KR20100005069A - True color communication - Google Patents

Abstract

Embodiments of the present invention recite a system and method for conveying the true color of a subject. In one embodiment, the present invention comprises an image capture device (201), an imaged reference color set (202) comprising at least one reference color (202a) and a control reference color set (203) comprising at least one control color (203a) corresponding to the at least one reference color (203a). The present invention further comprises a color correction component (204) for accessing the control reference color set and the imaged reference color set (202) and for generating a color correction function (210) which eliminates a discrepancy between the at least one reference color (203a) and the at least one control color (203a).

Description

Image Capture System {TRUE COLOR COMMUNICATION}

Embodiments of the invention relate to accurately capturing and transferring the color of a subject.

In the field of image capture and reproduction, the processing parameters of the image capture and image display device are preset by the manufacturer. Typically, the manufacturer sets these parameters so that the generated image looks "good" so that the user is satisfied with the result. This is also referred to as a "photofinishing or preferred reproduction model" and is in contrast to a "colorimetric reproduction model" which focuses on delivering the correct color of the subject. For example, many digital cameras perform a task called "white balancing" where the imaging parameters are adjusted such that the overall average color of the image is, for example, the color of a half-brightness gray image (50% gray). have. This is done with the assumption that the imaged view is in fact 50% gray, but in reality it is not. Thus, white balancing is merely an arbitrary adjustment that works qualitatively to produce a visible image, but not qualitatively to produce an accurately depicted image.

As an example of a white balancing process, the darkest and brightest description values (eg, black and white levels) of an image are typically clipped by analysis of the distribution of observed brightness levels. By this removal, the usable signal range can be reliably utilized. For example, a predetermined percentage of dark and light values are removed and mapped to the same value (eg, zero or maximum). Values in between are scaled over the available range. However, doing this scaling to make the final image more pronounced can distort the true color spectrum. Typically these adjustments are predetermined by the manufacturer and applied uniformly to all of the acquired images. Thus, processing parameters of the digital camera cannot solve rendering the "true" color of the item of the view, since the rendering cannot be determined without other information.

Also, the overall color of the image may be distorted depending on the state of ambient light present when the image is captured. For example, when taken indoors, the light emitted by the emitter may be weighted in a specific range of the color spectrum. For example, a fluorescent lamp may emit light in a slightly blue color. Thus, a picture taken under fluorescent light will be distorted by the ambient light, thus depicting the subject in a more blue tint than it actually is.

To solve this distortion problem, a controlled environment can be provided in which the image processing parameters of the image capture device are precisely adjusted and monitored. This controlled environment also relies on precisely adjusting and controlling the light to identify or minimize any distortion produced by the ambient light and image processing device.

In addition to the problem of capturing photometrically accurate images, it is also problematic to reproduce the image without introducing distortion into the color space. For example, the color reproduction of a computer monitor or other display device changes over time. As a result, the displayed color value may slightly "drift" from a preset adjustment parameter over time. In applications where it is important for color rendering to be kept constant (eg computer animation), it is sometimes necessary to perform precise analysis and re-adjustment of computer monitors. Similarly, the printer is calibrated before sale, but online calibration is typically limited to on / off testing of the nozzle function. You can also use the scanner to adjust or readjust colors, but this combines the possible inaccuracies in both printing and scanning of the image.

Embodiments of the present invention disclose a system and method for delivering a true color of a subject. In one embodiment, the present invention includes an image capture device, an imaged reference color set including at least one reference color and a control reference color set including at least one control color corresponding to the at least one reference color. . The invention further includes a color correction component that accesses the control reference color set and the imaged reference color set to generate a color correction function that eliminates inconsistency between the at least one reference color and the at least one control color.

The accompanying drawings, which are incorporated in and constitute a part of this specification, disclose embodiments of the invention together with the description, to help explain the principles of the invention. Unless otherwise stated, it will be understood that the drawings referenced in this detailed description are not drawn to scale.

1 is a flowchart illustrating a method of transmitting an original color of a subject according to an embodiment of the present invention;

2A, 2B, 2C illustrate exemplary image capture systems used in accordance with embodiments of the present invention;

3 illustrates an exemplary reference color set used in an embodiment of the invention,

4 is a block diagram of a color correction component according to an embodiment of the present invention;

5 is a block diagram of an exemplary computer system in which embodiments of the present invention may be implemented.

Reference will now be made in detail to embodiments of the invention, examples of which are illustrated in the accompanying drawings. While the invention will be described in accordance with the following examples, it will be understood that this invention is not limited only to these examples. Rather, the invention includes alternatives, modifications and equivalents as may be included within the spirit and scope of the invention as defined in the appended claims. In addition, in the following detailed description of the invention, specific numerical values will be mentioned for ease of understanding the invention. However, embodiments of the invention may be practiced outside of these specific values. In other instances, existing methods, processing procedures, components and circuits have not been described in detail in order not to unnecessarily obscure aspects of the present invention.

Notation and nomenclature

Some of the detailed descriptions below are provided as procedures, logical blocks, processing, and other symbolic representations of operations on data bits in computer memory. These descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. In this specification, procedures, logic blocks, processes, and the like are considered to be a coherent sequence of steps or instructions for obtaining a desired result. This step requires physical manipulation of the physical quantity. Typically, these physical quantities take the form of electrical or electronic signals that can be stored, transferred, combined, compared, and otherwise manipulated in a computer system, but are not necessarily so.

Note, however, that these terms and similar terms are all associated with appropriate physical quantities and are merely convenience notations applied to these physical quantities. In the present invention, such as "access", "create", "apply", "connect", "use", "identify", "save", "generate", "capture", etc. Descriptions using the terminology, unless specifically stated otherwise in the following description, operate in computer systems or other similar electronic computing devices by manipulating data expressed as physical (electronic) quantities in registers and memories of the computer. Refers to the action and processing of converting into other data similarly represented as a memory, a register, or other information storage, transfer, or physical quantity in a display device.

1 is a flowchart of a method 100 for delivering a true color of a subject in accordance with an embodiment of the invention. In step 110 of FIG. 1, an imaged reference color set that includes at least one other reference color is accessed. In an embodiment of the invention, an image comprising a set of reference colors is captured. The imaged reference color set may be only one object of the captured image, or may be included in the captured image of the subject. In an embodiment of the present invention, the subject may be a person or may be a place or another that can capture an image thereof.

Typically, the amount of light and spectral characteristics of the light irradiated onto a given subject affects the appearance of the camera and the subject appearing in the image generated by the camera. The camera itself introduces additional changes in the perceived color of the subject due to the physical characteristics in the design and manufacture of the sensor and the internal processing characteristics of the camera. When these effects are combined, the color measurement criteria of the captured image become very unclear. Embodiments of the present invention provide a reference color space, i.e., an ambient light state and It is easy to determine whether to convert the image into a "true" color space that is independent of the camera's image processing capabilities.

In step 120 of FIG. 1, a control reference color set is accessed that includes at least one control color corresponding to at least one reference color. In an embodiment of the invention, the true color space is represented by a control reference color set that includes a color corresponding to the color of the imaged reference color set. The control reference color set may comprise a logical reference color set that is accessed to obtain the spectral reflectance and color signal values of the reference color set in the captured image rather than the actual physical entity.

In step 130 of FIG. 1, a color correction function is generated that eliminates inconsistency between the at least one reference color and the corresponding control color. By comparing the characteristics of the control reference color set with the characteristics of the imaged reference color set captured in the image, embodiments of the present invention allow for variations, i. Color correction function ". This color correction function directly compensates for the combined effect of ambient light in the room and color distortion of the captured camera.

To easily determine this reference transform, embodiments of the present invention detect an imaged reference color set in an image and measure the observed characteristics of the imaged reference color set. Embodiments of the invention then determine a color correction function that will provide a color depiction that is close to the color value of the control reference color set among the color depictions of the imaged reference color set. This color correction function is applied to the captured image, or subsequently captured image, so that the colors in the image can more accurately convey the true color of the subject.

As such, embodiments of the present invention can infer the coupling effects of device features and image processing capabilities of the image capture system and the ambient light state of the location where the image was captured. These combined effects must be substantially eliminated in the image to convey a more accurate color representation of the subject. In an embodiment of the invention, the color correction function may be generated and applied by the image capture device itself, by the device displaying the image, by a service by a third party, or through a combination thereof.

2A illustrates an example image capture system 200 used in connection with an embodiment of the present invention. In an embodiment of the invention, the system 200 includes an image capture device 201, an imaged reference color set 202, a control reference color set 203, and a color correction component 204. In the embodiment of FIG. 2A, the imaged reference color set 202 further includes at least one reference color 202a and a unique identifier 202b. In addition, the control reference color set 203 further includes at least one control color 203a corresponding to the at least one reference color 202a and a corresponding identifier 203b corresponding to the unique identifier 202b.

In an embodiment of the invention, the color correction component 204 is for accessing the imaged reference color set 202 and the control reference color set 203. Specifically, the color correction component 204 compares the reference color 202a with the control color 203a and, due to the ambient light condition and image processing parameters of the image capture device 201, sets the imaged reference color set ( It is determined how much the color of 202 has been converted. The color correction component 204 then generates a color correction function (eg, 210) that removes if there is a mismatch between the reference color 202a and the control color 203a.

In an embodiment of the invention, the system 200 further includes an applicator 205 connected with the color correction component 204. In an embodiment of the invention, the application unit 205 applies the color correction function 210 generated by the color correction component 204 to the image (eg, 206) to generate the modified image 207. By doing so, the device characteristics and image processing capabilities of the image capture device 201, as well as the coupling effect of the ambient light state at the location where the image 206 is captured, are removed from the modified image 207. As a result, the true color of the subject (eg, 211) is transferred to the modified image 207. In the present invention, the term “removed” means that the difference between the reference color in the imaged reference color set 202 (eg, the modified image 207) and the reference color in the control reference color set 203, Note that it is outside the detection parameter range of the system 200 or within the allowable deviation.

As discussed above, in embodiments of the present invention, an imaged reference color set 202 may be captured within an image 206 such as the subject 211. In another embodiment, the imaged reference color set 202 may be captured in an image different from the image 206 in which the subject 211 was captured. This may be beneficial in situations where it is not desirable to represent the imaged reference color set 202 in the same image as the subject 211. For example, in studio photography, the photographer would not want the imaged reference color set 202 to appear in the portrait of the subject 211. Thus, the photographer can capture the first image of the imaged reference color set 202 and use it in determining the color correction function 210. The captured image of the subject 211 is then processed using the color correction function 210 previously generated by the color correction component 204. In one embodiment, the system 200 further includes a color correction function 210 and a data storage device 208 for storing one or more images (eg, the image 206, the modified image 207, etc.). . Note that in the embodiment of the present invention, the ambient light condition and the image processing capability of capturing each image must be substantially the same to derive an accurate color correction function 210.

Note that the configuration of the system 200 of FIG. 2A is exemplary and other components of the configuration are possible in accordance with embodiments of the present invention. For example, the color correction component 204, the application unit 205, and the data storage device 208 may be implemented as separate color correction systems, or may be implemented as a network of communicatively connected components. In an embodiment of the present invention, the functions of the color correction component 204, the application unit 205, and the data storage device 208 may be performed as a service by a third service provider, or a provider of the network 209. Can be. Alternatively, the color correction component 204, the application unit 205, and the data storage device 208 can be implemented as components of the image capture device 201. In another embodiment, the applicator 205 is disposed in the image capture device 201 communicatively coupled with the color correction component 204 and the data storage device 208. Thus, the image capture device 201 receives the color correction function 210 via the network 209 and applies it to the image 206, producing a modified image 207. In another embodiment, the color correction component 204, the application unit 205, and the control reference color set 203 are removable, using a removable medium, such as a smart card or other removable data storage device. It may be implemented as a component (eg, of image capture device 201).

In an embodiment of the invention, the image capture device 201 does not require a controlled infrastructure when capturing the image 206. For example, the image capture device 201 may be a personal computer system of a subject, a digital camera or a mobile phone capable of generating a picture (for example, referred to as an "picture phone"). Thus, embodiments of the present invention may capture the image 206 using the subject's personal equipment, rather than relying on the adjusted device (eg, adjusted camera and adjusted light). Moreover, if the light state is maintained enough for the color correction component 204 to process the image, it is not necessary to know the ambient light state or to capture the image 206 in an environment in which the ambient light state is controlled. As a result, the image 206 may be captured, for example, in a variety of environments, including outdoors or home of the subject 211.

Embodiments of the present invention, because the color correction component 204 uses the received image of the imaged reference color set 202 to estimate the ambient light condition and image processing parameters of the image capture device 201, It is preferable in that it does not require a controlled facility. For example, the color correction component 204 can compare the color depiction of the color comprising the imaged reference color set 202 with the color depiction of the corresponding color from the control reference color set 208. As a result, the embodiment of the present invention does not rely on the adjusted camera or the adjusted light when capturing an image of the subject 211. By performing this analysis, the color correction component 204 can infer the combined effect of the ambient light state at the location where the subject 211 is located and the image processing performance of the image capture device 201. The color correction component 204 then associates the received spectral reflectance and color signal values of the imaged reference color set 202 with the known spectral reflectance and color signal values of the control reference color set 203. You can decide what adjustments are needed. Thus, the color correction component 204 compensates for image distortion caused by ambient light conditions and image processing parameters of the image capture device 201 when capturing an image, and based on this analysis, the subject 211 You can guess the exact color that depicts. Although the present invention discloses that no controlled facility is required, embodiments of the present invention can also be used in controlled installations.

In an embodiment of the invention, the image capture device 201 is a device, such as a printer, scanner, videophone, digital camera, PDA, personal computer system, digital video recorder, or similar device capable of capturing images. Can include personal collections. However, embodiments of the present invention may be used in their own systems, where manufacturers have prepared kiosks or other automated systems to provide product consultants.

In an embodiment of the present invention, network 209 includes a dial-up Internet connection, a public switched telephone network (PSTN), a high speed network connection (eg, cable Internet, or high speed computer network), and the like. Alternatively, the image capture device 201 may use a cellular telephone connection, a satellite telephone connection, a wireless connection, an infrared communication connection, or the like.

In an embodiment of the invention, accurately expressing true color to the viewer is as important as capturing the true color of the subject 211. Thus, embodiments of the present invention can be used to adjust the display such that the color seen by the display is as desired. In other words, removing the color distortion generated by the display device is also important for conveying the true color of the subject. In an embodiment of the present invention, the data accessed by the display may be described as "raw" data that has not yet been processed as described above with reference to FIG. 2A. In another embodiment, the data accessed by the display will be described as "processed" data processed as described above with reference to Figure 2A.

Moreover, it should be understood that embodiments of the present invention are not limited to color correction. For example, in an embodiment of the present invention, the color correction component 204 examines the reference color set 202 imaged for a geometric pattern such that a lens of the image capture device 201 can display geometric defects in the image 206. It can be determined whether it is being introduced. If geometric defects are detected in the image 206, the color correction function may further include a transform function to correct these defects in the modified image 207.

2B illustrates another exemplary image capture system used in accordance with an embodiment of the present invention. In the embodiment of FIG. 2B, the data accessed by the display device may be described as "processed" data that has been processed as described above with reference to FIG. 2A, indicating "true" color. In FIG. 2B, the display device 220 generates the display 221. In an embodiment of the invention, the display 221 may include a printed display, a projected display, a digitally generated display, and the like. In FIG. 2B, an imaged reference color set 202 appears on the display 221, with a physical reference color set 222 disposed in proximity to the display 221. Note that the imaged reference color set 202 may include a reference color 202a and a unique identifier 202b, as described above with reference to FIG. 2A. Similarly, the physical reference color set 222 may further include a physical reference color 222a and a corresponding identifier 222b. Note that the spectral reflectance and color signal values of the physical reference color 222a may correspond to the spectral reflectance and color signal values of the control reference color set 203 as described above with reference to FIG. 2A.

In an embodiment of the present invention, the ambient light condition and image processing parameters of the image capture device 201 may first be determined prior to processing the imaged reference color set 202 shown on the display 221. Thus, in one embodiment, the color correction component 204 compares the physical reference color 222a with the control color 203a and, due to the ambient light condition and the image processing parameters of the image capture device 201, is imaged. Determine how the reference color set 202 has been transformed. The color correction component 204 then makes some adjustments to match the received spectral reflectance and color signal values of the physical reference color set 222 to the known spectral reflectance and color signal values of the control reference color set 203. You can decide if this is necessary. The color correction component 204 then compensates for the distortion of the image caused by the ambient light condition or image processing parameters of the image capture device 201 when capturing the image of the physical control reference color set 222. A color compensation function 210 is generated.

As shown in FIG. 2B, the imaged reference color set 202 and the physical control reference color set 222 are imaged simultaneously by the image capture device 201. In an embodiment of the invention, the image 202 is a "true" color depiction of the provided control reference color set 203, and the captured image 206 is passed to the color correction component 204, where the imaged reference A color correction function is generated based on the comparison of the color set 202 and the control reference color set 203 '. Thus, when a mismatch between the imaged reference color set 202 and the control reference color set 203 ′ is detected by the color correction component 204, the imaged reference color set 202 and the control reference color set ( A second color correction function 225 is generated that eliminates mismatches between 203 '). As described in more detail below, in an embodiment of the present invention, the color correction component 204, or the application unit 205, may generate a color adjustment value generator for controlling at least one color control of the display 221. It may include. Thus, in the embodiment of FIG. 2B, the application unit 205 is configured such that the reference color set 202 and the control reference color set 203 ′ imaged by the second color correction function 225 changing one of the color controls of the display. In response to removing the inconsistency between the < RTI ID = 0.0 >), < / RTI >

In other words, embodiments of the present invention determine a first transform function (eg, color correction function 210) between the physical control reference color set 222 and its own photometric apprarance of accurate viewing. A second conversion function (eg, second color correction function 225) between the control reference color set 203 ′ and the imaged reference color set 202 is determined. Mapping the display to accurate viewing in the image can be determined by properly combining these two transformations. The color correction function 210 takes into account the combined effect of the illumination and image capture parameters on the observed colors of the physical control reference color set 222. The second color correction function 225 takes into account the combined effects of illumination, display parameters of the display 220, and image capture parameters. Thus, an inverse product process of the color correction function 210 and the second color correction function 225 may be performed to determine the effect of the display parameters of the display 220. As a result, the output of the display device 220 is output to the system 200 so that not only the display parameters of the display device 220 but also the ambient light condition in the display device 220 does not affect the color representation in the display 221. Can be controlled by In other words, the image displayed by the display device 220 is currently independent of the ambient light condition and the image processing capability of the camera capturing the image, and the true color of the subject can be accurately transmitted by the system 200. . Note also that the control reference color set 203 ′ applied to the displayed image 202 need not be different from the reference set 203 applied to the physical control reference color set 222. If the data accessed by the display device 220 is the same as the color depiction (ie, processed to be 203) of the physical control reference color set 222, these reference sets will be the same.

Note that the configuration of the system 200 of FIG. 2B is exemplary and other configurations of the components are possible in accordance with embodiments of the present invention. As described above, the color correction component 204, the application unit 205, and the data storage device 208 may be implemented in different color correction systems, or may be implemented as a network of communicatively connected components. It may be. In an embodiment of the present invention, the functions of the color correction component 204, the application unit 205, and the data storage device 208 may be performed as a service by a third service provider, or a provider of the network 209. Can be. Alternatively, the color correction component 204, the application unit 205, and the data storage device 208 may be implemented as components of the image capture device 201 or the display device 220. This process may be done once as an adjustment step of the display device 220 such that the final display of the image 202 on the display 221 is within the tolerance range of the "true" control reference color set 203 ', It may be done in a repetitive or feedback cycle to constantly adjust the color control of the display device 220, or as an adjustment to the accessed color representation of the image 202.

Referring to FIG. 2C, the data accessed by the display device 220 (eg, the modified image 207) is a control color reference set 203 that matches the “true” color of the physical control reference color set 202. It can be described as "synthetic" data, generated according to. As shown in FIG. 2C, the modified image 207 and the imaged reference color set 202 are imaged simultaneously by the image capture device 201. In an embodiment of the present invention, this image 206 is passed to the color correction component 204, where two reference color sets—the displayed image 207 and the reference color set shown in the modified image 207. (202) Generate a color correction function based on the comparison of. Thus, if a discrepancy between the modified image 207 and the reference color set 202 is detected by the color correction component 204, it is possible to eliminate the discrepancy between the modified image 207 and the reference color set 202. Color correction function 225 is generated. As described in more detail below, in an embodiment of the present invention, the color correction component 204 or the application unit 205 includes a color adjustment value generator for controlling at least one color control of the display 221. can do. Thus, in the embodiment of FIG. 2C, the application unit 205 is configured such that the second color correction function 225 changes one of the color controls of the display 221 so that the reference color and the reference color of the modified image 207 are used. In response to removing the inconsistency between the sets 202, the adjustment value 223 may be generated.

Since the modified image 207 should represent the "true" color value of the control reference color set 202, the discrepancy between the modified image 207 and the control reference color set 202 is shown on the display 221. Losing color indicates distortion. Thus, in an embodiment of the present invention, the modified image 207 can be used as a reference color set for determining the color correction 225 when viewed on the display 221. A conversion function (eg, color correction function 225) between the imaged reference color set 202 and the displayed image reference color set 207 is determined. Inconsistencies between these color values indicate that there is distortion in color representation due to the characteristics of the display device 220. As a result, the output of the display device 220 is controlled by the system 200 so that the display processing parameters of the display device 220 do not deviate from the color of the reference color set 202 in the color representation of the display 221. Can be. In other words, the image displayed by the display device 220 matches the desired "true" color set 202. How much the display actually matches will depend on the gamut of the display device, that is, the ability to accurately render the desired color.

Note that the configuration of the system 200 in FIG. 2C is exemplary and that other components of the configuration are possible in accordance with embodiments of the present invention. As described above, the color correction component 204, the application unit 205, and the data storage device 208 may be implemented as separate color correction systems, or may be implemented as a network of communicatively connected components. It may be. In an embodiment of the present invention, the functions of the color correction component 204, the application unit 205, and the data storage device 208 may be performed as a service by a third service provider, or a provider of the network 209. Can be. Alternatively, the color correction component 204, the application unit 205, and the data storage device 208 may be implemented as components of the image capture device 201 or the display device 220. This process may be done once as an adjustment step of the display device 220 such that the final display of the modified image 207 on the display 221 is within the tolerance range of the "true" control reference color set 203 '. Note that it may be done as a repetition or feedback cycle to constantly adjust the color control of the display device 220 or as an adjustment to the accessed color representation of the image 202.

In the embodiment of the invention shown in FIGS. 2A, 2B, and 2C, feedback from the analysis of the image 206 can be used to adjust internal sensor and actuator settings. This allows the image capture device 201 to have its register settings (e.g. gain, exposure amount, luminance, black level and dark level, saturation, contrast, for example, so that the final capture of the image best represents the true color value). Test, etc.) can be optimized. Similarly, the control of display device 220 may be adjusted to optimize the output of its display 221 or the displayed colors may be converted to effect the system provided with its best display.

3 illustrates an exemplary imaged reference color set 202 used in an embodiment of the invention. Although the description below discloses an area of an imaged reference color set 202 that includes one color or a plurality of colors, it is noted that for simplicity, these colors have been omitted from FIG. 3. In an embodiment of the invention, the imaged reference color set 202 is designed for complete automatic detection by the color correction component 204.

As shown in FIG. 3, the imaged reference color set 202 includes a plurality of color patches (eg, 301-324) with eight color patches arranged in three rows each. The color patches 301 to 324 constitute the reference color 202a described with reference to FIGS. 2A, 2B, and 2C. In the embodiment of the present invention, the color patches 301 to 324 are provided with the black background 330 surrounded by the white border 340 and the black border 350 as the background. In an embodiment of the invention, the color correction component 204 uses a detection algorithm to identify the pattern that matches the pattern created by surrounding the black background 330 with a white border 340. Black border 350 may be used to easily identify white border 340. The embodiment is not limited to this type of pattern, but if any reference pattern arrangement is present in the image 206, if the color correction component 204 can detect it, then the detectable reference pattern arrangement is Note that it can be used. For example, the imaged reference color set 202 may include a background in which the colors represented by the checkerboard patterns, stripes, or color patches 301-324 appear on wallpaper, wall hangings, floor coverings, and the like. In another embodiment, the imaged reference color set 202 may comprise a continuous change of color beyond the desired color range, such as the spectrum or rainbow of colors. Sampling a color from a continuous range may include sampling the entire range of colors, or sampling each region of the continuous range. In addition, although FIG. 3 shows a rectangular array, the color patches 301-324 can be arranged in a circular pattern, a triangle pattern, a rectangular pattern, a square pattern, or the like.

In the embodiment of FIG. 3, color patches 301-324 have two shades of first and second color for general scene tone balance, and gray, black and white for white balance. It includes. The color patches 309 to 324 include sixteen color patches representing a range of color selections. For example, in one embodiment, color patches 309-324 include a range of human skin colors. In an embodiment of the invention, the color depiction of the control reference color set 203 is known to the color correction component 204 such that the imaged reference color set 202 is compared with the characteristics of the reference, ie, light and image capture device. Is used as an unrelated "true" color space. For example, in one embodiment, the spectral reflectance of each color patch (eg, 301-324) is measured and approximated with a digital value encoded with a three component standard of red, green, and blue (RGB). These encoded signal values are compared with the corresponding three component signal values of the control color (eg, 203a) of the control reference color set 203.

As shown in FIG. 3, the imaged reference color set 202 includes a unique identifier 202b. In an embodiment of the present invention, the unique identifier 202b may include symbols, letters, words, patterns, numbers, barcodes, RFID tags, and the like recognizable by the image capture device 201.

By uniquely identifying the reference color set, embodiments of the present invention facilitate identification of the control reference color set 203 having color characteristics corresponding to the color patches 301-324. This is desirable for remotely accessing control reference color data (eg, by the image capture device 201) corresponding to the imaged reference color set 202. Thus, if the image capture device 201, or the display 220 includes a color correction component 204, the control reference color set 203 corresponding to the imaged reference color set 202 is corresponding identifier 203b. Can be identified and downloaded. Similarly, a carrier or service provider can quickly identify color characteristics corresponding to a particular imaged reference color set 202.

4 is a block diagram of a color correction system 400 that provides true color correction in accordance with an embodiment of the present invention. In an embodiment of the present invention, the color correction component 204 includes a first accessor 401 for accessing the imaged reference color set and a second accessor 402 for accessing the control reference color set 203. Include. In an embodiment of the present invention, one access may be operated that accesses both the color correction component 204 and the control reference color set 203. In the embodiment of FIG. 4, the color correction system 400 is coupled to the first accessor 401 and the second accessor 402 to generate a function generation component 403 that generates a color correction function (eg, 210). It includes more. In an embodiment of the invention, the first accessor 401, the second accessor 402, the input 404, the output 405, and the function generating component 403 are shown in FIGS. 2A, 2B, and 2C. The function of the color correction component 204 described above may be performed. In the embodiment of FIG. 4, the system 400 further includes an application unit 205 for applying the color correction function 210 to the image, and a data storage device 208 for storing data. Note that in the embodiment of the present invention, the application unit 205 may output the modified color values of the pixels of the image 206 rather than the modified image described above. In the embodiment of FIG. 4, the system 400 includes a color adjustment generator 406 for generating adjustment values for at least one color control of the display device, a color adjustment value generator 406, and a display device (FIGS. It further includes a display output unit 407 connected to 220 of Figure 2c.

In an embodiment of the invention, the color correction component 204 automatically detects a target pattern (eg, an imaged reference color set 202). In one exemplary target detection sequence, a monochromatic (eg, luminance only) version of a color image is filtered using, for example, a Laplacian filter. This determines the trajectory (eg, between the color patches 301-324 and the background 330, or between the white border 340 and the black border 350) in which the maximum brightness changes in the image. If we can link the trajectory of the zero-crossing position observed at the Laplacian output, we can connect them to create a set of lung contours. Each lung contour is simplified into a series of linear portions, which can be determined through a continuous bisection operation based on creating a contour from a straight line. "Rectangle candidates" are introduced for these contours so that the individual linear portions of the contour (as described above) have a matching relationship (i.e., opposing) to the projection of the planar rectangle. The sides form four major linear portions that coincide in parallel with each other and the adjacent sides coincide in orthogonal relation to each other. In one embodiment, the location of the first contour “rectangular candidate” with contrast representing the dark exterior (eg black border 350) and the bright interior (eg white border 340) is traced. Later, within the first contour rectangular candidate, the position of the second contour “rectangular candidate” with contrast representing the bright outside (eg, white boundary 340) and the dark inside (eg, black background 330). Is traced.

In an embodiment of the invention, the contour (eg, the edge of the black background 330) is a "straight rectangular candidate" contour with a contrast indicating that the bright interior is set within the dark exterior (eg, a color patch ( 301-324). For example, each of the color patches 301-324 is brighter than the black background 330 where they are located. Mapping the outer two "rectangular candidate" contours (eg, black border 350 and white border 340) to a true rectangle with the correct aspect ratio and relationship based on the values of these contours found from the reference target description. It is determined whether to deform. In this embodiment, even when the inner contour (e.g., the contour of the color patches 301-324) is deformed by the above deformation (based on the value of the contour of the known color patch), it also has the correct aspect ratio and Determine if the locations match. Note that some of the color patches may have contrast values that are difficult to detect in a given image 202. However, in an embodiment of the present invention, if a sufficient number of internal color patches are detected (eg, an appropriate value of “sufficient” may be 90%), it is recognized that a reference target has been detected. In an embodiment of the present invention, the color values detected above and found to be valid are sampled and used as sample values to establish the true-color conversion that the image analysis system 205 performs. When strictly using the measurement of geometric rectangles, the orientation of the imaged reference color set 202 is indeterminate depending on the situation, so the orientation of the imaged reference color set 202 is the arrangement of the color patches 301-324 itself. Can be determined by evaluating In other embodiments, separate markings (eg, geometric patterns, or geometric patterns of color patches 301-324) may be used to reveal the direction of the imaged reference color set 202 through their shape or correlation. have.

In an embodiment of the present invention, the color correction component 204 validates the imaged reference color set 202 upon detection, such that the color patches 301-324 in the imaged reference color set 202 are validated. Ensure fidelity of. For example, if the color patches 301-324 fade or become discolored due to staining, the result of the color correction component 204 sampling the color patch may be distorted. As a result, the calculated value of the color correction function 210 by the color correction component 204 may be inaccurate. Thus, in an embodiment of the invention, the color correction component 204 may verify the validity of the age or version of the imaged reference color set 202. In another embodiment, the unique identifier 202b may be used to measure when the imaged reference color set 202 was created and thus determine whether it is still valid. Alternatively, one or more of the inks used to produce the imaged reference color set 202 can be selected and blurred after a period of time. As a result, a portion of the imaged reference color set 202 is left in a state where the color correction component 204 is unrecognizable, which prevents further calculation of the color correction function from the imaged reference color set 202. In another embodiment, if one or more of the inks are blurred, a message may be displayed to inform the user that the imaged reference color set 202 has expired and a new version will be needed.

In an embodiment of the invention, if it is determined that the imaged reference color set 202 is a valid copy, the color correction component 204 is configured to control the color space and control reference color set 203 of the imaged reference color set 202. The color correction function 210 is determined by calculating the color conversion (also referred to as a "conversion function") of the liver. In one embodiment of the invention, a least-squares calculation is used to derive a color correction function F in the form of a 3x4 matrix, which is derived from the imaged reference color set 204 (e.g., one The measured patch average color M of the color patches 301 to 324 described above is mapped to the corresponding control color value R in the control reference color set 203. In another embodiment, the measured patch average color values can be processed through an inverse gamma function to remove the effects of nonlinear contrast adjustment of the device. The matrix results in a transform function F, which is in fact the sum of the 3x3 color transformation matrix and an additional per-color-component offset. In an embodiment of the present invention, prior to performing least squares estimation, the patch average color with at least one saturated component is excluded and the RGB color component function is inverted for both M and R. In another embodiment, the measured patch average color values can be processed through an inverse gamma function to remove the effects of nonlinear contrast adjustment of the device. A 3x4 matrix can be used to determine the color correction function, however, the invention is not limited to linear algebra to determine this function. In other words, the color correction function 210 can take any form of function.

In an embodiment of the invention, all color patches from the imaged reference color set 202 can be measured and used to determine the color correction function 210. In other embodiments, the color patches can be selectively sampled. For example, in one embodiment, only color patches of the first color, the second color, and the monochrome color (eg, blue, green, red, cyan, magenta, yellow, and gray shades) are used to determine the color correction function 210. do. In addition, embodiments of the present invention may sample white tones from a white boundary 340 and sample black tones from a background 330 or black boundary 350. In another embodiment, to determine the color correction function 210, both black, white and gray tones as well as color patches (eg, color patches 309-324) are sampled. In other embodiments, color patches (eg, Only color patches 309-324 are sampled to determine the color correction function 210. In an embodiment of the invention, the color patches 309-324 are best matched to the color of the subject 211. It may be desirable to provide a reference color set 202. For example, if the subject 211 is a red vehicle, selecting the imaged reference color set 202, wherein the color patches 309-324 are predominantly red tones. In such an embodiment, it may be desirable to sample only the color patches 309-324 to determine the color correction function most suitable for calculating the color of the subject 211. For example, imaging To the reference color set 202 Sampling all the imaged color patches can produce a color correction function 210 that is best suited for correcting the color of the entire image, but this is not necessarily the best suited for correcting the captured color of the subject 211. Thus, when calculating a color correction function suitable for use in calculating the color of the subject 211, it is possible to precisely sample the main color region (e.g., the red tone of the vehicle) rather than extensively sampling the entire color space. Is more important.

Accordingly, color correction component 204 determines color correction function 210 that substantially eliminates inconsistencies between imaged reference color set 202 and control reference color set 203. If the color correction function 411 is F in the form of any function, it can be expressed as follows.

I_R = F (I_C)

Where I_R is the color in the control reference color set 203 and I_C is the corresponding color in the imaged reference color set 202. When the color correction function 210 is applied to the image 206, it attempts to accurately convey the color of the image 206 by compensating the effect of the ambient light condition and the effect of the image capture device 201. Note that the color correction function 210 can only be outlined. For example, the color correction function F does not map each image obtained from the imaged reference color set 202 to the exactly corresponding reference color in the control reference color set 203. Moreover, it will be appreciated that F, when applied to the corresponding color in the imaged reference color set 202, does not have sufficient accuracy to accurately match the reference color in the control reference color set 203. In the present invention, the phrase "substantially remove" means that the color of the subject 211 after F has been applied to the color value 412 of the identified skin pixel (eg, or its color depiction) of the image 206. And the difference between the corrected colors of the subject 211 represented by the modified image 207 is not easily noticeable, or the difference is within the allowable parameter.

5 is a block diagram of an exemplary computer system 500 in which embodiments of the invention may be implemented. In an embodiment of the invention, some of the invention consists of computer-readable instructions and computer-executable instructions, for example, embedded within computer system 500 used as part of a general purpose computer network (not shown). The computer system 500 of FIG. 5 is merely illustrative, and the present invention is directed to a number of different computers, including general purpose computer systems, embedded computer systems, laptop computer systems, portable computer systems, networked computer systems, and standalone computer systems. It will be appreciated that it can operate within the system.

In this embodiment, computer system 500 stores an address / data bus 501 for transferring digital information between various components, a CPU 502 for processing digital information and instructions, and stores this digital information and instructions. Volatile main memory 503 consisting of volatile RAM and a non-volatile ROM 504 that stores information and instructions of a more permanent nature. In addition, computer system 500 may further include a data storage device 505 (eg, magnetic, optical, floppy, or tape drive, etc.) that stores vast amounts of data. Note that the software program for carrying out the present invention may be stored in volatile memory 503, data storage 505, or external storage (not shown).

Devices selectively connected to the computer system 500 include a display device 506 for displaying information to a computer user, an alphanumeric input device 507 (e.g., a keyboard), and data input, selection, update, and the like. There is a cursor control device 508 (e.g., mouse, trackball, light pen, etc.) for input. Computer system 500 may include a mechanism (not shown) for generating an audible signal.

With continued reference to FIG. 5, the optional display device 506 of FIG. 5 may be a liquid crystal device, a cathode ray tube, or other display device suitable for generating graphical images and alpha-numeric characters recognizable by a user. Using the optional cursor control device 508, a computer user can dynamically send two-dimensional movement signals of visible symbols (cursors) on the display screen of the display device 506. Various implementations of the cursor control device 508 are known, including trackballs, mice, touch pads, joysticks, or special keys on an alphanumeric input device 507 that can signal movement or mode displacement in any given direction. have. Alternatively, it will be appreciated that the cursor can be directed and activated through input from the alphanumeric input device 507, using special keys and key sequence commands. Alternatively, the cursor can be directed and activated via input from a number of specially adapted cursor orientation devices.

Computer system 500 may also include input / output (I / O) signal units (interfaces) 509 for interfacing with peripherals 510 (eg, computer network modems, mass storage devices, etc.). Thus, computer system 500 can be coupled to a network, such as a client / server environment, whereby a number of clients (eg, personal computers, workstations, portable computers, minicomputers, terminals) can execute processes to perform desired tasks. Etc.) can be used. In particular, computer system 500 may be coupled to a system that estimates skin color from one captured image.

Claims (10)

An image capture system that delivers the true color of a subject. An image capture device 201, An imaged reference color set 202 including at least one reference color 202a, A control reference color set 203 including at least one control color 203a corresponding to the at least one reference color 202a; A color correction function that accesses the control reference color set 203 and the imaged reference color set 202 to eliminate inconsistencies between the at least one reference color 202a and the at least one control color 203a. A color correction component 204 that generates 210 Image capture system. The method of claim 1, Further comprising an application unit 205 for applying the color correction function 210 to the image 206 to produce a modified image 207. Image capture system. The method of claim 2, The application unit 205 includes the components of the image capture device 201, The color correction component 204 is communicatively connected with the image capture device 201. Image capture system. The method of claim 2, The applicator 205 and the color correction component 204 include components of the image capture device 201. Image capture system. The method of claim 1, The imaged reference color set 202 further includes a unique identifier 202b, The control reference color set 203 corresponds to the imaged reference color set 202 uniquely identified by the unique identifier 202b. Image capture system. The method of claim 1, Further comprising a data storage device 208 for storing the color correction function 210 Image capture system. The method of claim 1, Basically, the apparatus further comprises a display device 220 for generating a display 221 selected from the group consisting of a projected display, a printed display and a digitally generated display. Image capture system. The method of claim 7, wherein The color correction component 204 generates an adjustment value 223 for at least one color control of the display device 220. Image capture system. The method of claim 8, The image capture device 201 captures an image 206 of a physical control reference color set 222 disposed in proximity to the display 221, The display 221 includes the imaged reference color set 202. Image capture system. The method of claim 8, The display 221 delivers a modified image 207 to which the color correction function 210 has been applied. Image capture system.

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