KR20030005554A - Apparatus and method for managing display automatically with metadata - Google Patents

Abstract

PURPOSE: An apparatus and a method for automatically adjusting a screen using meta data are provided to utilize the meta data and automatically maintain the preferred status of the screen by each multimedia data. CONSTITUTION: An apparatus for automatically adjusting a screen using meta data includes an image property extracting part(120) extracting image properties of multimedia data; an agent(140) extracting the properties of a display device and user preference elements; a meta data constructing part(160) constructing meta data with the image properties, the properties of the display device, and the user preference elements; and a screen adjusting part(180) automatically executing screen adjustment to each multimedia data in response to the meta data.

Description

Apparatus and method for managing display automatically with metadata}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display apparatus, and more particularly, to a screen adjusting apparatus and a method for automatically adjusting screen using metadata.

With the increase in the amount of multimedia data, the development of multimedia-related technologies, and the widening trend of various networks, technological movements for effectively satisfying user's various desires for multimedia contents have been actively performed. Display devices for outputting such multimedia data generally have a function of adjusting the characteristics of the screen itself. However, since these functions are fixed until the user manually manipulates them, it is almost impossible to adjust the screen to suit each image data to be displayed, and frequent screen adjustments are troublesome for the user. have. In addition, since the screen characteristics of the multimedia contents change from time to time according to the characteristics of the screen, it is almost impossible to provide a user's preferred output state for each multimedia data.

The technical problem to be achieved by the present invention is to configure the image characteristic value of the multimedia data, the characteristic value of the display device and the user preference elements as metadata, the automatic screen adjustment device that can provide the user preferred output state for each multimedia data And providing a method.

1 is a block diagram of a screen adjustment apparatus according to a preferred embodiment of the present invention.

2 is a flowchart illustrating a screen adjusting method according to a preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10: data storage unit 20: display device

30: user 40: encoder

100: screen adjustment device 120: image characteristic value extraction unit

140: agent 160: metadata component

180: screen adjustment unit

In order to achieve the above object, the automatic screen adjustment device according to the present invention,

An image characteristic value extracting unit which extracts image characteristic values of the multimedia data; An interface unit for extracting characteristic values of the display device and user preference elements; A metadata construction unit configured to configure the image characteristic value, the characteristic value of the display device, and the user preference element as metadata; And a screen adjustment unit for automatically performing screen adjustment on each of the multimedia data in response to the metadata.

Automatic screen adjustment method according to the present invention to achieve the above object,

If the multimedia data includes an image characteristic value, extracting the image characteristic value; Calculating the video characteristic value when the multimedia data does not include the video characteristic value; Extracting feature values and user preference elements for the display device; Organizing the preference element and the characteristic values into metadata; And automatically performing screen adjustment on each of the multimedia data in response to the metadata.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a block diagram showing the configuration of a screen adjusting apparatus 100 according to a preferred embodiment of the present invention. Referring to FIG. 1, the screen adjustment apparatus 100 may include an image feature value extractor 120 extracting an image feature value C1 of multimedia data, an agent extracting a feature value C2 and a user preference element C3 of a display device. (agent; 140), a metadata constructing unit 160 configured to configure the extracted image characteristic value C1, the characteristic value C2 of the display device, and the user preference element C3 as metadata, and the multimedia in response to the configured metadata. And a screen adjusting unit 180 which automatically performs screen adjustment for each data. An operation performed by each component of the screen adjusting apparatus 100 is as follows.

The image characteristic value extractor 120 extracts the image characteristic value C1 of the multimedia data stored in the data storage unit 10. The data storage unit 10 is a data storage means for storing a plurality of images, for example, a database including a large amount of image data. The database may include a number of still images such as photographs, or may include multimedia data such as movies or dramas.

The image characteristic value extracting unit 120 extracts the characteristic value C1 of the multimedia data, if the image characteristic value C1 is composed of metadata, without a separate calculation process. If the image characteristic value C1 of the multimedia data is not composed of metadata, the color temperature and gamma characteristics of the multimedia data are calculated and used as the image characteristic value C1.

Color temperature is a quantification of the visible visible energy emitted when a suitable temperature is applied to a black emitter such as graphite, and is used to quantify the warmth and coolness that humans feel in an image. The color temperature, expressed in Kelvin (K °), is expressed as the absolute temperature (273 °) plus the Celsius temperature when the object exhibits a unique color. The color temperature is calculated by the illumination color obtained by the converted color coordinate system after the coordinate system of the image is converted into the chromaticity coordinates of the light source. There are several ways to obtain the illumination color in the color coordinate system of the light source, one of which is to use the density of the color. This method obtains the angle and distance which form a white reference point with respect to each point of a color coordinate system, and synthesize | combines two images obtained from the obtained angle and distance. Then, pixels having the same value are collected from the synthesized image, and the illumination color is determined according to the number of collected color sets. Such a method is disclosed in Japanese Patent Laid-Open No. 10-118862 and Korean Patent Registration No. 10-230446 obtained by the present applicant. Another method of obtaining the illumination color is a method capable of high-speed processing, which finds a plurality of color transition bands, approximates a straight line from the chromaticity coordinates of the pixels included in each color transition band, and calculates an average of intersection points between the straight lines. This is the method of setting the lighting color. This method is disclosed in Korean Patent Registration No. 10-237284 obtained by the applicant. In addition, the color temperature is converted to a natural feel by M. Nielsen and M. Stokes, as shown in the 1998 Proceedings IS & T / SID 6th Color Image Conference, pages 253-257, "The Creation of the sRGB ICC Profile." Can be. According to this method, for example, in the case of converting (X, Y, Z) DC1 specified at color temperature C1K (DC1) to (X, Y, Z) DC2 specified at color temperature C2K (DC2K), (X, Y , Z) DC2 is expressed as

[Equation 1]

Here, (Xwhite_DC1, Ywhite_DC1, Zwhite_DC1) and (Xwhite_DC2, Ywhite_DC2, Zwhite_DC2) represent tri-stimulus with respect to the white reference points of (X, Y, Z) DC1 and (X, Y, Z) DC2, respectively. By knowing the white reference point of the two color temperatures to be converted, one can simply calculate the conversion matrix. In this method, the smaller the difference between the two color temperatures to be converted, the smaller the error due to the conversion. The method of calculating the white reference points (Xwhite, Ywhite, Zwhite) of two color temperatures to be converted is as follows.

First, the chromaticity coordinates x _D , y _D and z _D corresponding to the color temperature Tc may be expressed as follows.

The color temperature (Tc) is 1000K <When Tc <7000K, the chromaticity coordinates _{(x D, y D, z} D) x D is

[Equation 2]

That is, _D x of the color temperature (Tc) is the 7000K ≤ Tc ≤ 25000K, the chromaticity coordinates _{(x D, y D, z} D) is

[Equation 3]

Becomes And, _D y of the chromaticity coordinates _{(x D, y D, z} D) is

[Equation 4]

Becomes When x _D and y _D are determined by [Equation 2] to [Equation 4], the white reference points (Xwhite, Ywhite, Zwhite) are

[Equation 5]

Is determined as follows. This method is effective when the effective color temperature range is in the range of about 4000K to 25000K.

The agent 140 is connected to the display apparatus 20 and the user 30 to extract the characteristic value C2 and the user preference element C3 of the display apparatus 20. The characteristic value C2 of the display apparatus 20 includes a color temperature or correlated color temperature and a gamma characteristic value, and the user preference element C3 includes a color temperature and gamma characteristic of the display apparatus 20 set by the user. The setting state of is included. There are several ways to obtain the color temperature and gamma characteristics of the display device 20. One of them is a colorimetric method using a colorimeter, and the other is a color temperature mode provided in the display device 20. How to use. For example, when the display device 20 is a computer monitor, the computer monitor is provided with several color temperature modes that can be set by the user so that the user can set an arbitrary color temperature mode. In this case, the color temperature value set by the user may be used as the color temperature of the display apparatus 20. The gamma characteristic of the display apparatus 20 is determined by the scanning method of the display apparatus 20. For example, it is assumed that the display device 20 of the sRGB method has a value of 2.4, and the display device 20 of the National Television System Committee (NTSC) method has a gamma characteristic of 2.2. These gamma characteristics can also be obtained by visual measurement, such as applications such as Adobe Photoshop or Paint Shop Pro.

The agent 140 is a concept used in a user interface, and means an apparatus or software used in the middle for smooth information exchange between a user and a computer. For example, if a user uses an input device such as a keyboard or a mouse or simply inputs a voice input to a computer, this is simply called a guide. But if you use artificial intelligence in the middle, analyze and grasp the user's intentions, and deliver this refined content, it's an agent, not a guide. The agent 140 used in the present invention performs direct communication with the display apparatus 20 to extract the feature value C2 and the user preference element C3, or the feature value C2 from the user's direct input. Extract user preference element (C3). If the display device 20 is a computer monitor, a corresponding characteristic value C2 and a user preference element C3 may be directly extracted through a universal serial bus (USB).

The metadata constructing unit 160 configures the image feature value C1 extracted from the image feature value extracting unit 120, the feature value C2 extracted from the agent 140, and the user preference element C3 as metadata. When the image characteristic values and the user preference elements C1, C2, and C3 are configured as metadata by the metadata configuring unit 160, the screen adjusting unit 180 encodes through the encoder 40 in response to the metadata. Automatically performs screen adjustment for each screen of the multimedia data. As a result, the state of the preferred screen is automatically maintained without the user having to manually adjust the state of the device. In particular, the screen adjustment device according to the present invention does not need to extract and construct separate data characteristic value data since multimedia data is used as it is if the video characteristic value is composed of metadata. Thus, the utilization of these metadata, which is limited to search and browsing functions, can be increased. In addition, even if the multimedia data does not include an image characteristic value, the characteristic value of the image data may be calculated and used for automatic screen adjustment.

2 is a flowchart illustrating a screen adjusting method according to a preferred embodiment of the present invention. Referring to FIG. 2, in the screen adjusting method according to the present invention, first, it is determined whether multimedia data is metadata including an image characteristic value C1 (step 121). If the multimedia data is metadata including the image characteristic value C1, the image characteristic value C1 is directly extracted from the multimedia metadata without a separate calculation process (step 122). If the multimedia data does not include the image characteristic value C1, the image characteristic value C1 is calculated by the method described above (step 123). Here, the image characteristic value C1 relates to the color temperature and gamma characteristics of the image, and these may be configured as metadata in the multimedia data, but may not be configured as metadata in some cases. Therefore, in the present invention, when the image characteristic value C1 is composed of metadata, the image characteristic value C1 is used as it is (step 122). Otherwise, it is calculated and used (step 123).

When the extraction of the image characteristic value C1 is performed, the characteristic value C2 and the user preference element C3 for the display apparatus are extracted (step 141). The characteristic value C2 for the display apparatus is the color temperature and gamma characteristics of the display apparatus, and the user preference element C3 is a setting state for the color temperature and gamma characteristics of the display apparatus set by the user. The characteristic value C2 and the user preference element C3 of the display device are extracted by the agent, and depending on the circuit configuration, the agent may directly receive the characteristic value data C2 and C3 using USB or the like.

As described above, when the image characteristic value C1, the characteristic value C2 of the display device, and the user preference element C3 are all extracted, these characteristic values C1 and C2 and the user preference element C3 are composed of metadata. In step 161, screen adjustment for each data by metadata is automatically performed (step 181).

In the above, as an embodiment of the present invention has been specifically illustrated for the automatic screen adjustment for the multimedia data, the present invention can be applied to other displays such as still images.

The invention can also be embodied as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like, and may also be implemented in the form of a carrier wave (for example, transmission over the Internet). Include. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

As described above, according to the screen adjusting apparatus and method according to the present invention, the characteristic value of the display device, the user preference element, and the image characteristic value of the multimedia data are extracted, and the extracted characteristic values and the user preference element are metadata. It is configured to, the screen adjustment by data is automatically performed. At this time, if the image characteristic value is composed of metadata in the multimedia data, it is extracted as it is, otherwise it is calculated and used. Therefore, the utilization of these metadata, which is limited to search and browsing functions, can be increased, and the user can automatically maintain a preferred screen state for each multimedia data without having to manually adjust the state of the device.

Claims (7)

An image characteristic value extracting unit which extracts image characteristic values of the multimedia data; An interface unit for extracting characteristic values of the display device and user preference elements; A metadata construction unit configured to configure the image characteristic value, the characteristic value of the display device, and the user preference element as metadata; And And a screen adjustment unit for automatically performing screen adjustment for each of the multimedia data in response to the metadata. The apparatus of claim 1, wherein the interface unit is directly connected to the display device and includes an agent that directly extracts a characteristic value of the display device. The automatic screen adjustment apparatus of claim 1, wherein the image characteristic value extracting unit calculates the image characteristic value when the multimedia data does not include the image characteristic value. The apparatus of claim 1, wherein the image characteristic value, the characteristic value of the display apparatus, and the user preference element are any one of a color temperature and a gamma characteristic. If the multimedia data includes an image characteristic value, extracting the image characteristic value; Calculating the video characteristic value when the multimedia data does not include the video characteristic value; Extracting feature values and user preference elements for the display device; Organizing the preference element and the characteristic values into metadata; And And automatically performing screen adjustment on each of the multimedia data in response to the metadata. The method of claim 5, wherein the image characteristic value, the characteristic value of the display device, and the user preference element are any one of a color temperature and a gamma characteristic. A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 5 to 6.