KR100846068B1 - Apparatus for encrypting data and method thereof - Google Patents

Abstract

A data encryption device and method thereof are disclosed. An apparatus for encrypting data according to the present invention is a holographic optical information storage medium system, comprising: an encryption processing unit for outputting data to be recorded on a holographic optical information storage medium in combination with an arbitrary encryption kit value, and encrypted by the encryption processing unit. An encoder for converting data into a signal that can be processed by a computer, and a decoder for converting the data encoded by the encoder into a signal that can be processed on a reproduction medium, and the data and encryption processing unit decoded by the decoder. And an encryption decryption unit for reproducing data by combining the encryption kit values. According to the present invention, since data can be reproduced only in the same system when information is recorded on the holographic optical information storage medium, the data can be encrypted and stored.

Encryption, Holographic, Storage, Preprocessing, Keys, Adder

Description

Apparatus for encrypting data and method

1 is a diagram briefly illustrating a coding operation for a data recording and reproducing apparatus of a general holographic system.

2 is a diagram of a data encryption apparatus of a holographic optical information storage medium system according to a preferred embodiment of the present invention.

3 is a view illustrating in detail the preprocessor and the post processor shown in FIG.

4 is a diagram illustrating data processing of a random generator according to a preferred embodiment of the present invention.

5 is an exemplary diagram of an encoding pattern performed according to a preferred embodiment of the present invention.

FIG. 6 is a diagram illustrating a pattern when the pattern of FIG. 5 is encoded into another initial value.

* Brief description of symbols for the main parts of the drawings *

11: preprocessor 12: encoder

13: channel 14: decoder

15: post-processing unit

The present invention relates to a holographic optical information storage medium system, and more particularly, to a data encryption apparatus and method for providing encryption means that can be used only in the system.

Today, as the high-speed Internet is rapidly developing and changing from the analog to the digital age, many analog media and other contents are digitizing.

Unlike analog, digital signals are easy to copy and store, providing a lot of convenience for users. However, since digital signals can be copied exactly like the originals, illegal copying of copyrighted digital contents is always exposed. Piracy is a very serious problem because it blocks the author's legitimate income and eliminates the desire for creation.

Digital data distributed in combination with mathematical data encryption via media currently in use is not protected from unauthorized copying.

Cracking mathematically encrypted data is a matter of hardware cost. It may also be impossible to encrypt data that is typically processed in real time. For legitimate users of such digital data, a data reading device with an appropriate decryption system is required.

Continuous decryption algorithms cannot be very secure because they do not have enough time to decrypt the data. In addition, when a legitimate user wants to retrieve data, distributing and accessing the decryption key always causes considerable inconvenience. In particular, if the data is not a special secret to the customer but a secret to a data provider such as an audio CD disc, the customer may not always take this inconvenience. Therefore, you will not purchase a digital data protection system that requires the entry of a personal access code or other similar actions.

1 is a diagram briefly illustrating a coding operation for a data recording and reproducing apparatus of a general holographic system. As shown in Fig. 1, a conventional holographic optical storage medium system records a 2D image during data recording and decodes and reproduces the data into a 2D image during playback. After data is encoded by the encoder 1 at the time of data recording, the data of the same channel is decoded by the decoder 3 with the same code value at the time of reproduction.

In this case, since the recorded data is decoded in the same manner as the encoding method, it is difficult to prevent illegal copying of the CD contents through a commercially available CD recording apparatus.

An object of the present invention for solving the above problems is to provide a data encryption apparatus and method for providing a data encryption key only to the system to operate only in the system.

According to an aspect of the present invention, there is provided a data encryption apparatus comprising: an encryption processing unit for outputting data to be recorded on a holographic optical information storage medium in combination with an arbitrary encryption kit value; An encoder for converting the data encrypted by the encryption processing unit into a signal that can be processed by a computer; A decoder for converting the data encoded by the encoder into a signal that can be processed in a reproduction medium; And an encryption decryption unit that reproduces the data by combining the data decoded by the decoder and the encryption kit value used in the encryption processing unit.

The encryption processing unit may exclusively OR the data generated for each clock with an arbitrary encryption code generated through a random data generator.

The encryption decryption unit exclusively ORs data generated every clock with an arbitrary encryption code generated by the random data generator of the encryption processing unit. The random data generator generates random data by the same number of bits as the number of data bits generated for each clock. Preferably, the random data generator uses a shift register. When the bits of the shift register are smaller than the number of data bits generated for each clock, the random data generator selects a bit of the shift register a predetermined number of times. Iteratively outputting the same bit as the number of data bits generated for each clock. The shift register installs an adder in at least one position when shifting the value of each bit. The shift register is preferably such that the position of the adder can be changed by user setting.

Another data encryption apparatus of the present invention for achieving the above object is a holographic optical information storage medium system, comprising: an encoder for converting data to be recorded on the holographic optical information storage medium into a computer processable signal; An encryption processing unit for outputting a combination of data encoded by the encoder and an arbitrary encryption kit value; An encryption decryption unit that reproduces data by combining the data output from the encryption processing unit and the encryption kit value used in the encryption processing unit; And a decoder for converting the data decoded by the encryption decryption unit into a signal that can be processed in a reproduction medium.

A data encryption method according to the present invention for achieving the above object is a method for recording information on a holographic optical information storage medium and reproducing in a storage medium system, wherein the data to be recorded on the holographic optical information storage medium is arbitrary. Outputting an output in combination with an encryption kit value of? An encoding step of converting the encrypted output data into a signal that can be processed by a computer; Decoding the encoded data into a signal that can be processed in a reproduction medium; And reproducing the data by combining the decoded data and the encryption kit value used in the encryption process.

Another data encryption method according to the present invention for achieving the above object is a method for recording information on a holographic optical information storage medium and reproducing in a storage medium system, the data to be recorded on the holographic optical information storage medium Converting the signal into a computer processable signal; An encrypted output step of combining the converted data with an arbitrary encryption kit value and outputting the result; Decrypting the data by combining the data output in the encryption processing step and the encryption kit value used in the encryption processing; And converting the decrypted data into a signal that can be processed in a reproduction medium.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

In the present invention, when data is recorded in any storage, the data can be reproduced only in a system that was used at the time of recording the data in the storage. In this case, when data is recorded, the data is encoded by combining with an arbitrary encryption key, and then extracted by combining with the encryption key to safely reproduce the data.

In the present invention, an example of extracting data by combining an encryption key before encoding the data and combining the encryption key after decoding is performed. However, the encryption step is performed after encoding and the encryption step is performed before decoding. Can be.

The key point of the present invention is to perform the encryption process at the time of recording and decryption of the encryption key at the time of playback regardless of the process of encoding and decoding.

2 is a diagram of a data encryption apparatus of a holographic optical information storage medium system according to a preferred embodiment of the present invention. Referring to FIG. 2, a pre-processing unit 11 for performing encryption before encoding data to be recorded, and a signal capable of using the data encrypted and output from the preprocessor 11 in a computer. The encoder 12 to encode the video signal, the decoder 14 to decode the corresponding channel 13 to be reproduced into a signal that can be used in the playback medium, and the data and preprocessing unit 11 outputted through the decoder 14. And a post-processing unit 15 for reproducing the data by combining the encryption keys used.

3 is a view illustrating in detail the preprocessor and the post processor shown in FIG.

As shown in FIG. 3, the preprocessor 11 outputs an exclusive OR with data generated for each clock and arbitrary encryption codes generated through random data generators 111 and 151. . The encryption code generated by the random data generator 111 is then used by the post-processing unit 15 for decryption.

The post processor 15 performs exclusive OR on the data generated for each clock with the encryption code generated and used by the random data generator 111 of the pre processor 11.

The random data generator should generate random data by the same number of bits as the number of data bits generated per clock. If the random data bits are smaller than the number of data bits generated for each clock, the generated bits must be repeated a predetermined number of times to output the same bits as the number of data bits generated for each clock.

In general, a shift register is used to generate random data, which is a principle of shifting each bit of the register back or forward one bit at the next clock.

4 is a diagram illustrating data processing of a random generator according to a preferred embodiment of the present invention. In FIG. 4, a 3-bit (R1, R2, R3) shift register is taken as an example. In FIG. 4, the value output from the R1 flip-flop and the value output from the R3 flip-flop are added and used as the R1 value of the next clock. The value output from R1 is P2, the value output from R2 is P3, and the value output from R3 is P1, which is the value obtained by adding P4, P2 and P4.

By default, P2, P3, and P4 are set to '1,1,1'.

If the initial values (P2, P3, P4) are set to (0, 0, 0), all the values come out as 0, so there is no meaning because data can be reproduced in any system.

Seven different data are outputted as a result of the operation of the 3-bit shift register. Repeat this value three times to get 21 bits.

Using 8-bit shift registers, we get 255 different data.

In addition, in order to increase the degree of encryption, the random data generator may install at least one adder between the shift registers.

It can be seen that it is more complicated to predict which value the bit value of the register will be based on the position of the adder. Therefore, it is desirable for the shift register to change the position of the adder by user setting. If the position of the adder is changed by the user setting, the structure of the random data generator is changed for each system, and thus data can be reproduced only in the corresponding system.

If the structure of the random data generator, that is, the location of the adder, is changed, the data recorded by the system A cannot be confirmed by the same password in the system B.

And if you want to play the data on the same system of random data generator, if the user changes the initial value and uses it, it is the same as the user setting the password when recording the data. do.

Therefore, the effect of double encryption of data occurs.

Hereinafter, the data format encoded by the apparatus will be described as an example.

5 is a diagram illustrating an encoding pattern performed according to a preferred embodiment of the present invention, and FIG. 6 is a diagram illustrating a pattern when the pattern of FIG. 5 is encoded with another initial value.

Referring to FIG. 5, 20 bits are generated for each clock from a random data generator to encode a result of an exclusive OR of data and a random data generator bit for each clock.

If the encoded pattern as described above is encoded with different initial values, the encoded pattern is encoded in a completely different pattern as shown in FIG. 6.

In FIG. 2, the data is preprocessed by combining the encryption key before encoding the data, and the data is extracted by combining the encryption key used during encoding after decoding the data.

Unlike the above method, after encoding the data, the data can be encrypted by combining with the encryption key, and the decrypted data can be reproduced by combining the encryption key used during encoding before decoding.

As described above, the present invention can reproduce the data only in the same system when recording the information on the holographic optical information storage medium, which has the effect of encrypting and storing the data.

In addition, since the initialization value can be set as a password when recording, even if the same system can not play the data without knowing the password, the encryption effect is maximized.

Claims (11)

A holographic optical information storage medium system, An encryption processing unit for outputting data to be recorded on the holographic optical information storage medium in combination with an arbitrary encryption kit value; An encoder for converting the data encrypted by the encryption processing unit into a signal that can be processed by a computer; A decoder for converting the data encoded by the encoder into a signal that can be processed in a reproduction medium; And An encryption decryption unit that reproduces the data by combining the data decoded by the decoder and the encryption kit value used in the encryption processing unit, The encryption processing unit And exclusively ORing data generated every clock with an arbitrary encryption code generated through a random data generator. delete The method of claim 1, wherein the decryption unit And exclusively ORing data generated every clock with an arbitrary encryption code generated by the random data generator of the encryption processing unit. The method of claim 3, wherein the random data generator A data encryption device, characterized in that for generating random data by the same number of bits as the number of data bits generated for each clock. The method of claim 4, wherein the random data generator A data encryption device using a shift register. The method of claim 5, wherein the random data generator When the bits of the shift register are smaller than the number of data bits generated per clock, And repeating a bit of the shift register a predetermined number of times and outputting the same bit as the number of data bits generated for each clock. 6. The shift register of claim 5, wherein the shift register is And an adder in at least one position when shifting the value of each bit. 8. The shift register of claim 7, wherein the shift register is A data encryption device, characterized in that the position of the adder can be changed by user setting. A holographic optical information storage medium system, An encoder for converting data to be recorded on the holographic optical information storage medium into a signal which can be processed by a computer; An encryption processing unit for outputting a combination of data encoded by the encoder and an arbitrary encryption kit value; An encryption decryption unit that reproduces data by combining the data output from the encryption processing unit and the encryption kit value used in the encryption processing unit; And A decoder for converting the data decrypted by the encryption decryption unit into a signal that can be processed in a reproduction medium, The encryption processing unit And exclusively ORing data generated every clock with an arbitrary encryption code generated through a random data generator. A method of recording information on a holographic optical information storage medium and reproducing in a storage medium system, the method comprising: An encryption output step of outputting data to be recorded on the holographic optical information storage medium in combination with an arbitrary encryption kit value; An encoding step of converting the encrypted output data into a signal that can be processed by a computer; Decoding the encoded data into a signal that can be processed in a reproduction medium; And Reproducing data by combining the decoded data and an encryption kit value used in an encryption process, The encryption output step And exclusively ORing data generated every clock with an arbitrary encryption code generated through a random data generator. A method of recording information on a holographic optical information storage medium and reproducing in a storage medium system, the method comprising: Converting data to be recorded on the holographic optical information storage medium into a signal that can be processed by a computer; An encrypted output step of combining the converted data with an arbitrary encryption kit value and outputting the result; Decrypting and outputting data by combining the data output in the encryption output step and an encryption kit value used in an encryption process; And Converting the decrypted data into a signal that can be processed in a playback medium; The encryption output step And exclusively ORing data generated every clock with an arbitrary encryption code generated through a random data generator.

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