KR20100092693A - A method for processing a video signal and a system thereof - Google Patents

Abstract

PURPOSE: An image signal processing system and a method thereof are provided to convert a video signal of a specific source device to fit the characteristic of each device, thereby improving color reproduction. CONSTITUTION: A source device(500) transmits a gamut metadata packet related to a video image. A HDMI(High Definition Multimedia Interface) sync unit(512) decodes an input data. The HDMI sync unit processes a control data of the source device. A video processing unit(514) processes the processed video data to fit a panel(517) and a requirement of a user. A xvYCC processing unit(515) executes gamut mapping in one part among xvYCC block by the measurement data of a panel.

Description

A method for processing a video signal and a system

The present invention relates to a video signal processing method and system, and more particularly to a processing of a video signal having different color space information between a source device and a sink device.

The video device has a built-in recording medium capable of storing files, so that the stored file can be played in the device or through a connected external device.

The imaging device reproduces an image based on a specific color gamut. Recently, with the development of such video equipment, the range of color gamut is gradually increasing.

Regarding the color gamut, looking at the color range based on the standard YC _b C _r signal, the color space is used for the color gamut for the sRGB signal, the color gamut for the sYCC signal, and the xvYCC signal. Color range is wide in order of color.

However, the video device and the external device may have their own color gamut depending on their performance or characteristics. Therefore, the external device is difficult to sufficiently reproduce the color of the video signal of the video device having a different color gamut, there is a problem inferior color reproducibility.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to increase color reproduction of an input of a specific source device in each sink device.

Another object of the present invention is to propose gamut metadata standardized to enable color reproduction in each sink device as described above.

Another object of the present invention is to provide a video signal processing system therefor.

In order to achieve the above object, an example of the image signal processing method according to the present invention comprises the steps of: receiving image data having a specific color space; Get Gamut Boundary Description (GBD) data including gamut metadata having Tristimulus values (XYZ) data structure in relation to a color space from the received image data (get) step; Extracting gamut metadata from the obtained gamut boundary description (GBD) data, and converting gamut of the input image data by obtaining tristimulus value data according to a predefined equation based on the extracted gamut boundary metadata; It is characterized by comprising.

In this case, the gamut metadata having a tristimulus data structure with respect to the color space includes first information indicating a color space of gamut boundary description (GBD) data, wherein the first information is vertex. And a second field for an xy chromaticity diagram for each vertex according to the number of vertices.

The value of the first field may be 4 indicating white, red, green, and blue.

The second field may include a Y value of a chromaticity coordinate and a tristimulus value for each vertex according to the value of the first field.

The first information includes ITU-R BT. 709, xvYCC ₆₀₁ and xvYCC ₇₀₉ using YC _b C _r , and xyY using tristimulus values.

In addition, the gamut metadata having a tristimulus data structure in relation to the color space may include a format type of whether the following data is vertex / facets description or range description. At least one of second information indicating)), third information indicating facets included in gait boundary description (GBD), and fourth information indicating the size of each component of each vertex or range entry. can do.

The predefined formula may be X + Y + Z = 1, X = x / y * Y, and Z = 1-X-Y.

An example of a video signal processing system according to the present invention includes a source device having an HDMI output; Receives and processes an HDMI output including image data having a specific color space from the source device, and includes a gait boundary with gamut metadata having a tristimulus data structure with respect to the color space from the image data included in the HDMI output. A sink device including a video signal processing unit for obtaining description (GBD) data and converting a gamut of the video data; And a cable for transmitting and receiving data by connecting the source device and the sink device.

The video signal processor may include: a sink unit configured to extract gamut boundary description (GBD) data from the video data, and extract and decode gamut metadata from the extracted gamut boundary description (GBD); And a video processor configured to convert the gamut of the image data by using the decoded gamut metadata and a predefined equation to process the corresponding video data.

The video signal processor may further include a storage unit configured to store configuration / state information supported by the sink unit.

The video processor may include a color space processor that performs gamut mapping on some blocks of the corresponding data blocks to process the specific color space.

The color space processor extracts first information indicating a color space from the decoded gamut metadata in performing gamut mapping based on gamut metadata having a tristimulus data structure with respect to the color space. Here, the first information may include a first field for the number of vertices and a second field for an xy chromatity diagram for each vertex according to the number of vertices.

In addition, when the value of the first field is 4, the color space processor may recognize that each vertex indicates white, red, green, and blue. .

The color space processor may extract a Y value of a chromaticity coordinate and a tristimulus value for each vertex as the value of the second field according to the value of the first field.

The color space processing unit may further include an ITU-R BT. 709, at least one of xvYCC ₆₀₁ and xvYCC ₇₀₉ using YC _b C _r and xyY using tristimulus values can be extracted.

The color space processing unit may further include second information and a boundary boundary indicating whether the data following the gamut metadata having a tristimulus data structure in relation to the color space is a vertex / facets description or a range description. At least one of third information indicating facets included in the description GBD and fourth information indicating a size of each component of each vertex or range entry may be extracted.

In addition, the color space processing unit may be calculated using the predefined formula, that is, X + Y + Z = 1, X = x / y * Y, and Z = 1-X-Y.

Therefore, according to the video signal processing method and apparatus according to the present invention,

First, an image signal of a specific source device may be converted to match the characteristics of each sink device, thereby improving color reproduction.

Second, there is an effect that can provide the normalized gamut metadata for gamut conversion to match the video signal of a specific source device to the characteristics of the sink device in each sink device.

Third, there is an effect that each sink device can process and express a unique color gamut of a specific source device.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described. At this time, the configuration and operation of the present invention shown in the drawings and described by it will be described by at least one embodiment, by which the technical spirit of the present invention and its core configuration and operation is not limited.

The terms used in the present invention have been selected as general terms widely used as possible in consideration of the functions in the present invention, but may vary according to the intention or custom of a person skilled in the art or the emergence of a new technology. In addition, in certain cases, there is also a term arbitrarily selected by the applicant, in which case the meaning will be described in detail in the description of the invention. Therefore, it is intended that the terms used in the present invention should be defined based on the meanings of the terms and the general contents of the present invention rather than the names of the simple terms.

Hereinafter, a video signal processing method and an apparatus thereof according to the present invention will be described. Hereinafter, the technical spirit of the present invention will be described more clearly and for convenience of description, the video signal will be described using an HDMI video signal as an example. The HDMI standard has recently included the xvYCC color space as a color space, hereinafter, in particular, an image signal having an xvYCC color space is taken as an example.

Hereinafter, terms used herein in connection with the present invention will be briefly defined, and an image signal processing method and apparatus thereof according to the present invention will be described.

-Definition of Terms-

In the following description, the term "color space" refers to a concept used to store color as digital information and to reproduce it. The concept of the color space may include RGB (RedGreenBlue), CYMagenta YellowblacK (CMYK), HueSaturationValue (HSV), xvYCC, and the like. However, in the present specification, as an example of the color space, xvYCC will be described as an example for convenience of description with respect to the HDMI video signal.

"xvYCC", also called Extended YCC Colorimetry for Video Applications, refers to a color standard approved by the International Electrotechnical Commission (IEC). This is to update the color spectrum displayed on the display screen in the HD era.

"HDMI", short for High-Definition Multimedia Interface, refers to DVD players (Digital Versatile Disc (DVD) players), set-top boxes and other AudioVisual sources. To transmit digital television audiovisual signals to TV sets, projectors, and other Video Displays. In the present specification, an HDMI device includes an (HDMI) source device having an HDMI output, and an HDMI sink device having an HDMI input such as a display, a monitor, and a DTV monitor. And cables that exchange data in both directions between the source device and the sink device. There is also a repeater with one or more HDMI inputs and outputs.

HDMI video signal processing

1 is an example of a system block diagram depicting an HDMI system architecture in connection with the present invention. Hereinafter, the HDMI system architecture will be described with reference to FIG. 1.

The HDMI system architecture is defined by consisting of sources and sinks. Here, a given device may have one or more HDMI inputs and one or more HDMI outputs. In such devices each HDMI input will follow all of the rules for HDMI sink and each HDMI output will follow all of the rules for HDMI source.

The HDMI source 100 has an HDMI transmitter 110, and the HDMI sink 200 has an HDMI receiver 210. In addition, the HDMI sink 200 further includes an E-EDID ROM (Extended Display Identification Data ROM) 220.

The HDMI cable and connectors 150-155 carry four differential pairs. Here, the four differential pairs are composed of a Transition Minimized Differential Signaling (TMDS) data channel 150 to 152 and a TMDS clock channel 153. The TMDS Data Channels 0-2 and 150-152 are used to transmit video, audio and auxiliary data from the HDMI transmitter 110 to the HDMI receiver 210. The TMDS clock channel 153 generally transmits a TMDS clock driven at a video pixel rate, and is an HDMI receiver 210 as a frequency reference for data recovery on three TMDS data channels 150-152. Used by).

There is another channel, that is, a Display Data Channel (DDC) channel, between the HDMI source 100 and the HDMI sink 200. The DDC channel 154 is used for configuration and status exchange between the source 100 and the sink 200. The DDC channel 154 is used to read the sink's E-EDID ROM 220 from the source 100 to know the configuration and / or capability of the sink 200.

The optional Consumer Electronics Control (CEC) protocol 155 provides high-level control functions among all of the various audiovisual products in the user environment.

HDMI uses a packet structure to transmit audio and auxiliary data over TMDS channels existing between HDMI source 100 and HDMI sink 200. Here, the packet structure used between the HDMI source 100 and the HDMI sink 200 also includes a gamut metadata packet, which is different from the Gamut Boundary Description (GBD) in relation to the present invention. Other Gamut-related metadata are transmitted using the Gamut metadata packet. Gamut metadata may be transmitted to describe the gamut of the next video or the gamut of the currently transmitted video. In relation to this, each change in the video stream requires the transmission of new gamut metadata.

In general, source 100 uses specific default colorimetry for the video format to be transmitted.

According to the present invention, the HDMI sink 200 may include gamut metadata related to the color space of the video signal to process the HDMI video signal having the xvYCC color space input from the HDMI source 100. ) Can be processed according to the provided display only after receiving and processing.

In this regard, the xvYCC color space has been adopted in the HDMI 1.3 specification. Therefore, a video image including an image signal having an xvYCC color space should support the HDMI 1.3 standard in both devices, that is, the source 100 and the sink 200.

Basically, the HDMI source 100 transmits the xvYCC-encoded video image to the HDMI sink 200 in accordance with the encoded data according to whether or not the corresponding HDMI sink 200 is supported. Sends a metadata packet including a. The HDMI sink 200 decodes the transmitted gait metadata packet, extracts the relevant additional information, and processes it according to the characteristics of the provided display. Here, the HDMI sink 200 performs a gamut transform of the display gamut and the input signal in the process so that the desired data is output to finally reproduce the color on the display.

However, as described above, related additional information including gamut metadata defined to process the xvYCC color space in order to accurately and predictably display an xvYCC-encoded video image in the HDMI sink 200 should be defined. . Accordingly, the present invention intends to define gamut metadata related thereto.

Basically, the color space of the HDMI source 100 (eg, camera) and the color space of the display in the HDMI sink 200 may be completely different color spaces. Therefore, when a video image including an image signal having a specific color space input from an HDMI source is displayed on a display by being processed by the HDMI sink 200, there may be a difference according to the other color space.

In order to solve the problem caused by the difference, the primary color is reproduced by matching different color spaces. However, RGB boundary data is problematic because it is data that cannot be used in actual products.

Therefore, in the present invention, by using the data according to the CIEXYZ standard instead of the RGB boundary data, not only the expansion of data that xvYCC has in terms of color reproducibility, but also accurate color reproduction of the HDMI source can be performed. In other words, to achieve compatibility of the color data. For example, suppose there are HDMI sources A, B, and C. In this case, each HDMI source may have different colors in the same video image according to characteristics of each other. However, according to the present invention, the gait metadata may be defined and standardized to have device-independent characteristics. This reflects the color characteristics of the display device in the HDMI sink and follows the standard CIEXYZ, so that in each HDMI sink, the video image including the video signal of any HDMI source can be clearly processed through the operation. In addition, it can be compatible with other devices by extending it in another color space.

Hereinafter, gamut metadata that can be standardized according to the present invention is defined. Here, the gamut metadata is defined to include a data structure of XYZ Tristimulus values for convenience of explanation of the technical idea of the present invention.

FIG. 2 is a diagram illustrating a data structure of Vertices / Facets boundary boundary descriptions (GBD) defined in the HDMI standard in relation to the present invention.

Unlike the classic colorimetry standards used for SD (Standard Definition) and HD (High Definition) video, the enhanced colorimetry of xvYCC is virtually unrestricted. (virtually unconstrained gamut). Enhanced colorimetry transmission is essential for the video source to indicate the color gamut of the transmitted video. The metadata allows the display to map the appearance of the video stream more accurately and more predictably with the display appearance.

Gamma describes all the colors that can be reproduced by being present in a special reference display or given content. Color gamut can be explained by gamut boundary description (GBD). If the given image content is different from or larger than the HDMI sync appearance, the colors placed outside the intended appearance need to be clipped or moved. This process is called gamut mapping. The gamut of content is circumscribed by the gamut of HDMI source color space. The display utilizes the Gamut Boundary Description (GBD) of the content so that it can accurately and predictably perform its own predictable mapping.

There are a number of transmission profiles (P0, P1, etc.) for gamut related metadata. The difference between the transmission files is mainly the transmission rate, in particular the number of packets that can be transmitted in every video field. The transmission rate limits the maximum size of the profile because it is needed to transmit the entire metadata. The maximum size of the metadata corresponds to the accuracy of the gamut boundary description (GBD).

The HDMI source gamut is described by either a set of R / G / B range limits, or a set without provided vertices or indexed facets.

Referring to Fig. 2, the GBD data structure will be described in more detail. Here, each byte # will be described sequentially.

First, looking at Byte # 0, four pieces of information are defined. The Format_Flag field (1 bit) indicates what format is provided, to identify whether the following data describes a gamut range boundary or a gamut vertices boundary. Information. In this case, when the value of the Format_Flag field is '0', it indicates that the next data is vertices / facets description. If '1', the next data is range description. description).

A Facet_Mode field (1 bit) indicates facets included in the boundary boundary description (GBD). This field is valid only if the value of the Format_Flag field is '0'.

The GBD_Color_Precision field (2 bits) indicates the size of each component of each vertex or range entry, and the color precision of the vertex and range data of the boundary description (GBD). ).

A GBD_Color_Space field (3 bits) indicates a color space of GBD data. Herein, in the context of the present invention, if the GBD_Color_Space field indicates '0b000', it indicates a color space using RGB, and if '0b001' indicates an xvYCC ₆₀₁ (SD) color space using YC _b C _r and indicates '0b010' In this case, xvYCC ₇₀₉ (HD) color space using YC _b C _r is indicated, and in the case of '0b011', the conventional XYZ color space is indicated, but in the present specification, it is defined as indicating xyY color space. A more detailed description thereof will be described later.

In relation to this, the remaining Byte # of FIG. 1 includes individual data or fields based on the contents defined in Byte # 0. For example, the Number_Vertices (_H, _L) field (2 bytes) defines the number of vertexes depicted by the following structure, and the Number_Facets (_H, _L) field (2 bytes) is the facets of the facets depicted by the following structure: Define the number.

FIG. 3 is a diagram illustrating a data structure of range boundary descriptions (GBD) defined in the HDMI standard according to the present invention.

Referring to FIG. 3, the description of Byte # 0 refers to the description of FIG. 2. However, if the value of the corresponding field is '0b001', the GBD_Color_Space field indicates the RGB representation of the xvYCC ₆₀₁ coordinate system. If the value is '0b010', the GBD_Color_Space field indicates the RGB representation of the xvYCC ₇₀₉ coordinate system. Defined as indicating that the expression is related to the xyY coordinate system.

Byte # 1 to N include N bytes of packetized range data (Packeted_Range_Data). The packetized range data includes, for example, at least two of Min_Red_Data, Max_Red_Data, Min_Green_Data, Max_Green_Data, Min_Blue_Data, and Max_Blue_Data.

4 is a diagram illustrating a data structure of Vertices / Facets boundary boundary descriptions (GBD) defined in the HDMI standard according to an embodiment of the present invention.

Referring to FIG. 4, in describing the GBD data structure according to the present invention, the descriptions of the parts in common with the above description will be referred to the contents of FIGS. Explain mainly.

Referring to FIG. 4, GBD_Color_Precision is the same, still using Facet_Mode in the GBD data structure according to the present invention. However, as described above, with respect to the color space of the GBD data, it is shown in Table 1 below.

3 bits Color space of GBD data 0b000 ITU-R BT.709 (using RGB) 0b001 xvYCC601 (IEC 61966-2-4.SD) (using YC _B C _R ) 0b010 xvYCC709 (IEC 61966-2-4.HD) (using YC _B C _R ) 0b011 xyY

Next, Byte # 1 is defined for Number_Vertices. However, in FIG. 2, it is fixed as '4' in relation to the present invention as compared to the high (H) and the low (L). This is defined in the following Byte # 2 to 13, in the context of the present invention, information relating to the xy chromaticity diagram, for example, packetized GBD White, Red, Green This is because it is sufficient to define only four kinds of,, and blue.

This will be described in more detail as follows.

Table 2 below is for Byte # 2 to 4 shown in FIG. 4, which conveys the Y value of the chromaticity coordinates (x, y) and the tristimulus values of the xy chromaticity diagram of the reference white. It is to define.

Byte # 2 Packed_GBD_White_x_chromaticity_diagram Byte # 3 Packed_GBD_White_y_chromaticity_diagram Byte # 4 Packed_GBD_White_Y

Table 3 below is for Byte # 5 to 7 shown in Figure 4, which is the Y value of the chromaticity coordinates (x, y) and tristimulus values of the xy chromaticity diagram of the primary red (Primary Red) To pass.

Byte # 5 Packed_GBD_Red_x_chromaticity_diagram Byte # 6 Packed_GBD_Red_y_chromaticity_diagram Byte # 7 Packed_GBD_Red_Y

Table 4 below is for Byte # 8 to 10 shown in Figure 4, which is the Y value of the chromaticity coordinates (x, y) and tristimulus values of the xy chromaticity diagram of the primary green (Primary Green) To pass.

Byte # 8 Packed_GBD_Green_x_chromaticity_diagram Byte # 9 Packed_GBD_Green_y_chromaticity_diagram Byte # 10 Packed_GBD_Green_Y

Table 5 below is for Byte # 11 to 13 shown in Figure 4, which is the Y value of the chromaticity coordinates (x, y) and tristimulus values of the xy chromaticity diagram of the primary blue (Primary Blue) To pass.

Byte # 11 Packed_GBD_Blue_x_chromaticity_diagram Byte # 12 Packed_GBD_Blue_y_chromaticity_diagram Byte # 13 Packed_GBD_Blue_Y

In connection with the present invention, when a video image including a video signal having an xvYCC color space is received, the HDMI sink may obtain and process the GD information of Tables 1 to 5, that is, the 4D from the HDMI source. . At this time, the HDMI sink performs Gamut Mapping according to the display characteristics based on the information and CIEXYZ to RGB conversion modeling for processing as described above. In this case, the following equation is used in the gamut mapping process.

X + Y + Z = 1 (1)

X = x / y * Y (2)

Z = 1-X-Y (3)

That is, the HDMI sink may convert and process an image signal input from an HDMI source according to its display characteristics through a gamut mapping process. More specifically, according to the above formula, the HDMI sink can process the input video signal if it knows the tristimulus values, that is, the X, Y, and Z values.

Referring to Equation 1, in Equation 1 (1), the sum of the tristimulus values X, Y, and Z is basically 1. Therefore, if only two of the tristimulus values are known, the remaining values can be inferred. In the gamut boundary description (GBD) according to the present invention, the Y value of the tristimulus values is provided. Therefore, the HDMI sink needs to find only the values for X and Z of the tristimulus values. In relation to (2), X of the tristimulus values can be inferred from the x, y, and Y values defined in the Gait Boundary Description (GBD). In (3), Y of the tristimulus values can be obtained using the obtained tristimulus values X and Y. Hereinafter, in the present specification, as described above, a method of obtaining a coefficient of a gamut transform matrix based on triangular boundary description (GBD) and tristimulus value XYZ information obtained using Equation 1 according to the present invention is dynamically changed. In contrast, it is defined as a transform, and in contrast, a method of calculating a case using a predetermined value according to an existing standard is defined as a static gamut transform. However, the term dynamic here does not mean that the gait is dynamic, but that calculation is performed dynamically.

5 is a block diagram illustrating a system for processing an image signal having an xvYCC color space according to an embodiment of the present invention.

Referring to FIG. 5, a system for processing an image signal having an xvYCC color space is largely divided into a source device 500 and a display device 510 which is a sink device. The display device 510 includes an image signal processor 511 and a panel 518.

Hereinafter, each component will be described in more detail with reference to FIG. 5.

The source device 500 collectively refers to a video output device having an HDMI output, and examples thereof include a DVD, a set-top box, a game machine, and the like. The source device 500 transmits a video image including an image signal having an xvYCC color space to the sink device 510 through the HDMI cable 505, and transmits a gamut metadata packet related thereto. Here, the gamut metadata packet includes Gamut Boundary Descriptions (GBD) and other data related to gamut.

The HDMI cable 505 connects the source device 500 and the display device 510 which is a sink device. The HDMI cable 505 basically reads the image data and data on the HDMI function support specification of the display device 510 from the E-EDID ROM 516 of the sink device so that the source device 500 can refer to the basic setting. do.

Next, the internal components of the sink device 510 will be described.

As described above, the sink device 510 includes an image signal processor 511 and a panel 518. The video signal processor 511 includes an HDMI sink 512, a video processor 514, and an Extended Display Identification Data (E-EDID) ROM 516.

The HDMI sink 512 is responsible for decoding data input through the HDMI cable 505 and processes control data transmitted from the source device 500.

The video processor 514 processes the image data processed by the HDMI sink 512 according to the needs of the panel 518 and the user. The video processor 514 includes a specialized xvYCC processor 515 for processing xvYCC data among the image data processed by the HDMI sink 512. The xvYCC processing unit 515 performs gamut mapping on some blocks of the xvYCC block using the measurement data of the panel 518. In this case, the xvYCC processing unit 515 may perform the operation according to the above description with reference to gamut mapping.

The E-EDID ROM 516 is a storage unit that stores the HDMI specification supported by the display device.

The panel 518 displays a display image such as an LCD and a PDP.

FIG. 6 is a flowchart illustrating a process of processing xvYCC image data in a source device in the image signal processing system of FIG. 5 according to the present invention.

First, an HDMI input input is set (S601).

In operation S602, it is determined whether an xvYCC encoded signal is input among video data input according to the HDMI input set in step S601.

If the xvYCC encoded signal is not input as a result of the determination in step S602, the process is terminated. However, if the xvYCC encoded signal is input as a result of the determination in step S602, GBD data (Gamut Boundary Descriptions (GBD) data) is obtained from the input image data (S603).

Based on the obtained GBD data, it is determined what the GBD color space is (S604). That is, it is determined whether or not the GBD color space is XYZ based on the GBD data obtained in step S603.

As a result of the determination in step S604, if the GBD color space is XYZ, the dynamic gamut is calculated using the GBD data obtained in step S603 and the measurement information of the panel (S605), and the input xvYCC data is processed (S607).

However, if it is determined in step S604 that the GBD color space is not XYZ and is a different color space, the calculated static gamut is calculated (S606) to process the input xvYCC data (S607).

For more detailed description of the dynamic gamut and static gamut in steps S605 to S606, the foregoing description is made with reference to FIGS. 4 to 5.

According to the present invention described above, xyY parameters can be defined using CIEXYZ space in HDMI.

On the other hand, the terms used in the present invention (terminology) are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a person skilled in the art, the definition of which is used throughout the present invention. It should be based on what has been done.

The present invention is not limited to the above-described embodiments, and can be modified by those skilled in the art as can be seen from the appended claims, and such modifications are within the scope of the present invention.

And, the above-mentioned numerical value is a preferred embodiment or merely an example, and the scope of the present invention is not limited to the numerical values, and as can be seen in the appended claims, the general scope of the present invention. Modifications are possible by those skilled in the art and such modifications are within the scope of the present invention.

1 is an example of a system block diagram depicting an HDMI system architecture in connection with the present invention,

FIG. 2 is a diagram for explaining the data structure of Vertices / Facets Gamut Boundary Descriptions (GBD) defined in the HDMI standard in relation to the present invention.

3 is a diagram illustrating a data structure of range boundary descriptions (GBD) defined in the HDMI standard in relation to the present invention;

4 is a diagram illustrating a data structure of Vertices / Facets boundary boundary descriptions (GBD) defined in the HDMI standard according to an embodiment of the present invention.

5 is a block diagram illustrating a system for processing an image signal having an xvYCC color space constructed according to an embodiment of the present invention.

FIG. 6 is a flowchart illustrating a process of processing xvYCC image data in a source device in the image signal processing system of FIG. 5 according to the present invention.

* Description of the major signs in the drawings

500: source device 510: sink device

512: HDMI sink 514: video processing unit

515: xvYCC processing unit 516: E-EDID ROM

517: panel

Claims (17)

Receiving image data having a specific color space; Get Gamut Boundary Description (GBD) data including gamut metadata having Tristimulus values (XYZ) data structure in relation to a color space from the received image data (get) step; And Extracting gamut metadata from the obtained gamut boundary description (GBD) data, and converting gamut of the input image data by obtaining tristimulus value data according to a predefined equation based on the extracted gamut boundary metadata; The video signal processing method characterized in that the. The method of claim 1, Gamut metadata having a tristimulus data structure with respect to the color space, Include first information indicating a color space of the gamut boundary description (GBD) data; The first information includes a first field for the number of vertices and a second field for an xy chromaticity diagram for each vertex according to the number of vertices. Image signal processing method characterized in that. The method of claim 2, The value of the first field is And 4 indicating white, red, green, and blue. The method of claim 2, The second field is, And a Y value among chromaticity coordinates and tristimulus values for each vertex according to the value of the first field. The method of claim 2, The first information is, ITU-R BT using RGB. 709, xvYCC ₆₀₁ and xvYCC ₇₀₉ using YC _b C _r , and xyY using tristimulus values. The method of claim 2, Gamut metadata having a tristimulus data structure with respect to the color space, Second information indicating whether the following data is a vertexs / facets description or range description, the format type, and the facets included in the gait boundary description (GBD). And at least one of third information for indicating and fourth information for indicating the size of each component of each vertex or range entry. The method of claim 1, The predefined formula is, A video signal processing method, wherein X + Y + Z = 1, X = x / y * Y, and Z = 1-X-Y. A source device with an HDMI output; While receiving and processing the HDMI output including the image data having a specific color space from the source device, A video signal processing unit for converting gait boundary description (GBD) data including gait boundary metadata having gamut metadata having a tristimulus data structure with respect to a color space from the image data included in the HDMI output; Sink devices; And And a cable connecting the source device and the sink device to transmit and receive data. The method of claim 8, The video signal processor, A sink unit for extracting gamut boundary description (GBD) data from the image data, and extracting and decoding gamut metadata from the extracted gamut boundary description (GBD); And a video processor configured to convert the gamut of the image data by using the decoded gamut metadata and a predefined equation to process the corresponding video data. 10. The method of claim 9, The video signal processor, And a storage unit which stores configuration / state information supported by the sink unit. 10. The method of claim 9, The video processor, And a color space processor for performing gamut mapping on some blocks of the corresponding data blocks to process the specific color space. The method of claim 11, The color space processing unit, In performing gamut mapping based on gamut metadata having a tristimulus data structure with respect to the color space, Extract first information indicating a color space from the decoded gamut metadata, Here, the first information includes a first field for the number of vertices and a second field for an xy chromatity diagram for each vertex according to the number of vertices. Signal processing system. The method of claim 12, The color space processing unit, And if the value of the first field is 4, each vertex is recognized as indicating white, red, green, and blue. The method of claim 12, The color space processing unit, And a Y value of a chromaticity coordinate and a tristimulus value for each vertex as the value of the second field according to the value of the first field. The method of claim 12, The color space processing unit, ITU-R BT using RGB from the first information. 709, xvYCC ₆₀₁ and xvYCC ₇₀₉ using YC _b C _r and xyY using tristimulus values. The method of claim 12, The color space processing unit, Second information indicating the format type whether the data following from gamut metadata having a tristimulus data structure with respect to the color space is vertexes / facets description or range description, included in gamut boundary description (GBD) And at least one of third information indicating facets and fourth information indicating the size of each component of each vertex or range entry. The method of claim 12, The color space processing unit, The predefined formula, i.e. An image signal processing system comprising calculating using X + Y + Z = 1, X = x / y * Y, and Z = 1-X-Y.

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