value and the second timestamp value.

In the digital image generation method according to the present invention, the digital image is a moving image, and the digital image generation step may calculate a unit time value in units of frames of the digital image.

In the digital image generating method according to the present invention, the digital image generating step may be a step of calculating a unit hash value by an SHA-256 hash algorithm.

A method for verifying a digital image according to the present invention is a method for verifying whether a digital image has been tampered with, including a device ID, a first time stamp value indicating a time at which generation of a digital image is started, a first hash signature value, And a final hash signature value, the method comprising the steps of: calculating a verification value in units of a predetermined capacity of the digital image file, Wherein the first verification hash value of the digital image is calculated by a hash algorithm and the Nth verification hash value of the digital image is calculated by the N-1th calculated N- Calculating a Nth unit capacity data by a hash algorithm to calculate a first verification hash value and a last calculated validation hash value; A first hash signature value verification step of verifying the first hash signature value included in the transaction using a public key using the first verification hash value; A final hash signature value validation step of validating the final hash signature value included in the transaction with a public key using the final validation hash value; And a transaction verification step of determining whether or not the same transaction as the transaction is in a block chain distributed and stored in a block-chain network.

In the digital image forgery verification method according to the present invention, the first hash signature value verification step may include a first hash signature value verification step using a device ID, a first time stamp value, And verifying the signature value with the public key.

In the digital image forgery verification method according to the present invention, the final hash signature value verification step may include a step of verifying the final hash signature value using a device ID, a second timestamp value, And verifying the value with the public key.

In the digital image forgery verification method according to the present invention, the transaction further includes a block chain address, and the transaction verification step searches for a block chain address included in the transaction and a first timestamp value, It may be judged whether or not the transaction is in a block chain distributed and stored in the block chain network.

In the digital image forgery verification method according to the present invention, the block chain address included in the transaction may be generated by the public key.

According to the present invention, a transaction of a digital image is generated by using a hash algorithm, and the transaction is transmitted to a block-chain network, distributedly stored in blocks in a form of a block chain, and a digital image file to which the transaction is added is generated , It is possible to verify whether a digital image file is forged or falsified by comparing a transaction added to a digital image file and a transaction stored and distributed in a block chain network.

1 is a conceptual diagram of a block-chain network to which a photographing apparatus according to an embodiment of the present invention is connected.
2 is a conceptual diagram of a photographing apparatus according to an embodiment of the present invention;
3 is a flowchart of a digital image generating method according to an embodiment of the present invention.
4 is a flowchart illustrating a method of forgery verification of a digital image according to an exemplary embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may be easily suggested, but are also included within the scope of the invention.

In the following description, the same reference numerals are used to designate the same components in the same reference numerals in the drawings.

1 is a conceptual diagram of a block-chain network 10 to which a photographing apparatus 100 according to an embodiment of the present invention is connected.

Referring to FIG. 1, a photographing apparatus 100 according to an embodiment of the present invention may be connected to a block-chain network 10 including a plurality of nodes 11.

At this time, the photographing apparatus 100 according to an embodiment of the present invention is a device capable of photographing an image and generating a digital image file, and is a computer having a digital camera, a CCTV, a vehicle black box, a smart phone, And the like.

Meanwhile, the above-described apparatuses are merely examples of various forms of the photographing apparatus 100 according to an embodiment of the present invention, and the form of the apparatus is not limited thereto.

On the other hand, when the photographing apparatus 100 according to an embodiment of the present invention is in the form of a computer equipped with a camera, the photographing apparatus 100 may include a node (not shown) included in the block- 11).

2 is a conceptual diagram of a photographing apparatus 100 according to an embodiment of the present invention.

2, a photographing apparatus 100 according to an exemplary embodiment of the present invention includes a photographing unit 110, a storage unit 120, an image generating unit 130, a hash calculation unit 140, a transaction generating unit 150 ), And a transmission unit 160.

The photographing unit 110 may include a lens to photograph an image.

That is, the photographing unit 110 may include a lens to obtain image information.

The storage unit 120 may store a device ID, a private key, and a public key of the photographing apparatus 100.

In addition, the storage unit 120 may store a digital image file.

At this time, the private key and the public key may form a key pair.

That is, the data encrypted with the private key can be decrypted with the public key, and the data encrypted with the public key can be decrypted with the private key. have.

Meanwhile, the storage unit 120 may include a key storage unit 121, and the key storage unit 121 may be provided as a secure element.

In other words, the key storage unit 121 may be provided in a detachable chip form or the like, and more specifically, it may be provided in a detachable form such as a USIM, a SIM, a micro SD, a memory card, or the like.

However, the form of the key storage unit 121 is not limited to the above-described form, but may be provided as various types of secure elements applicable to ordinary technicians.

At this time, the private key may be stored in the key storage unit 121. By thus allowing the private key to be stored in a secure element, key can be prevented from being exposed.

The image generating unit 130 may generate a digital image using the image information obtained by the photographing unit 110.

At this time, the digital image generated by the image generating unit 130 may be a moving image including a plurality of frames, or a still image which is still image information.

When the digital image is generated in the image generator 130, the hash calculator 140 may calculate a unit time value in units of a predetermined capacity.

Here, the first unit hash value calculated first by the hash value calculator 140 may be calculated by a hash algorithm based on the first unit capacity data of the digital image.

Then, the hash calculation unit 140 may calculate the second unit hash value by calculating the first unit hash value and the second unit hash value using a hash algorithm.

In this way, it is possible to calculate the third, fourth, ..., Nth unit hash value repeatedly.

In other words, in the sum calculator 140, the first unit hash value calculated first is calculated by a hash algorithm, and the Nth unit hash value May calculate the (N-1) th N-th unit hash value and the N-th unit capacity data by the hash algorithm.

At this time, the sum calculator 140 may process the finally calculated unit hash value as a final hash value.

Here, the case where the unit capacity is 100 KB, for example, will be described. The sum calculator 140 calculates the first unit hash value by calculating the first 100 KB data using the hash algorithm, And the second 100 KB data are calculated by the hash algorithm to obtain the second unit hash value and the third unit hash value and the third 100 KB data are calculated by the hash algorithm to obtain the third unit hash value, The Nth unit hash value can be obtained in units of 100 KB, and the final unit hash value can be set as the final unit hash value.

Meanwhile, when the digital image is a moving image, the digits calculator 140 may calculate a time value per frame of the digital image.

On the other hand, the hash algorithm that the hash calculator 140 uses to calculate the unit hash value may be the SHA-256 hash algorithm.

The transaction generation unit 150 generates a transaction including a block chain address, a device ID, a first time stamp value, a first hash signature value, a second time stamp value, and a final hash signature value can do.

Here, the block-chain address may be a virtual location on the block-chain network 10 of the photographing apparatus 100, and may be stored in the storage unit 120.

In addition, the block chain address may be generated by the public key.

That is, the storage unit 120 may store the block chain address generated by the public key.

Meanwhile, the first timestamp value may be a value indicating a time at which the generation of the digital image is started, and the second timestamp value may be a value indicating a time at which the generation of the digital image is terminated.

On the other hand, the first signature value may be an electronic signature of the device ID, the first timestamp value, and the first unit hash value with the private key, The value may be an electronic signature of the device ID, the second timestamp value, and the final unit hash value with the private key.

In other words, the transaction generating unit 150 generates a first hash signature value by digitally signing the device ID, the first time stamp value, and the first unit hash value with the private key , The device ID, the second time stamp value, and the final unit hash value with the private key to generate a final hash value, and transmits the block chain address, the device ID ), A transaction including the first timestamp value, the first hash signature value, the second timestamp value, and the final hash signature value.

Here, the storage unit 120 may store a digital image file to which the transaction is added to the digital image.

The transfer unit 160 may transmit the transaction to the block-chain network 10.

In more detail, the transmission unit 160 may transmit the transaction to at least one or more nodes 11 on the block-chain network 10.

Here, the node 11 having received the transaction generates a block including the transaction, and then transmits the block including the transaction to each node 11 included in the block-chain network 10 The updated block chain may be formed by combining the blocks in a distributed block chain so that each block included in the block chain network 10 is updated with each node 11 ). ≪ / RTI >

As described above, according to the photographing apparatus 100 according to the embodiment of the present invention, a digital image file to which a transaction is added is stored in a digital image, and the transaction is transmitted to the block- Chain nodes 10 in a block chain and distributedly stored in each of the nodes 11 so that the transactions included in the digital image file and the distributed storage of the transactions included in the nodes 11 of the block- It is possible to confirm whether the digital image file has been forged or altered since the digital image file was first created.

3 is a flowchart of a digital image generation method (S100) according to an embodiment of the present invention.

Referring to FIG. 3, a digital image generation method S100 according to an exemplary embodiment of the present invention includes a key pair generation step S110, a block chain address generation step S120, a digital image generation step S130, A creation step S140, a transaction creation step S150, a transaction transmission step S160, and an image storage step S170.

The key pair generation step S110 may be a step of generating a private key and a public key.

Here, the private key and the public key can be a key pair, that is, the data encrypted with the private key can be decrypted with the public key , And the data encrypted with the public key may be decrypted with the private key.

Meanwhile, in the key pair generation step S110, the generated private key and the public key may be stored in a secure element.

In other words, the secure element may be provided in the form of a removable chip or the like, and more specifically, it may be provided in the form of a USIM, a SIM, a micro SD, a memory card, or the like.

However, the form of the secure element is not limited to the above-described form, and may be provided as various types of secure elements that can be applied by a typical technician.

As described above, in the key pair generation step (S110), the private key is stored in a secure element, thereby preventing the private key from being exposed.

The block chain address generation step (S120) may be a step of generating a block chain address using the public key.

At this time, the block-chain address may be a value indicating a virtual position of the photographing apparatus 100 on the block-chain network.

The digital image generation step S130 includes the steps of generating a digital image using the image information acquired by the photographing unit 110 having a lens and calculating a time value per unit of a predetermined capacity when the digital image is generated, Lt; / RTI >

At this time, in the digital image generation step (S130), the first unit hash value calculated first is calculated by a hash algorithm, and the first unit hash value The second unit capacity data is calculated by the hash algorithm to calculate the second unit hash value, and the third, fourth, ..., Nth unit hash value can be repeatedly calculated in this manner.

In other words, in the digital image generation step (S130), the first unit hash value calculated first is calculated by the hash algorithm of the first unit capacity data of the digital image, The time value can be calculated by the hash algorithm using the (N-1) th calculated N-1 unit hash value and the Nth unit capacity data.

At this time, the last calculated unit hash value may be the final hash value.

In the digital image generation step (S130), first 100 KB data is calculated by a hash algorithm to obtain a first unit hash value, and the first unit hash value The second unit hash value and the third 100KB data are calculated by the hash algorithm to obtain the second unit hash value and the third unit hash value is calculated using the hash algorithm to obtain the third unit hash value, Method, the Nth unit hash value can be obtained in units of 100 KB, and the final unit hash value can be set as the final unit hash value.

Meanwhile, in the digital image generation step (S130), when the digital image is a moving image, a time value may be calculated in units of frames of the digital image.

On the other hand, in the digital image generation step (S130), the hash algorithm used for calculating the unit hash value may be the SHA-256 hash algorithm.

The hash signature value generation step (S140) may be a step of generating the first hash signature value and the final hash signature value.

Here, the first hash signature value may include a device ID of the photographing apparatus 100, a first time stamp value indicating a time at which generation of the digital image is started, It may be digitally signed with a private key.

In addition, the final hash signature value includes a device ID of the photographing apparatus 100, a second time stamp value indicating a time at which the generation of the digital image is ended, and a final unit hash value, It may be an electronic signature.

The transaction generation step S150 includes the block chain address, the device ID, the first timestamp value, the first hash signature value, the second timestamp value, and the final hash value A transaction may be generated.

The transaction transfer step (S160) may be the step of transferring the transaction to the block-chain network (10). .

More specifically, the transaction transfer step (S160) may be a step of transmitting the transaction to at least one or more nodes (11) on the block-chain network (10).

Herein, the node 11 receiving the transaction generates a block including the transaction, and then transmits the block including the transaction to each node 110 included in the block-chain network 10 The updated block chain may be formed by combining the blocks in a distributed block chain so that each block included in the block chain network 10 is updated with each node 11 ). ≪ / RTI >

The image storage step S170 may be a step of storing the digital image file in which the transaction is added to the digital image.

As described above, according to the digital image generation method (S100) of the embodiment of the present invention, a digital image file to which a transaction is added is stored in the digital image, the transaction is transferred to the block chain network , And is included in the block chain on the block chain network 10 and distributedly stored in each of the nodes 11 so that the transaction included in the digital image file and the transaction included in each node 11 of the block- If a transaction on the block chain in which the digital image file is distributed is stored, it can be confirmed whether the digital image file has been forged or altered since the digital image file was first generated.

The key pair generation step S110 and the block chain address generation step S120 may be performed only once before the imaging device 100 first captures an image.

In other words, the private key, the public key, and the block chain address generated in the block chain address generation step S120, generated in the key pair generation step S110, And can be continuously used in image generation.

That is, the key pair generating step (S110) and the block chain address generating step (S120) may be performed only once for each photographing apparatus.

4 is a flowchart of a digital image forgery verification method (S200) according to an exemplary embodiment of the present invention.

Referring to FIG. 4, a digital image forgery verification method S200 according to an exemplary embodiment of the present invention includes a verification value calculation step S210, a first hash signature value verification step S220, A verification step S230, and a transaction verification step S240.

Meanwhile, the digital image forgery verification method S200 according to an exemplary embodiment of the present invention verifies whether a digital image file generated or generated by the digital image generation method S100 is forged or modified And a method of forgery verification of a digital image.

That is, the digital image forgery verification method S200 according to an exemplary embodiment of the present invention includes a device ID, a first time stamp value indicating a time at which generation of the digital image is started, a first hash signature value, A second timestamp value indicating the time at which the generation of the digital image file is completed, and a forgery and tamper verification method of the digital image that verifies the forgery and corruption of the digital image file attached with the transaction including the final hash signature value.

The verification hash value calculation step (S210) may be a step of calculating a verification value at a predetermined capacity unit of the digital image file.

At this time, in the verification value calculation step (S210), the first verification hash value that is calculated first calculates the first unit capacity data of the digital image by the hash algorithm, Value is calculated by the hash algorithm using the N-1th calculated N-1 verification hash value and the Nth unit capacity data, and the first verification hash value and the final verification verification value And calculating the verification hash value.

That is, the method of calculating the verification solution value in the verification solution value calculation step (S210) may be the same as the method of calculating the unit solution value in the digital image generation method (S100).

The first hash signature value verification step (S220) may be a step of verifying the first hash signature value included in the transaction with a public key.

Here, in order to verify the first hash signature value with a public key, a verify function that is conventionally used for verification may be used.

At this time, the verification function may verify the first hash signature value with the public key using a device ID, a first stamp value, and a first verification hash value.

The final hash signature value verification step (S230) may be a step of verifying the final hash signature value included in the transaction with a public key.

Here, a verify function, which is conventionally used for verification, may be used to verify the final hash signature value with the public key.

At this time, the verification function can verify the final hash signature value with the public key using a device ID, a second stamp value, and a final verification hash value.

In the transaction verification step S240, whether the same transaction as the transaction attached to the digital image file is in a block chain distributed and stored in the block chain network 10 . ≪ / RTI >

Meanwhile, the transaction may further include a block chain address generated by the public key. In the transaction verification step S240, a block chain address included in the transaction And a first timestamp value to quickly determine whether or not the same transaction as the transaction is in a block chain distributed and stored in the block chain network 10. [

As described above, according to the digital image forgery verification method (S200) of the embodiment of the present invention, the first hash signature value verification step (S220) and the final hash signature value verification step (S230) It is possible to judge whether or not a slight modification has been made to the digital image file, and it is possible to judge whether the transaction attached to the digital image file is forged or not through the transaction verification step (S240) can do.

While the invention has been shown and described with reference to certain embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It will be obvious to those of ordinary skill in the art.

10: Block Chain Network 11: Node
100: photographing apparatus according to an embodiment of the present invention
110: photographing unit 120:
121: key storage unit 130:
140: Sundial calculator 150: Transaction generator
160:
S100: Digital image generation method according to an embodiment of the present invention
S110: key pair generation step S120: block chain address generation step
S130: Digital image generation step S140: Hash signature value generation step
S150: Transaction creation step S160: Transaction transfer step
S170: Image storage step
S200: Forgery verification method of a digital image according to an embodiment of the present invention
S210: Calculation of verification hash value Step S220: Verification of first hash signature value
S250: verification of signature value at final hash value step S260: transaction verification step

Claims (23)

1. A photographing apparatus connected to a block-chain network including a plurality of nodes,
A photographing unit provided with a lens to acquire image information;
A storage unit storing a device ID of the photographing apparatus, a private key, a public key forming a key pair with the private key, and a block chain address generated by using the public key and representing a virtual location on the block chain network of the photographing apparatus, ;
An image generating unit for generating a digital image using image information obtained by the photographing unit;
Wherein the first unit hash value is calculated by a hash algorithm when the digital image is generated by the image generator, and the first unit hash value calculated first by the hash algorithm is N Th Nth unit hash value is calculated by the hash algorithm and the last calculated unit hash value is calculated as the final unit A sundial calculator for processing the time value;
A first hash signature value obtained by digitally signing the first unit hash value with the private key, and a second hash signature value obtained by digitally signing the unit hash value, A second hash signature value indicating a time at which the generation of the digital image is terminated, and a final hash signature value obtained by digitally signing the final hash value with the private key, A transaction generator for generating a transaction including the final hash signature value, the block chain address, the first timestamp value, and the second timestamp value; And
And a transfer unit for transferring the transaction to the block-chain network,
Wherein the storage unit stores a digital image file to which the transaction is added to the digital image.
The method according to claim 1,
Wherein the storage unit has a key storage unit, and the private key is stored in the key storage unit.
3. The method of claim 2,
Wherein the key storage unit is provided as a secure element.
The method of claim 3,
Wherein the key storage unit is provided in a removable form such as a USIM, a SIM, a Micro SD, a memory card, and the like.
The method according to claim 1,
Wherein the digital image is a moving image,
Wherein the sum calculator calculates a unit time value in units of frames of the digital image.
delete delete delete The method according to claim 1,
Wherein the sum calculator calculates the unit solution value by the SHA-256 hash algorithm.
A key pair generating step of generating a private key and a public key forming a key pair with the private key;
A block chain address generating step of generating a block chain address indicating a virtual position of the photographing apparatus on the block-chain network using the public key;
A digital image is generated using the image information obtained by the photographing unit having the lens, and when the digital image is generated, the time value is calculated in a unit of a predetermined capacity, The first unit capacity data of the digital image is calculated by the hash algorithm, and the Nth unit hash value calculated as the N-th unit is calculated by using the (N-1) th calculated N-1 unit hash value and the Nth unit capacity data as the hash algorithm A digital image generation step of calculating a digital image;
A first time stamp value indicating a time at which generation of the digital image is started and a first hash signature value obtained by electronically signing the first unit hash value with a private key, A second time stamp value indicating a time at which the generation of the digital image is terminated, and a final hash signature value in which the last unit hash value, which is the last calculated unit hash value, A hash signature value generation step of generating a hash signature value;
Generating a transaction including the device identity, the first hash signature value, the block chain address, the final hash signature value, the first timestamp value, and the second timestamp value;
A transaction transfer step of transferring the transaction to a block-chain network; And
And storing the digital image file to which the transaction is added in the digital image.
delete 11. The method of claim 10,
And in the key pair generation step, the private key is stored in a secure element.
13. The method of claim 12,
Wherein the secure element is a removable form such as a USIM, a SIM, a Micro SD, a memory card, and the like.
delete delete delete 11. The method of claim 10,
Wherein the digital image is a moving image,
Wherein the step of generating digital images comprises calculating a time value per unit of a frame of the digital image.
11. The method of claim 10,
Wherein the digital image generation step is a step of calculating a unit solution value by an SHA-256 hash algorithm.
A first hash signature value, a second time stamp value indicating a time at which the generation of the digital image ends, a final hash signature value, and a public key A method for forgery verification of a digital image that verifies forgery and falsification of a digital image file to which a transaction including a block chain address generated by the transaction is attached,
Wherein the first verification hash value calculated first by the predetermined capacity unit of the digital image file is obtained by calculating a first unit capacity data of the digital image using a hash algorithm, The hash value is calculated by the hash algorithm using the (N-1) th computed N-1 verification hash value and the Nth unit capacity data, and calculates the first verification hash value and the last calculated validation hash value A verification hash value calculation step;
A first hash signature value verification step of verifying the first hash signature value included in the transaction using a public key using the first verification hash value;
A final hash signature value validation step of validating the final hash signature value included in the transaction with a public key using the final validation hash value; And
And a transaction verification step of searching for the block chain address included in the transaction and the first timestamp value to determine whether or not the same transaction as the transaction is in a block chain distributed and stored in a block chain network, Forgery verification method.
20. The method of claim 19,
The first hash signature value verification step is a step of verifying the first hash signature value using a public key using a device ID, a first time stamp value, and the first verification hash value. A method of forgery verification of a digital image.
20. The method of claim 19,
Wherein the final hash signature value verification step is a step of verifying the final hash signature value with a public key using a device ID, a second time stamp value, and the final verification hash value A method of forgery verification of digital images.
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