KR20100137989A - Detecting method of digital image forged - Google Patents

Abstract

PURPOSE: A digital photo forgery detecting method is provided to determine the forgery attempt and a try of an inspection digital image thereby rapidly determining the identity of the inspection digital image. CONSTITUTION: A series of markers is extracted from a binary code of a target digital image(ST-121). A series of markers photographing the inspection digital image is extracted. Marker sequence of the inspection digital image and the marker sequence of the camera are compared(ST-125). If the marker sequence and marker contents are matched, the inspection digital image is determined as the digital image which is downloaded and stored to PC after photographing and is determined as the digital image which lost the identity.

Description

Detecting Method Of Digital Image Forged

The present invention relates to a digital photo (false) forgery detection method, a digital photo forgery detection method that can be clearly and simply check whether the forgery of the inspection digital image, and by contrasting the image can more clearly grasp the forgery state will be.

1 is a block diagram schematically illustrating a part of an internal configuration of the digital camera 10, and FIG. 2 is a block diagram schematically illustrating an image input unit included in the digital camera of FIG. 1. As shown in FIG. 1, the digital camera 10 includes an image input unit 11, a shooting setting unit 12, an image input driver 13, an image buffer 15, a meta information insertion unit 16, and a JPEG encoding unit. (18), a meta information extracting unit 17 and a JPEG decoding unit 19. The image input unit 11 includes a lens 11a, and captures an image by shooting setting information set by the shooting setting unit 12. The image input unit 11 includes a sensor module 11b and a DSP module 11c for image processing data, and the light signal input through the lens 11a passes through the sensor module 11b. The DSP module 11c converts the image data into a color signal expressed in a specific color space and outputs the signal. The image buffer 15 stores image data output from the image input unit 11. The image input driver 13 stores the photographing setting information, in which the register 14 stores the information.

3 is a general JPEG compression method and a data conversion process (encoding process), which is composed of a pixel frame 1, a discrete cosine converter 2, a quantizer 3, and an entropy encoder 4. The pixel frame data 5 is output as unit pixel block (8x8 pixel) data 6 for every input pixel frame. The pixel data is input to the discrete cosine converter 2 as 8x8 pixel block data, and the DCT coefficient data 7 is output after the conversion process. This data is input to the quantizer 3, converted into quantized data 8, and then input to the entropy encoder 4. The input data is output as the final compressed data 9. JPEG can be applied to intra-frame image coding and is used in applications that compress still images.

4 is a data block diagram schematically showing a general JPEG file structure, and FIG. 5 is a block diagram showing another example of a JPEG file structure. As shown in Figs. 4 and 5, the JPEG file is composed of SOI 31, APP1, APPn, DQT, DHT, SOF, SOS, compressed data, and EOI, each data block having a 2-byte size starting with 0xFF. It is divided into markers. In the above description, SOI is an abbreviation of Start OF Image and indicates a starting point of a JPEG file, DQT is an abbreviation of Define Quantization Table, and DHT is an abbreviation of Define Huffman Table, and DHT is an abbreviation of Huffman Code. Abbreviation for Frame, which indicates the starting point of the video frame. In addition, SOS is an abbreviation of Start Of Scan, and helps to read an image frame, and EOI is an abbreviation of End Of Image.

APP1 34 is an abbreviation of APPlication marker segment 1 and is a data block associated with image meta information at the time of camera photographing. APPn is an abbreviation of APPlication marker segment n and is a series of data blocks containing other extension information.

In FIG. 5, reference numeral 33 is a portion corresponding to a preview image stored for preview, and the resolution is generally 160 × 120, and 35 is an image for displaying on the digital camera LCD according to the LCD size of the digital camera. In the following description, the resolution is different for each camera manufacturer. The resolution is 570 × 375, 320 × 240, 640 × 480, and the like.

Digital images taken by the digital camera 10 are used as clues of crime scenes, but their reliability is also questioned due to the popularization of digital cameras, the development of digital editing technology, and the ease and sophistication of editing. . Although many studies have been conducted in the field of digital forensics in the past few years to restore the trust of digital images, there is no way to judge the uniqueness of digital images, and it is impossible to judge forgery by directly preparing the modulated images. There was a problem that it was not possible to judge whether or not it could be adopted as evidence for investigation.

The present invention has been proposed to solve the above problems, and it is possible to quickly and clearly detect whether a forgery or forgery of an image, which is a digital photograph, and digital photograph forgery, which can detect whether a digital image state is modulated. It is an object to provide a detection method.

In order to achieve the above object, the present invention provides a marker extraction step of extracting a series of markers from the binary code of the inspection digital image, a camera data extraction step of extracting a series of markers of the camera on which the inspection digital image was taken; The present invention provides a digital photograph forgery detection method comprising a contrasting step of comparing a sequence of markers extracted in a marker extraction step and a sequence of markers extracted in a camera data extraction step.

The present invention further includes extracting the DQT table of the inspection digital image in addition to the series of markers, and extracting the camera data further comprises extracting the DQT table of the camera in addition to the series of markers. In addition, the contrast step provides a digital photograph forgery detection method further comprising the step of contrasting the DQT table of the inspection digital image and the DQT table of the camera.

The present invention further includes extracting the DHT table of the inspection digital image in addition to the series of markers, and extracting the camera data further comprises extracting the DHT table of the camera in addition to the series of markers. In addition, the contrast step provides a digital photograph forgery detection method further comprises the step of contrasting the DHT table of the inspection digital image and the DHT table of the camera.

The present invention also includes the step of extracting the marker further includes a step of calculating the compressed data size of the inspection digital image in addition to the series of markers, and the step of extracting the camera data is performed by calculating the compression ratio for the resolution in addition to the series of markers. The method further includes a step of providing a digital photograph forgery detection method further comprising the step of comparing the compression ratio of the inspection digital image with the compression ratio calculated in the calculation step.

In addition, after the contrasting step, the present invention extracts the data of the first image from the binary code of the inspection digital image (first image extraction step), decodes the first image data, and displays it on the display unit along with the inspection digital image for inspection. A digital photo forgery detection method for comparing a digital image with a first image is provided.

According to the digital photograph forgery detection method according to the present invention, it is possible to quickly determine the uniqueness of the inspection digital image by judging in advance whether the inspection digital image has been forged or attempted to forge, and by contrasting with the first image, Counterfeit status can also be confirmed.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention. In the description of the present invention, the same name is used for the configuration having the same function as the prior art, and the detailed description of the contents described in the prior art is omitted.

FIG. 6 is a block diagram showing a first embodiment of a digital photo forgery detection method according to the present invention. FIG. 7 is a block diagram showing a DB generation step included in the digital photo forgery detection method of the present invention. 9 is a block diagram showing a second embodiment of the digital photo forgery detection method according to the present invention, and FIG. 9 is a block diagram showing a third embodiment of the digital photo forgery detection method according to the present invention, and FIG. Fig. 11 is a block diagram showing a fourth embodiment of the digital photo forgery detection method according to the present invention. Fig. 11 is a block diagram showing the image contrast method included in the digital photo forgery detection method according to the present invention.

The digital image photographed by the digital camera is stored in the storage means 20 with the syntax structure as shown in FIGS. 4 and 5 through the steps shown in FIG. 3. Since digital cameras are programmed to have a unique JPEG syntax sequence structure for each manufacturer and even for the same manufacturer, the digital images captured by the digital camera have a unique JPEG syntax structure.

The present invention was conceived in the light of the fact that a digital image has a unique JPEG syntax structure according to a digital camera. The above-described modulation of a displayed image of a digital image (hereinafter referred to as an "inspection digital image") to confirm whether or not the above modulation is performed Before checking whether or not a marker is used to extract the data block from the binary code of the inspection digital image (ST-121, marker extraction step). In the above, SOI starts with marker OxFFD8, immediately following APP1 is divided into marker 0xFFE1, DQT is divided into marker 0xFFDB, DHT is divided into marker 0xFFC4, SOF is divided into marker 0xFFC0, and SOS is marked with marker 0xFFDA. The EOI is separated by the marker 0xFFD9. The marker also includes the size of each block.

When a series of markers are extracted from the binary code of the digital image having the syntax structure as shown in FIG. 4, the sequence is as follows: OxFFD8, 0xFFE1, 0xFFEn, 0xFFDB, 0xFFC4, 0xFFC0, 0xFFDA, and 0xFFD9. When the marker is extracted from the binary code of the digital image having the syntax structure as shown in FIG. 5, OxFFD8, OxFFD8 to 0xFFD9, OxFFD8 to 0xFFD9, 0xFFDB, 0xFFC0, 0xFFC4, 0xFFDA, and 0xFFD9 are used. In the above description, 'to' is omitted by omitting markers for DQT and DHT provided between OxFFD8 and 0xFFD9.

It is then programmed into a digital camera (hereinafter referred to as the "digital camera") that captured the inspection digital image, and also extracts a sequence of markers generated during shooting (ST-123, camera data extraction step). The marker order of a digital camera photographing the inspection digital image can be extracted from the binary code of the digital image generated by photographing an arbitrary image.

In contrast to the sequence of markers extracted in the marker extraction step (ST-121) and the sequence of markers extracted in the camera material extraction step (ST-123) (ST-125, contrast step), the order of the markers coincides with each other. If the markers match, the inspection digital image can be judged as a stored image taken by the digital camera. If the marker contents do not match, the inspection digital image is taken from the digital camera, down to the PC, etc. It may be determined that the uniqueness is lost in the previous step of determining whether there was a presence or absence. Inspection digital images that have lost their uniqueness are evidence of criminal cases and will have no or less evidence.

It is also possible to compare the DQT table and the DHT table to more accurately grasp the uniqueness of the inspection digital image. Referring to the process of contrasting the DQT table, the DQT table of the inspection digital image is extracted in the marker extraction step (ST-121) (ST-131, DQT table extraction step), and the camera data extraction step (ST-123). ) Extracts the DQT table of the camera in addition to the series of markers (ST-133, camera DQT table extraction step). In addition to contrasting the order of the markers in the contrasting step ST-125, the DQT table of the inspection digital image and the DQT table of the camera are contrasted (ST-135).

Next, a process of contrasting the DHT table will be described. In the marker extraction step ST-121, the DHT table of the inspection digital image is extracted (ST-141, DHT table extraction step), and the camera data extraction step (ST- In step 123, the DHT table of the camera is extracted in addition to the series of markers (ST-143, camera DHT table extraction step). In addition to contrasting the order of the markers in the contrasting step ST-125, the DHT table of the inspection digital image and the DHT table of the camera are contrasted (ST-135).

In addition, it is possible to contrast the compression rate of the compressed data in the compression process shown in FIG. 3 in order to more accurately confirm the uniqueness of the inspection digital image. To this end, the compressed data size of the inspection digital image is calculated in addition to the series of markers in the marker extraction step (ST-121) (ST-151). It is possible to calculate the size of the compressed data portion in the binary code of the check digital image. And it is possible to check the compression ratio from the meta information of the binary code of the check digital image and compare it with the calculated actual compressed data size. In addition, in the camera data extraction step (ST-123), a digital image such as the resolution of the inspection digital image is generated in addition to the series of markers, and the compression rate is confirmed by the meta information of the generated comparison digital image (ST-153). By contrast with the compression ratio (ST-155) it will be possible to check forgery and alteration of meta information.

Through the above process, it is possible to check whether there is an attempt for forgery such as downloading and modifying and storing the inspection digital image from the digital camera to the PC, and the actual forged part is prepared after the contrasting step (ST-125), Extract code data corresponding to the first image from the binary code of the inspection digital image (ST-161, first image extraction step), decode the first image data (ST-163), and inspect the display means such as a PC. The digital image is displayed on a display unit (for example, a monitor) (ST-165) to directly compare the inspection digital image with the first image (ST-167) to check the actual forgery content. Although the above step may be a preview image, the resolution of the preview image is relatively low and it is preferable to compare the first image.

As shown in FIG. 7, the DB is generated in advance (ST-100) for various models of digital cameras produced by various manufacturers and stored, and the uniqueness thereof is compared with data such as markers extracted from the stored DB and the inspection digital image. It is possible to detect. In this case, the data to be included in the DB may include a marker, a DQT table, a DHT table, a compression ratio, and the size of compressed data according to each resolution.

Although the exemplary embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited to such specific embodiments, and the scope obvious to those skilled in the art to which the present invention pertains is described within the claims of the present invention. It should be interpreted as belonging to a category.

1 is a block diagram schematically showing a part of an internal configuration of a digital camera.

FIG. 2 is a block diagram schematically illustrating an image input unit included in the digital camera of FIG. 1.

3 schematically illustrates a JPEG image compression step.

4 is a data block diagram schematically showing a general JPEG file structure.

5 is a data block diagram schematically showing another example of a general JPEG file structure.

6 is a block diagram showing a first embodiment of a digital photograph forgery detection method according to the present invention.

7 is a block diagram showing a DB generation step included in the digital photograph forgery detection method of the present invention.

8 is a block diagram showing a second embodiment of a digital photograph forgery detection method according to the present invention.

9 is a block diagram showing a third embodiment of the digital photo forgery detection method according to the present invention.

10 is a block diagram showing a fourth embodiment of the digital photo forgery detection method according to the present invention.

11 is a block diagram illustrating an image contrast method included in the digital photograph forgery detection method according to the present invention.

Claims (5)

A marker extraction step (ST-121) for extracting a series of markers from the binary code of the inspection digital image, a camera data extraction step (ST-123) for extracting a series of markers of the camera on which the inspection digital image was taken, and a marker extraction And a contrast step (ST-125) for comparing the sequence of markers extracted in the step and the sequence of markers extracted in the camera material extraction step (ST-125). The method of claim 1, wherein the extracting the marker (ST-121) further comprises extracting the DQT table of the inspection digital image in addition to the series of markers (ST-131), and extracting the camera data (ST-123). The method may further include extracting the DQT table of the camera in addition to the series of markers (ST-133), and in the contrasting step (ST-125), comparing the DQT table of the inspection digital image and the DQT table of the camera (ST-133). 135) further comprises a digital photo forgery detection method characterized in that it further comprises. The method of claim 1, wherein the extracting the marker (ST-121) further comprises extracting the DHT table of the inspection digital image in addition to the series of markers (ST-141), and extracting the camera data (ST-123). In addition to the series of markers, the method further includes extracting the DHT table of the camera (ST-143), and in the contrasting step (ST-125), comparing the DHT table of the digital image with the DHT table of the camera (ST-125). And 145). The method of claim 1, wherein the marker extracting step (ST-121) further includes a computing step (ST-151) for calculating a compressed data size of the inspection digital image in addition to a series of markers. 123 further includes a step (ST-153, verification step) of confirming the compression ratio for the resolution of the inspection digital image from the meta information in addition to the series of markers, and in the contrast step ST-125, the compressed data of the inspection digital image And comparing the compression rate calculated in step ST-151 with the compression rate checked in step ST-151 (ST-155). The method of claim 1, wherein after the contrasting step ST-125, data of the first image is extracted from the binary code of the inspection digital image (ST-161, the first image extraction step), and the first image data is decompressed. (ST-163), and displaying the inspection digital image on the display unit (ST-165) and comparing the inspection digital image and the first image (ST-167).

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