KR20030021881A - Device and method for compressing a image data - Google Patents

Abstract

PURPOSE: An apparatus and a method for compressing image data are provided to separately compress and encipher an original image and a background image, thereby realizing high-speed transmission of image data and reducing storage capacity. CONSTITUTION: A design processor(100) designs an original image used for various software on a background picture, and then outputs the corresponding design data. An image compressing processor(200) receives the design data for detecting a first position and a final position of the original image, compresses and outputs the original image including a first pixel value and a final pixel value. An image enciphering processor(300) receives the compressed image for indexing a preliminarily set encryption code at the first pixel and the final pixel of the compressed image, and outputs the enciphered image data. An image data storing part(400) receives and stores the enciphered image data, and receives reading data for outputting the enciphered image data. A cryptanalysis processor(500) receives the enciphered image data for analyzing the encryption code and outputting the deciphered image data. An original image reproducing processor(600) analyzes the first pixel value and the final pixel value for reproducing and displaying the original image.

Description

DEVICE AND METHOD FOR COMPRESSING A IMAGE DATA}

The present invention relates to an apparatus and method for compressing image data, and in particular, when transmitting image data used in various games or general software, the image data can be compressed and encrypted to minimize the storage capacity of the image data and to transmit the image data at high speed. In addition, the present invention relates to an image data compression apparatus and method for minimizing hacking that may occur during image data transmission.

In general, to display characters used in various games (e.g. people, chairs, desks, cars, buildings, wood or kitchenware, etc.) or image data used in general software on various screens Image data is compressed and transmitted by the device that stores the image to be displayed on the screen. In this case, the image data is compressed by calculating the width and height (x-axis, y-axis) of the image and copying the image data. Send the data to the displaying device.

Then, the display device receives the transmitted image data, reads the surrounding image corresponding to the width and height of the actual image by 1 byte from the copied image, detects and deletes unnecessary images, and displays the actual image.

However, when copying and transmitting various images as described above, image copying is performed using only the width and height (x-axis, y-axis) of the corresponding image. Not only can the surrounding images be displayed, but the speed of reading the images slows down the image data transfer speed and display speed, while also using the capacity of a hard disc drive (HDD) to store the transferred image data. There was a problem.

In addition, there is a risk of hacking when transferring image data because only the width and height of the image is copied and transmitted when copying and transferring the image. Therefore, a huge economic loss may occur due to a program error caused by the hacking. There was a problem.

In addition, since the image is copied to the surrounding screen of the image to be actually displayed as described above, even if the CPU speed of the computer increases gradually, the time required for displaying the image on the screen becomes longer, so netizens who enjoy the game enjoy the speed of the game. There was a problem that can not.

Accordingly, the present invention is to solve the above-mentioned conventional problems, an object of the present invention is to simultaneously compress the image data used in various games or general software to the desktop corresponding to the width and height of the image at the same time By compressing and encrypting the original image and the desktop image respectively, and transmitting the image data without compressing and transmitting the image data, not only can the high speed transmission and storage capacity of the image data be reduced, but also the economic loss due to the hacking of the image data. To provide an image data compression apparatus and method to minimize the problem.

In order to achieve the above object, the image data compression device of the present invention comprises a design processor for designing an original image on a desktop by user's manipulation of an image used in various software and outputting design data corresponding thereto;

An image compression processor which receives the design data output from the design processor, detects an initial position and a final position of an original image designed on a desktop, and then compresses and outputs an original image including an initial pixel value and a final pixel value;

An image encryption processor which receives the compressed image output from the image compression processor and indexes a predetermined encryption code in the first pixel and the final pixel of the compressed image and outputs encrypted image data;

An image data storage unit configured to receive and store encrypted image data output from the image encryption processor, and to receive leading data and output encrypted image data;

A decryption processor that receives the encrypted image data output from the image data storage unit, decrypts an encryption code indexed to the first pixel and the last pixel of the image data, and then outputs the decrypted image data;

And an original image reproduction processor configured to receive the decrypted image data output from the decryption processor, analyze the initial pixel value and the final pixel value, and reproduce and display the original image.

On the other hand, the image data compression method of the present invention, in the image compression processor design data input determination step of determining whether the design data is input from the design processor;

And if the design data is not input in the design data input determination step, return to the beginning, and if input, the image compression processor determines an initial position detection whether or not the first position of the original image is detected;

Detecting the initial position of the original image in the initial position detection determination step, the image compression processor determines a final position detection whether to determine whether or not the final position of the original image is detected;

An original image compression step of compressing and outputting an original image including the first pixel value and the last pixel value of the original image when the final position of the original image is detected in the final position detection determination step;

An encryption code indexing step of receiving the compressed image output from the image compression processor and indexing and outputting an encryption code preset to the first pixel and the last pixel of the compressed image;

An image data storage step of receiving and storing encrypted image data output from the image encryption processor;

In the image data storage unit, a reading data input determining step of determining whether reading data for reading image data is input;

If the leading data is not input in the reading data input determination step, returning to the reading data input determination step, and if input, the encrypted image data output step of outputting the encrypted image data;

The decryption processor receives the encrypted image data output from the image data storage unit and determines whether the encryption code is identical to determine whether the encryption code indexed to the first pixel and the last pixel of the image data is the same;

In the determining whether the encryption code is the same, if the encryption code indexed to the first pixel and the final pixel is the same, the decryption processor decrypts and outputs the encryption code indexed to the first pixel and the last pixel of the image data and outputs the image data. Wow,

An image data pixel position determination step of receiving, from the original image reproduction processor, the image data output from the decryption processor to determine whether the pixel position of the image data is between an initial pixel value and a final pixel value;

In the image data pixel position determination step, if the pixel position of the image data is between the first pixel value and the final pixel value, the original image reproduction processor comprises an original image display step of displaying after playing the original image desired by the user. do.

1 is a block diagram showing an image data compression apparatus according to an embodiment of the present invention;

2 is a flowchart illustrating a method of compressing image data according to an embodiment of the present invention;

3 is a diagram illustrating image compression in an image data compression apparatus and method according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: design processor 200: image compression processor

300: image encryption processor 400: image data storage unit

500: decryption processor 600: original image playback processor

Hereinafter, an image data compression apparatus and method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating an image data compression apparatus, FIG. 2 is a flowchart illustrating an image data compression method, and FIG. 3 is a diagram illustrating image compression in an image data compression apparatus and method.

1, the design processor 100, the image compression processor 200, the image encryption processor 300, the image data storage unit 400, the decryption processor 500 and the original image playback processor as shown in FIG. It consists of 600, the design processor 100 serves to output the corresponding design data after designing the original image on the desktop by the user's manipulation of the image used in various software.

In addition, the image compression processor 200 receives the design data output from the design processor 100, detects the initial position and the final position of the original image designed on the desktop and includes the initial pixel value and the final pixel value It compresses and outputs the original image.

Subsequently, the image encryption processor 300 receives a compressed image output from the image compression processor 200, indexes an encryption code preset to the first pixel and the last pixel of the compressed image, and outputs encrypted image data. Play a role.

In addition, the image data storage unit 400 receives and stores encrypted image data output from the image encryption processor 300, and receives reading data and outputs encrypted image data.

On the other hand, the decryption processor 500 receives the encrypted image data output from the image data storage unit 400, decrypts the encryption code indexed to the first pixel and the last pixel of the image data and then decrypted the image It outputs data.

In addition, the original image reproduction processor 600 receives the decrypted image data output from the decryption processor 500 and analyzes the initial pixel value and the final pixel value to play and display the original image. do.

Hereinafter, an operation process of the image data compression device configured as described above will be described.

For example, images used in various software include game characters, wallpapers, or props (cars, people, roads, buildings, advertising billboards, chairs, desks, appliances, etc.). When the user designs an image required for a game or various software for easy and quick use, as shown in FIG. 1, the design processor 100 designs the original image on the desktop by the user's operation and then design the corresponding image. Output the data.

Then, the image compression processor 200 receives various design data output from the design processor 100 and detects the initial position and the final position of the original image designed on the desktop, and then the initial pixel value and the final pixel value Compress and output the included original image.

In this case, as shown in FIG. 3, the initial position and the final position of the original image and the background image are detected respectively, and the original image and the background image including the initial pixel value and the final pixel value of the original image and the background image are respectively detected. Compress and output each image.

Subsequently, the image encryption processor 300 receives the compressed image output from the image compression processor 200, indexes a predetermined encryption code to the first pixel and the last pixel of the compressed image, and outputs encrypted image data. The image data storage unit 400 receives and stores the encrypted image data output from the image encryption processor 300, and receives the reading data and outputs the encrypted image data.

Then, the decryption processor 500 receives the encrypted image data output from the image data storage unit 400, decrypts the encryption code indexed to the first pixel and the last pixel of the image data, and then decrypts the image data. The original image reproduction processor 600 receives the decrypted image data output from the decryption processor 500, analyzes the first pixel value and the last pixel value, and plays the original image to display the original image.

In this case, when the encryption analysis of the image data encrypted by the decryption processor 500 is described, for example, the code included in the minimum pixel value and the final pixel value of the image is analyzed to have the same code or serial data (Serial). Data) can be inserted to detect the corresponding serial data and decrypt the index indexed on the image.

Meanwhile, when the image data compression method is described in more detail as shown in FIG. 2, the image compression processor 200 determines whether design data is input from the design processor 100 (S100). If the design data is not input in the data input determination step (S100), the process returns to the beginning, and if it is input, the image compression processor 200 determines whether the initial position of the original image is detected as shown in FIG. (S200).

Subsequently, when detecting the initial position of the original image in the initial position detection whether or not (S200), the image compression processor 200 determines whether or not the final position of the original image is detected (S300), the final position When the final position of the original image is detected in the detection determination step (S300), the image compression processor 200 may convert the original image including the first pixel value and the last pixel value of the original image into a byte unit, for example. Compress and output (S400).

Then, the image encryption processor 300 receives the compressed image output from the image compression processor 200 and indexes and outputs a predetermined encryption code in the first pixel and the final pixel of the compressed image (S500). The data storage unit 400 receives and stores the encrypted image data output from the image encryption processor 300 (S600).

Meanwhile, the image data storage unit 400 may use various devices to store image data. For example, the image data storage unit 400 may include a game server that provides a game or a CD-ROM or hard disk that can be used in a personal computer. It is available.

Subsequently, the image data storage unit 400 determines whether reading data for reading image data has been input (S700), and if reading data is not input in the reading data input determination step (S700), the reading Returning to the data input determination step (S700), when inputted, the image data storage unit 400 outputs encrypted image data (S800).

On the other hand, the reading data refers to data that an unspecified number of netizens transmit an image to the image data storage 400 using a personal computer, a PDA (Pers-onal Digital Assistant) or a mobile communication terminal. do.

In addition, the decryption processor 500 receives the encrypted image data output from the image data storage unit 400 and determines whether the encryption code indexed at the first pixel and the last pixel of the image data is the same (S900). ).

Subsequently, if the encryption code indexed to the first pixel and the last pixel is the same in the step of determining whether the encryption code is the same (S900), the decryption processor 500 decrypts the encryption code indexed to the first pixel and the last pixel of the image data. And then output (S1000).

Then, the original image reproduction processor 600 receives the decrypted image data output from the decryption processor 500 and determines whether the pixel position of the image data is between the first pixel value and the last pixel value. In operation S1100, when the pixel position of the image data is between an initial pixel value and a final pixel value in the image data pixel position determination step S1100, the original image reproducing processor 600 shows a desired original image in FIG. 3. After playback, the display is performed (S1200).

Meanwhile, if the initial position of the original image is not detected in the determination of whether the initial position is detected (S200), the image compression processor 200 determines whether or not a pixel of the background screen is detected (S210). If the pixel of the background screen is not detected in the pixel detection determination step (S210), the process returns to the initial detection position determination step (S200), and if detected, the image compression processor 200 displays the background screen as shown in FIG. 3. After the new image data is compressed, the process returns to the initial position detection determination step (S200) (S220).

If the final position is not detected in the final position detection step S300, the image compression processor 200 detects the final position of the original image and then proceeds to the original image compression step S400. (S310).

Subsequently, if the encryption code indexed in the first pixel and the final pixel is not the same in the step of determining whether the encryption code is the same (S900), the decryption processor 500 outputs a warning message according to the hacking of the image data and then terminates. In operation S910, when the pixel position of the image data is not between the first pixel value and the last pixel value in the image data pixel position determination step (S1100), the original image reproduction processor 600 may encrypt a password as shown in FIG. 3. After the reproduction of the decrypted image data, that is, the background screen, the process proceeds to the image data pixel position determination step S1100 (S1110).

As described above, the apparatus and method for compressing image data according to the present invention does not compress and transmit the image data used in various games or general software to the desktop corresponding to the width and height of the image at the same time. By compressing and encrypting the image and the desktop image separately to transfer the image data, not only can the transfer and storage capacity of the image data be reduced, but also the economic loss due to the hacking of the image data can be minimized. It works.

Claims (6)

A design processor for designing original images on the desktop by user manipulation of images used in various software and outputting corresponding design data; An image compression processor which receives the design data output from the design processor, detects an initial position and a final position of an original image designed on a desktop, and then compresses and outputs an original image including an initial pixel value and a final pixel value; An image encryption processor which receives the compressed image output from the image compression processor and indexes a predetermined encryption code in the first pixel and the final pixel of the compressed image and outputs encrypted image data; An image data storage unit configured to receive and store encrypted image data output from the image encryption processor, and to receive leading data and output encrypted image data; A decryption processor that receives the encrypted image data output from the image data storage unit, decrypts an encryption code indexed to the first pixel and the last pixel of the image data, and then outputs the decrypted image data; And an original image reproduction processor configured to receive the decrypted image data output from the decryption processor, analyze the first pixel value and the last pixel value, and reproduce and display the original image. In the image compression processor, a design data input determination step of determining whether design data is input from the design processor; And if the design data is not input in the design data input determination step, return to the beginning, and if input, the image compression processor determines an initial position detection whether or not the first position of the original image is detected; Detecting the initial position of the original image in the initial position detection determination step, the image compression processor determines a final position detection whether to determine whether or not the final position of the original image is detected; An original image compression step of compressing and outputting an original image including the first pixel value and the last pixel value of the original image when the final position of the original image is detected in the final position detection determination step; An encryption code indexing step of receiving the compressed image output from the image compression processor and indexing and outputting an encryption code preset to the first pixel and the last pixel of the compressed image; An image data storage step of receiving and storing encrypted image data output from the image encryption processor; In the image data storage unit, a reading data input determining step of determining whether reading data for reading image data is input; If the leading data is not input in the reading data input determination step, returning to the reading data input determination step, and if input, the encrypted image data output step of outputting the encrypted image data; The decryption processor receives the encrypted image data output from the image data storage unit and determines whether the encryption code is identical to determine whether the encryption code indexed to the first pixel and the last pixel of the image data is the same; In the determining whether the encryption code is the same, if the encryption code indexed to the first pixel and the final pixel is the same, the decryption processor decrypts and outputs the encryption code indexed to the first pixel and the last pixel of the image data and outputs the image data. Wow, An image data pixel position determination step of receiving, from the original image reproduction processor, the image data output from the decryption processor to determine whether the pixel position of the image data is between an initial pixel value and a final pixel value; In the image data pixel position determination step, if the pixel position of the image data is between the first pixel value and the last pixel value, the original image reproduction processor comprises an original image display step of displaying after playing the original image desired by the user. Image data compression method. 3. The method of claim 2, wherein if the initial position is not detected in the initial position detection step, the image compression processor determines whether the background pixel is detected or not in the image compression processor; And If the background pixel is not detected in the background pixel detection step, the screen returns to the initial position detection status determination step. If detected, the image compression processor newly compresses the image data of the background screen, and then detects the initial position. Image data compression method comprising a desktop image compression step of proceeding to a determination step. The final position of claim 2, wherein if the final position of the original image is not detected in the determination of whether the final position is detected, the image compression processor detects a final position of pixels of the original image and then proceeds to the original image compression step. Image data compression method characterized in that it comprises a detection step. According to claim 2, If the encryption code indexed to the first pixel and the last pixel in the step of determining whether or not the encryption code is the same, the decryption processor outputs a warning message for hacking the image data and ends the warning message Image data compression method comprising the output step. The image reproducing processor of claim 2, wherein in the image data pixel position determining step, if the pixel position of the image data is not between an initial pixel value and a final pixel value, the original image reproducing processor blocks the reproduction of the decrypted image data. And image data reproduction blocking step proceeding to the image data pixel position determination step.