KR20000010958A - Color correction device, color correction method, picture processing device, and picture processing method - Google Patents

Abstract

PURPOSE: A picture processing method and apparatus is provided whereby processing to a high degree of freedom can be executed by a simplified operation CONSTITUTION: The color of plural pixels making up a source video image is corrected by a computer(10), a hard disc device(20) and a picture processing device(30). The computer 10 functions as a parameter setting unit for setting plural parameters for designating the source color and the destination color and a computing unit for computing correction data for color correction from the source color to the destination color using the plural parameters set by the parameter setting unit. The hard disc device 20 stores the source video image and effects color correction in the picture processing device 30 for correcting the color of a pixel corresponding to the source color contained in the source video image to the destination color

Description

Color correction apparatus and color correction method, and image processing apparatus and image processing method

In editing a video material such as a broadcasting station, color temperature, color tone, etc. are adjusted by correcting a signal level of a video signal using a color correction device comprising an image processing device.

The color correction apparatus is configured to perform primary processing and secondary processing, and corrects a signal level of an image signal centered on luminance levels such as white level, black level, gamma correction, etc. by the primary processing. Further, the signal level of the video signal centered on the color consisting of the color vectors is corrected by the secondary processing.

In the editing scene, such a process corrects, for example, a difference in color temperature between editing materials recorded at different times. For this purpose, while checking the processing results at the editing site, it is necessary to set the characteristics of such processing by repeatedly examining the gap between materials, for example.

Such a color correction apparatus includes a hardware configuration created using a gate array or the like, and a software configuration by arithmetic processing. In the broadcasting field where real time processing is requested, a hardware configuration is mainly used.

By the way, in the conventional color correction apparatus, both of the apparatuses by the software configuration and the hardware configuration can be set as the processing target (the source vector, generally red, green, blue, yellow, cyan, magenta, etc.). magenta) and its number are limited, and fine color adjustment is limited by that amount. Moreover, adjustment of characteristics such as the range to be corrected and the degree of correction has been limited for such a source vector.

For this reason, the conventional color correction apparatus has the drawback that a process with high degree of freedom cannot be performed.

As one method of solving this problem, it is conceivable to correct the signal level of the video signal by a hardware configuration using a lookup table, and to change the contents of the lookup table in various ways according to the operator's settings. That is, when the signal level of the video signal is corrected by using the lookup table in this way, the desired color can be set in the source vector according to the setting of the lookup table, and the number of source vectors, the range of correction, etc. can be set in various ways. It is thought that processing with high degree of freedom can be performed by this.

However, if the processing with high degree of freedom can be executed in this way, it is difficult for the operator to accurately grasp the degree of processing and the like, and the operation may be cumbersome.

The present invention relates to a color correction apparatus and a color correction method, and an image processing apparatus and an image processing method used in the editing scene of an image material.

1 is a block diagram showing an overall configuration of an editing apparatus to which the present invention is applied.

Fig. 2 is a block diagram showing a specific configuration of a primary processing unit of the image processing apparatus in the editing apparatus.

3 (A) and 3 (B) are schematic diagrams for explaining the setting of the primary processing unit.

4 is a photograph showing an example of a source video image subjected to primary processing by the primary processing unit.

FIG. 5 is a photograph showing a result of primary processing by the primary processor by setting a gamma value of 2.51 for the source video image shown in FIG. 4; FIG.

FIG. 6 is a photograph showing a result of primary processing by the primary processor by setting the gamma value to 0.79 for the source video image shown in FIG. 4; FIG.

FIG. 7 is a photograph showing a result of primary processing by the primary processor by setting a gamma value of 0.32 for the source video image shown in FIG. 4; FIG.

FIG. 8 is a photograph showing a result of primary processing by the primary processor by setting a white level to 127 gradations for the source video image shown in FIG. 4; FIG.

FIG. 9 is a photograph showing a result of primary processing by the primary processor by setting the black level to 127 gradations for the source video image shown in FIG. 4; FIG.

FIG. 10 is a photograph showing a result of primary processing by the primary processor by setting the white level and the black level to 0 gray scale and 255 gray scale for the source video image shown in FIG. 4; FIG.

FIG. 11 is a photo showing the results of primary processing by the primary processing unit by setting the white level and the black level to zero gradation only for red color data with respect to the source video image shown in FIG. 4; FIG.

Fig. 12 is a block diagram showing the specific configuration of the secondary processing unit of the image processing apparatus in the editing apparatus.

13A and 13B are characteristic curve diagrams for explaining the weighting function in the secondary processing by the secondary processing unit.

14A and 14B are schematic diagrams showing the relationship between the weighting function and the correction amount in the secondary processing.

Fig. 15 is a photo showing an example of a source video image subjected to secondary processing by the secondary processing unit.

16 shows a saturation 71 and a color 115 ° (luminance level 107 gradations) as a source vector for the source video image shown in FIG. 15, and sets the color 87 degrees as a destination vector. Photo showing the result of car treatment.

FIG. 17 is a photo showing the results of secondary processing by the secondary processing unit by setting the color 308 ° to the destination vector for the source video image shown in FIG. 15. FIG.

FIG. 18 is a photograph showing a result of secondary processing by the secondary processor by setting a color of 222 ° to a destination vector for the source video image shown in FIG. 15; FIG.

Fig. 19 is a block diagram showing another specific configuration example of the secondary processing unit of the image processing apparatus in the editing apparatus.

20A and 20B are characteristic curve diagrams for explaining the weighting function in the secondary processing by the secondary processing unit shown in FIG. 19;

Fig. 21 is a view for explaining the resolution in the secondary processing.

FIG. 22 is a photograph showing an example of a source video image subjected to secondary processing by the secondary processing unit shown in FIG. 19; FIG.

FIG. 23 is a secondary processing unit shown in FIG. 19 by assigning a saturation degree 71 and a color 115 ° (luminance level 107 gradation) to a source vector for the source video image shown in FIG. 19, and setting the color 87 degrees to a destination vector. Photograph which shows the result of secondary processing by the.

FIG. 24 is a photo showing the results of secondary processing by the secondary processing unit shown in FIG. 19 with the color 308 ° set to the destination vector for the source video image shown in FIG. 19; FIG.

FIG. 25 is a photo showing the results of secondary processing by the secondary processing unit shown in FIG. 19 with the color 222 ° set to the destination vector for the source video image shown in FIG. 19; FIG.

FIG. 26 is a photo showing another example of a source video image subjected to secondary processing by the secondary processing unit shown in FIG. 19; FIG.

FIG. 27 is a photo showing the results of secondary processing by the secondary processing unit shown in FIG. 19, specifying red as the source vector, green as the destination vector, for the source video image shown in FIG.

FIG. 28 shows that the source video image shown in FIG. 26 is assigned red to the source vector, green to the destination vector, green to the source vector, and red to the destination vector. The photograph which shows the result of secondary processing by the secondary processing part shown in 19.

FIG. 29 is a view of the source video image shown in FIG. 26 by assigning red, green, and blue to the source vector, and setting the green, red, and yellow colors to the destination vector; Photo which shows the result of processing.

30 is a photograph showing another example of a source video image subjected to secondary processing by the secondary processing unit shown in FIG. 19;

FIG. 31 is a photo showing the results of secondary processing on the source video image shown in FIG. 30 by emphasizing the saturation of blue, yellow, and red components by the secondary processing unit shown in FIG. 19;

FIG. 32 is a photograph showing a result of secondary processing by reducing the yellow component under the above conditions by the secondary processing unit shown in FIG. 19 with respect to the source video image shown in FIG. 30; FIG.

33 is a block diagram showing another specific configuration example of the secondary processing unit of the image processing apparatus in the editing apparatus;

FIG. 34 is a photograph showing an example of a source video image subjected to secondary processing by the secondary processing unit shown in FIG. 33;

FIG. 35 shows the secondary video processing unit shown in FIG. 33 by assigning saturation 71 and color 115 degrees (luminance level 107 gradation) to the source vector, and setting the color 87 degrees to the destination vector for the source video image shown in FIG. Photograph which shows the result of secondary processing by the.

FIG. 36 is a photo showing the results of secondary processing by the secondary processing unit shown in FIG. 33 by setting the color 308 ° to the destination vector for the source video image shown in FIG. 34; FIG.

FIG. 37 is a photo showing the results of secondary processing by the secondary processing unit shown in FIG. 33 by setting the color 222 ° to the destination vector for the source video image shown in FIG. 34; FIG.

FIG. 38 is a view for explaining the correction of color by the secondary processing unit shown in FIG. 19; FIG.

FIG. 39 is a view for explaining the correction of color by the secondary processing unit shown in FIG. 33; FIG.

Fig. 40 is a photo showing an actual example of the condition setting screen for secondary processing displayed on the screen of the monitor apparatus in the editing apparatus.

Fig. 41 is a diagram schematically showing a condition setting screen of the secondary processing.

Fig. 42 is a diagram schematically showing a vector selection unit and a system setting unit together with part of a vector parameter setting unit in the condition setting screen of the secondary processing.

Fig. 43 is a diagram schematically showing a vector parameter setting unit of the condition setting screen of the secondary processing.

Fig. 44 is a diagram schematically showing a relationship between a control bar and a color correction processing of the condition setting screen of the secondary processing.

Fig. 45 is a view for explaining the setting of the weighting function on the condition setting screen of the secondary processing.

Fig. 46 is a diagram showing in detail a vector scope unit of the condition setting screen of the secondary processing;

Fig. 47 is a view for explaining the color space.

Fig. 48 shows the relationship between the reference color of the color bar and the uv plane;

Fig. 49 is a flowchart showing a procedure of creating a color distribution image.

Fig. 50 is a view for explaining the operation of the source vector in the vector scope unit.

Fig. 51 is a view for explaining the operation of the range of the weighting function in the vector scope unit.

Fig. 52 is a view for explaining the operation of the target vector in the vector scope unit.

Fig. 53 is a flowchart showing an operation procedure in the editing apparatus.

Accordingly, the present invention has been made in view of the above-described conventional situation, and an object of the present invention is to provide an image processing apparatus and an image processing method capable of performing a high degree of freedom processing with a simple operation.

Further, another object of the present invention is to provide a color correction apparatus and a color correction method that allows color correction by specifying a color range.

Further, another object of the present invention is to provide a color correction device and a color correction method that allow color correction by designating a plurality of colors. The present invention provides a color correction apparatus for correcting colors of a plurality of pixels constituting a source video image, comprising: parameter setting means for setting a plurality of parameters for designating a source color and a destination color, and set by the parameter setting means; Calculation means for calculating correction data for color correction from the source color to the destination color using a plurality of parameters, storage means for storing correction data calculated by the calculation means, and storage in the storage means. And color correction means for correcting the color of the pixel corresponding to the source color included in the source video image to the destination color using the corrected correction data.

In the color correction apparatus according to the present invention, for example, the calculation performed by the calculating means is performed by a software program, and the processing performed by the color correction means is performed by hardware.

Further, in the color correction device according to the present invention, the storage means is, for example, a lookup table for storing the color of the pixel and the correction data in association with each other. In the color correction apparatus according to the present invention, the source color and the destination color are represented by, for example, a vector on a color space.

Further, in the color correction apparatus according to the present invention, the parameter setting means includes means for setting, for example, parameters relating to color angle and saturation as parameters relating to the source color and the destination color, respectively. .

Further, in the color correction apparatus according to the present invention, the parameter setting means further includes, for example, gain setting means for setting a parameter relating to a gain inch of the correction data, wherein the calculating means The correction data is calculated using the parameters relating to the color angle and the saturation set by the parameter setting means as parameters of the source color and the destination color and the parameters relating to the gain inch set by the gain setting means.

Further, in the color correction apparatus according to the present invention, the parameter setting means further includes, for example, color range setting means for setting a parameter relating to a color range of the source color, wherein the calculation means further comprises: the source; When the color included in the video image is within the color range set by the color range setting means, the data representing the color of the pixel, the parameter set means as the parameters of the source color and the destination color by the parameter setting means. The correction data is calculated using a parameter relating to the color angle and the saturation degree, and a parameter relating to the gain inch set by the gain setting means.

In addition, the present invention provides a color correction apparatus for correcting a plurality of pixel colors constituting a source video image, comprising: parameter setting means for setting a plurality of parameters for defining a source color range and a destination color range in a color space; Calculating means for calculating correction data for correcting a color included in the source color range to a color included in the destination color range, using a plurality of parameters set by the parameter setting means, and the source video image; When the color of the constituting pixel is a color included in the source color range, the color for correcting the color of the pixel to a color corresponding to the destination color range based on the correction data calculated by the calculating means. A correction means is provided.

In the color correction apparatus according to the present invention, for example, the color direction of the source color range is defined by the source vector on the color space, and the color direction of the destination color range is defined by the destination vector on the color space. .

Further, in the color correction apparatus according to the present invention, the parameter setting means includes, for example, at least a parameter relating to a source color direction, a source color range, and a source saturation as a plurality of parameters for defining the source color range. Means for setting and a plurality of parameters for defining the destination color range, and means for setting at least a parameter relating to the destination color direction and the destination saturation.

Further, in the color correction apparatus according to the present invention, the parameter setting means further includes gain setting means for setting a parameter relating to a gain inch of the correction data, for example, and the calculation means sets the parameter. The correction data using the parameters relating to the source color direction, the source color range and the source saturation set by the means, the parameters relating to the destination color direction and the destination saturation, and the parameters relating to the gain inch set by the gain setting means. Calculate

In addition, in the color correction apparatus according to the present invention, the gain setting means, for example, as the color angle to be calculated is closer to the color direction of the color range, the gain inch becomes larger, and the color angle to be calculated. The get inch is set for each color so that the get inch becomes smaller as it moves away from the color direction of the color range.

Further, in the color correction apparatus according to the present invention, the calculation means may, for example, increase the value of the correction data as the color angle to be calculated is closer to the color direction of the color range. The correction data is calculated for each color such that the value of the correction data becomes smaller as the color angle becomes farther from the color direction of the color range.

Further, in the color correction apparatus according to the present invention, the color correction means, for example, as the color angle of the pixel is closer to the source color direction, the color angle of the pixel closer to the destination color direction The pixel is converted into a color having a color angle closer to that of the pixel as the color angle of the pixel is farther from the source color direction.

Further, in the color correcting apparatus according to the present invention, the computing means corresponds to, for example, the color of the pixel corresponding to the source color range while keeping the source saturation constant corresponding to the destination color range. Selectively using a source algorithm for correcting to a color and a destination algorithm for correcting the color of the pixel corresponding to the source color range to a color corresponding to the destination color range while varying the source saturation. Compute the correction data.

Further, the color correction apparatus according to the present invention includes, for example, a computer including the parameter setting means and the calculating means, and an image processing unit including the color correction means. The computer may include, for example, a parameter setting window for interactively setting parameters relating to the source color direction, the source color range, the source saturation, the destination color direction, and the destination saturation; The color correction means is programmed to display on the computer monitor a graphical interface consisting of a video image before color correction processing and a view window for displaying the video image after color correction.

In addition, the present invention is a color correction method for correcting the color of a plurality of pixels constituting a source video image, a plurality of parameters for defining a source color range and a destination color range in a color space, the source color Compensation data for correcting a color included in a range to a color included in the destination color range is calculated, and when the color of a pixel constituting the source video image is a color included in the source color range, the correction is performed. Based on the data, the color of the pixel is corrected to a color corresponding to the destination color range.

In the color correction method according to the present invention, for example, at least a parameter relating to a source color direction, a source color range, and a source saturation is set as a plurality of parameters for defining the source color range. As a plurality of parameters for defining, at least parameters relating to the destination color direction and the destination saturation are set.

Further, in the color correction method according to the present invention, for example, by setting a parameter relating to the gain inch of the correction data, it is possible to determine the source color direction, the source color range, the source saturation, the destination color direction, and the destination saturation. The correction data is calculated using a parameter and a parameter relating to the gain.

Further, in the color correction method according to the present invention, for example, the closer the color angle to be calculated is closer to the color direction of the color range, the larger the inch is, and the color angle to be calculated is the color range of the color range. The gain is set corresponding to each color angle so that the gain inch becomes smaller as it moves away from the color direction.

Further, in the color correction method according to the present invention, for example, the closer the color angle to be calculated is closer to the color direction of the color range, the larger the value of the correction data becomes, and the color angle to be calculated is the color range. The correction data is calculated for each color angle so that the value of the correction data becomes smaller as the distance from the color direction is.

Further, in the color correction method according to the present invention, for example, as the color angle of the pixel is closer to the source color direction, the color of the pixel is converted into a color having a color angle closer to the destination color direction. As the color angle of the pixel moves away from the source color direction, the color of the pixel is converted into a color having a color angle closer to that of the pixel.

Further, in the color correction method according to the present invention, for example, a source for correcting the color of the pixel corresponding to the source color range to a color corresponding to the destination color range while maintaining the source saturation constant. The correction data is selectively calculated using an algorithm and a destination algorithm for correcting the color of the pixel corresponding to the source color range to the color corresponding to the destination color range while varying the source saturation.

In addition, the present invention is a color correction device for correcting the color of a plurality of pixels constituting a source video image, the first to Nth source vector and the first to Nth source vector in the color space Parameter setting means for setting a parameter for each of the first to Nth destination vectors respectively corresponding to, and for correcting the color represented by the first source vector to the color represented by the first destination vector. Based on the plurality of correction data from the first correction data to the Nth correction data for correcting the color represented by the Nth source vector to the color represented by the Nth destination vector, the comprehensive correction data is obtained. The computing means for calculating and the color of the pixels constituting the source video image are selected from the first to Nth source vectors. And a color correction means for correcting the color of the pixel to the color of the destination vector corresponding to the source vector, based on the comprehensive correction data calculated by the calculation means in the case of the color on any one of the source vectors. It is characterized by.

In the color correction apparatus according to the present invention, the parameter setting means includes, for example, a parameter relating to first to Nth color windows for indicating the color range of the source vector, and the first to Nth parameters. The apparatus further includes means for setting parameters relating to gain values of correction data corresponding to the first to Nth source vectors, respectively.

Further, in the color correction apparatus according to the present invention, the calculating means may be, for example, the first to Nth source vectors, the first to Nth destination vectors, and the first to Nth colors. The comprehensive correction data is calculated based on a window and a parameter relating to a gain inch of the first to Nth correction data. Further, in the color correction apparatus according to the present invention, the parameter setting means includes, for example, the closer the color angle to the calculation vector to the source vector, the larger the gain inch, and the color angle to be calculated. The parameter about the gain inch is set for each color angle so that the gain inch becomes smaller as it moves away from the vector.

Further, in the color correction apparatus according to the present invention, the calculation means includes, for example, as the color angle to be calculated is closer to the source vector, the value of each correction data increases, and the color angle to be calculated is increased. Compensation data according to a distance from the source vector is calculated so that the value of each of the correction data becomes smaller as the distance from the source vector decreases.

Further, in the color correction device according to the present invention, the color correction means has a color angle closer to the color of the pixel by the destination vector, for example, as the color angle of the pixel is closer to the source vector. The color of the pixel is converted to a color having a color angle closer to that of the pixel as the color angle of the pixel is farther from the source vector.

Further, in the color correction apparatus according to the present invention, the calculating means corresponds to, for example, the color of the pixel corresponding to the first color range while keeping the source vector constant. And a first algorithm for correcting to a color to perform, and a second algorithm for correcting a color of the pixel corresponding to the first color range to a color corresponding to the second color range while changing the source vector. To calculate the correction data.

Further, the color correction apparatus according to the present invention includes, for example, a computer including the parameter setting means and the calculating means, and an image processing unit including the color correction means. The computer may include, for example, a parameter setting window for interactively setting the color range of the source vector and the destination vector, a video image before color correction processing, and color corrected by the color correction means. It is programmed to display on the computer monitor a graphical interface consisting of a view window that displays a later video image.

In addition, the present invention is a color correction method for correcting the color of a plurality of pixels constituting a source video image, the first to N-th source vector, and each of the first to N-th source vector in the color space From the first correction data for setting a parameter relating to the first to Nth destination vector corresponding to and correcting the color represented by the first source vector to the color represented by the first destination vector, Calculating comprehensive correction data based on a plurality of correction data up to an Nth correction data for correcting the color indicated by the Nth source vector with the color indicated by the Nth destination vector, wherein the source video is calculated. When the color of the pixels constituting the image is a color on any one of the first to Nth source vectors, And correcting the color of the pixel to the color of the destination vector corresponding to the source vector based on the calculated comprehensive correction data.

In the color correction method according to the present invention, for example, a parameter relating to first to Nth color windows for indicating a color range of the source vector, and to a gain inch of the first to Nth correction data. The parameters are set in correspondence with the first to Nth source vectors, respectively.

Further, in the color correction method according to the present invention, for example, the first to Nth source vectors, the first to Nth destination vectors, the first to Nth color windows, and the first to The comprehensive correction data is calculated based on a parameter relating to a gain inch of the Nth correction data.

Further, in the color correction method according to the present invention, for example, the closer the color angle to be calculated is closer to the source vector, the larger the inch is, and the farther the color angle to be calculated from the source vector is, the higher the color is. In order to make the inches smaller, the parameters relating to the gain inches are set for each color angle.

Further, in the color correction method according to the present invention, for example, as the color angle to be calculated becomes closer to the source spectrum, the value of each of the correction data becomes larger, and the color angle to be calculated becomes farther from the source vector. Compensation data according to the distance to the source vector is calculated so that the value of each correction data becomes smaller.

Further, in the color correction method according to the present invention, for example, as the color angle of the pixel is closer to the source vector, the color of the pixel is converted into a color having a color angle close to the destination vector, and the pixel The farther the color angle of the is from the source vector, the more the color of the pixel is converted into a color having a color angle closer to that of the pixel.

Further, in the color correction method according to the present invention, for example, for correcting the color of the pixel corresponding to the first color range to the color corresponding to the second color range while keeping the source vector constant. Selectively correcting the correction data using a first algorithm and a second algorithm for correcting a color of the pixel corresponding to the first color range to a color corresponding to the second color range while changing the source vector. Calculate

In addition, the present invention is a color correction device for correcting the color of a plurality of pixels constituting a source video image, a plurality of destination vectors corresponding to each of the plurality of source vectors and the plurality of source vectors in the color space Means for calculating vector correction means, a comprehensive correction data for correcting the colors on the plurality of source vectors with the colors of a plurality of destination vectors corresponding to each of the plurality of source vectors, and the source video image. When the color of the pixel constituting the pixel is a color on the source vector of any of the plurality of source vectors, the color of the pixel is set to the color of the destination vector corresponding to the source vector based on the comprehensive correction data. It is characterized by comprising a color correction means for correcting.

The image processing apparatus according to the present invention further includes data correction means for correcting and outputting input data by the lookup table, and table updating means for updating the contents of the lookup table. The table holds data corresponding to the color difference signal of the video signal.

In the image processing apparatus according to the present invention, the data correction means includes, for example, polar coordinate conversion means for converting the color difference signal into polar coordinates and generating angle data corresponding to the color difference signal with reference to a predetermined reference axis. The lookup table outputs the data held by the angle data as an address.

In the image processing apparatus according to the present invention, the polar coordinate converting means outputs the angular data by, for example, the number of bits larger than the color difference signal. Further, in the image processing apparatus according to the present invention, the look-up table is, for example, the data of the color of the video signal as an address, and outputs correction data for correcting the video signal. And polar coordinate conversion means for polarizing the color difference signal to output color data of the color difference signal to the lookup table, and arithmetic processing means for correcting the color difference signal by the correction data.

Further, in the image processing apparatus according to the present invention, the lookup table, for example, addresses data of the color of the video signal, outputs correction data for correcting the color and saturation of the video signal, and corrects the data. The means includes polar coordinate conversion means for polarizing the white signal and outputting color data of the color difference signal to the lookup table, and arithmetic processing means for correcting the color difference signal by the correction data.

Further, in the image processing apparatus according to the present invention, the look-up table outputs correction data for correcting, for example, addressing the data of the color of the video signal, the brightness and the color of the video signal, and correcting the data. The means includes polar coordinate conversion means for polarizing the color difference signal to output color data of the color difference signal to the lookup table, and arithmetic processing means for correcting the color difference signal by the correction data.

Further, in the image processing apparatus according to the present invention, the table updating means includes, for example, input means for inputting at least a color of a processing target and a color of a processing target, and data for generating data to be stored in the lookup table. And a generating means, wherein said data generating means adds to said lookup table to correct the color of said processing target in said video signal to the color of said processing target, based on the color of said processing target and the color of said processing target. Create data to store.

Further, in the image processing apparatus according to the present invention, the table updating means includes, for example, input means for inputting at least the color and saturation degree of the processing target, and the color and saturation degree of the processing target, and storing in the lookup table. And a data generating means for generating data, wherein the data generating means includes the color and saturation of the processing target, and the color and saturation of the processing target, based on the color and the saturation of the processing target. And generating data to be stored in the lookup table so as to correct the saturation to the color and saturation of the processing target.

Further, in the image processing apparatus according to the present invention, the table updating means includes, for example, input means for inputting at least a range of a processing target, and data generating means for generating data to be stored in the lookup table, The data generating means weights a correction value by a weighting function held at a valid value in the range of the processing target, and generates data to be stored in the lookup table so as to correct the color of the processing target to the target color. .

Further, in the image processing apparatus according to the present invention, the table updating means includes, for example, input means for inputting at least the degree of processing, and data generating means for generating data to be stored in the lookup table. The data generating means weights the correction value by a predetermined function, and generates data to be stored in the lookup table so as to correct the color of the processing target to the color of the processing target.

Further, in the image processing apparatus according to the present invention, the table updating means generates, for example, input means for inputting a plurality of sets of at least a color of a processing target and a color of a processing target, and data to be stored in the lookup table. And data generating means for generating correction data so as to correct the color of the processing target with the color of the processing target, for each set of the color of the processing target and the color of the processing target. The data for correction of the set is aggregated to generate data stored in the lookup table.

The image processing apparatus according to the present invention further includes a first lookup table, first data correcting means for correcting and outputting input data by the first lookup table, and a second lookup table. Second data correction means for correcting and outputting the input data by means of the second data correction means, and table updating means for updating contents of the first and second lookup tables, wherein the first lookup table corresponds to a luminance level of an image signal. The second lookup table holds data corresponding to a color difference signal of an image signal.

In addition, the present invention provides an image processing apparatus for correcting a color of an image to be processed, wherein a predetermined correction value is weighted by a weighting function held at a valid value in a range based on a predetermined reference color, thereby processing the image to be processed. Color correction means for correcting the color of each pixel in the target color of the processing target, image display means for displaying a color distribution image formed by projecting the pixels of the processing target image appearing in the three-dimensional color space onto an uv plane; And updating processing means for changing a condition for correcting the color by designation on a color distribution image.

In the image processing apparatus according to the present invention, the updating processing means displays, for example, the range of correction by the weighting function as the color distribution image, and by specifying on the color distribution image, By changing the range of correction, the conditions for correcting the color are changed.

Further, in the image processing apparatus according to the present invention, the updating processing means accepts, for example, the specification of a pixel on the processing target image, and distributes the marker to a place corresponding to the received pixel. Display on the image.

Further, in the image processing apparatus according to the present invention, the update processing means displays the reference color on the color distribution image, for example, and designates the reference color by designation on the color distribution image. By changing, the condition for correcting the color is changed.

Further, in the image processing apparatus according to the present invention, the update processing means receives a designation of a pixel on the image to be processed, for example, and a place corresponding to the received pixel in the color distribution image. Mark the markers.

Further, in the image processing apparatus according to the present invention, the update processing means displays, for example, a color of a correction target corresponding to the reference color on the color distribution image, and designates it on the color distribution image. By changing the color of the correction target, the correction amount is changed, and the condition for correcting the color is changed.

Further, in the image processing apparatus according to the present invention, the updating processing means accepts, for example, the specification of a pixel on the processing target image, and distributes the marker to a place corresponding to the received pixel. It is displayed on an image display.

In addition, the present invention is an image processing method for correcting the color of an image to be processed, wherein a predetermined correction value is weighted by a weighting function held at a valid value in a range based on a predetermined reference color, thereby processing the image to be processed. A color distribution image formed by correcting the color of each pixel of the pixel to the color of the processing target, projecting the pixels of the processing target image appearing in the three-dimensional color space onto the uv plane, and designating on the color distribution image. By changing the conditions for correcting the color.

In the image processing method according to the present invention, for example, the range of correction by the weighting function is displayed on the color distribution image, and the range of the correction is changed by designation on the color distribution image, The condition for correcting the color is changed.

In addition, in the image processing method according to the present invention, for example, designation of a pixel is accepted on the processing target image, and a marker is displayed at a place corresponding to the received pixel in the color distribution image.

In the image processing method according to the present invention, for example, the reference color is displayed on the color distribution image, and the reference color is changed by designation on the color distribution image to correct the color. Change the condition.

In addition, in the image processing method according to the present invention, for example, designation of a pixel is accepted on the processing target image, and a marker is displayed at a place corresponding to the received pixel in the color distribution image.

Further, in the image processing method according to the present invention, for example, the color of the correction target corresponding to the reference color is displayed on the color distribution image, and the designation of the correction target is performed by designation on the color distribution image. The color is changed to change the correction to change the condition for correcting the color.

In addition, in the image processing method according to the present invention, for example, designation of pixels is accepted on the processing target image, and a marker is displayed at a place corresponding to the received pixel in the color distribution image.

EMBODIMENT OF THE INVENTION Hereinafter, the best form for implementing this invention is demonstrated in detail with reference to drawings.

The present invention is applied to the editing apparatus 100 having a structure as shown in FIG. 1, for example. The editing apparatus 100 shown in FIG. 1 edits video signals based on the serial digital interface (SDI) of the SMPTE259M specification, and includes a computer 10 and a hard disk device (connected via a local bus). 20 and the image processing apparatus 30.

The computer 10 functions as a system controller for controlling the entire editing apparatus 100, and includes a central processing unit (CPU) 11 and a random access memory (RAM) 12 connected via an internal bus BUS _INT . ), A read-only memory (ROM) 13 or a monitor device 14. In addition, the keyboard 16 and the mouse 17 are connected to the internal bus BUS _INT of the computer 10 via the interface (1 / F) 15.

In addition, the hard disk device 20 is for temporarily storing a video signal conforming to the serial digital interface (SDI) of the SMPTE259M specification edited by the editing device 100, and a control command is executed via the local bus BUS. A given disk unit controller 21 and a hard disk array 22 controlled by the disk unit controller 21 are provided. The hard disk device 20 can store input signals of two channels in the hard disk array 22 and output signals read from the hard disk array 22 in three channels. A source video signal which is a video material for editing and an image processed video signal output from the image processing apparatus 30 are input as an input signal of the input signal. The hard disk device 20 accumulates the source video signal and the processed video signal output from the image processing apparatus 30 in the hard disk array 22 and is provided through the local bus BUS. The hard disk array 22 is controlled by the disk unit controller 21 according to a control command, and three video signals are output from the hard disk array 22.

The image processing apparatus 30 is for performing special image effect processing or color correction processing on the video signal edited by the editing apparatus 100, and is an image to which a control command is given via the local bus. The processing unit controller 31, the cross point switch 32 controlled by the image processing unit controller 31, the special effect processing unit 33, the mixer unit 34, the color collector unit 35, and the like.

In this image processing apparatus 30, the cross point switch 32 is a matrix switch having at least six channel input lines and seven channel output lines, and has three channels of output from the hard disk device 20. A six-channel video signal composed of a video signal, two channel video signals output from the mixer section 34, and one channel video signal output from the color collector section 35 are inputted as six input channels. To be supplied to the line. In addition, the output line of the cross point switch 32 is an output line of the monitor video signal, one channel is the output line of the video signal after the two channels, the output line to the special effect processor 33, One channel is assigned as an output line to the color collector portion. The output line of the monitor video signal is connected to the image processing unit controller 31. As a result, the image processing unit controller 31 supplies the monitor video signal from the output line to the monitor device 14 of the computer 10 via the bus BUS. The output line of the two-channel image processing finished video signal is used as an output line for supplying the edited video signal to a recording device in a later stage (not shown) of one channel output line, and output of another one channel. A line is connected to the hard disk device 20. As a result, the image processing apparatus 30 supplies the image processing finished image signal to the hard disk apparatus 20 through the output line. In addition, the three-channel video signal is supplied to the special effect processor 33 through the three-channel output line to the special effect processor 33. In addition, one color video signal is supplied to the color collector unit 35 through one channel output line to the color collector unit 35.

In addition, the special effect processing unit 33 performs a special effect on the video signal of the three channels supplied through the cross point switch 32, and the cross point of the special signal processed image signal from the mixer unit 34. It is supplied to the input line of the switch 32.

The color collector unit 35 further includes a demultiplexer (DEMUX) 36 to which an image signal conforming to the serial digital interface (SDI) of the SMPTE259M specification is input through the cross point switch 32, and the demultiplexer (DEMUX). A primary processing unit 37 to which the output signal of 36 is supplied, a secondary processing unit 38 to which the output signal of the primary processing unit 37 is supplied, and an output signal of the secondary processing unit 38 is supplied. It consists of a multiplexer (MUX) 39.

In the color collector unit 35, the demultiplexer 36 outputs a video signal conforming to the serial digital interface (SDI) of the SMPTE259M specification inputted through the cross point switch 32 to luminance data (Y) and color difference data. Convert to (U, V). In addition, the primary processing unit 37 is a video signal centered on luminance levels such as white level, black level, gamma correction, and the like in luminance data Y and color difference data U and V obtained by the demultiplexer 36. A process for correcting the signal level is performed. Further, the secondary processor 38 corrects the signal level of the image signal centered on the color in the luminance data Y and the color difference data U and V, which are processed by the primary processor 37. Implement treatment. In addition, the multiplexer 39 displays the luminance data Y and the color difference data U and V processed by the primary processing unit 37 and the secondary processing unit 38 in a serial digital interface (SMPTE259M specification). The image signal is converted into an SDI-compliant video signal and output.

As shown in FIG. 2, the primary processing unit 37 has the oversampling circuits 41U and 41V, the first matrix circuit 42, and a look up table (LUT) 43E and 43G. , 43B) and the second matrix circuit 44.

In the primary processing unit 37, the oversampling circuits 41U and 41V oversample the color difference data U and V obtained by the demultiplexer 36 at the sampling frequency of the luminance data Y. The color difference data U and V are supplied to the first matrix circuit 42 in synchronization with the luminance data Y. FIG.

In addition, the first matrix circuit 42 directly inputs luminance data Y obtained by the demultiplexer 36 and synchronizes the luminance data Y via the oversampling circuits 41U and 41V. Color difference data U and V are input. The first matrix circuit 42 performs a matrix operation on the synchronized luminance data Y and the color difference data U and V, whereby the luminance data Y and the color difference data U and V are obtained. Is converted into red, green and blue color data (R, G, B).

In addition, the lookup tables 43R, 43G, 43B have previously outputted data of the output signal level for each signal level calculated by the central processing unit 11 of the computer 10 via the bus. It is formed by accumulating this data, supplied to the image processing unit controller 31, and the color data R, G, of the signal level corresponding to the address of the signal level of the color data R, G, and B, respectively. Output B). The lookup tables 43R, 43G, and 43B are provided with respect to the color data R, G, and B sequentially output from the first matrix circuit 42.

OUT = ((WL-BL) x IN) ^{1 / γ} + BL

The arithmetic processing is performed to correct and output the signal levels of these color data (R, G, B) by the characteristic curve set by the operator in advance.

In formula (1), IN is an input level, OUT is an output level with respect to the input level IN, IN is input data, BL is a black level, WL is a white level, and gamma is a gamma correction value.

The second matrix circuit 44 performs matrix calculation on the color data R, G, and B output from the look-up tables 43R, 43G, and 43B, thereby performing these color data (R, G, B). Is converted into luminance data Y and color difference data U and V and output.

Here, the central processing unit (CPU) 11 installed in the computer 10 secures a work area in a random access memory (EAM) 13, in response to an operation of the keyboard 16 or the mouse 17. The operation of this editing apparatus 100 is controlled by executing a series of processing procedures stored in a read-only memory (ROM) 12 or a hard disk device (not shown).

In this control, if an operator specifies processing to use the color collector unit 35 of the image processing apparatus 30, the central processing unit 11 sends a control command to the image of the image processing apparatus 30. It transfers to the processing unit controller 31, and produces | generates the said color collector part 35 operation | movement. If the operator instructs the setting of the processing condition in this state, the central processing unit 11 accepts the processing condition and executes the parameter setting processing of the color collector unit 35 in accordance with the received condition. .

At this time, the central processing unit 11 accepts the setting of processing conditions by the GUI (Graphical User Interface) displayed on the monitor device 14. That is, when the menu of setting conditions relating to the white level, the black level, and the gamma correction is selected during the first processing, the central processing unit 11 displays the red, blue, and green color signals as shown in Fig. 3A. For this, the characteristic curve L1 indicating the relationship between the input signal level IN and the output signal level OUT is displayed. In FIG. 3A, the characteristic curve is shown only for the color signal of 1, and description of other color signals is omitted.

The central processing unit 11 also displays a plurality of points P0, P1 ... at predetermined intervals on the characteristic curve L1. In this characteristic curve L1, the start point P0 and the end point P4 among the plurality of points P0 and P1 ... represent the black level BL and the white level WL, respectively. The curvature exhibits gamma (γ).

The central processing unit 11 responds to the operator's operation, and the black level BL recorded by the black level BL, the white level WL, the gamma γ of the default value, or written in a predetermined calculation means, By performing the arithmetic processing of the above formula (1) by the white level WL and the gamma γ, the output level OUT for the input level IN is sequentially calculated, and this characteristic curve is used as a result of this calculation. (L1) is displayed.

In this state, when the operator grabs and moves the start point P0 or the end point P4 with the mouse 17, as indicated by the sign A, the coordinate values of the moved start point P0 and the end point P4 are referenced. Then, the arithmetic processing of formula (1) is executed, thereby accepting the change of the black level BL and the white level WL, and at the same time, as indicated by the sign L2, the changed black level BL. ), The characteristic curve is represented by the white level WL. If the operator grabs and moves the intermediate points P1, P2, and P3, the equation (1) is based on the coordinates of the moved point (P1, P2 or P3) and the starting point (P0) and the end point (P4). The arithmetic processing is executed to thereby accept the change in gamma (γ) and display the characteristic curve due to this gamma (γ).

As a result, the central processing unit 11 can set various input / output characteristics in response to an operator's operation. In addition, the central processing unit 11 forms a display screen so that the numerical input can be differently received for the black level BL, the white level WL, and the gamma γ. It is made to change the display of the characteristic curve.

Further, the central processing unit 11 calculates the output signal level sequentially with respect to the acquisition signal level of the video signal by the black level BL or the like thus accepted. At this time, the central processing unit 11 allocates 8 bits of data to the input level IN for each of the red, blue, and green color signals, and sequentially replaces the 8 bits of the input level IN. The arithmetic processing of 1) is executed, whereby the output level OUT is calculated from the 8-bit data corresponding to the input level IN sequentially.

Further, the central processing unit 11 transfers and sets this calculation result to the image processing unit controller 31 of the image processing apparatus 30, and sets the lookup tables 43R, 43G, 43B according to the set input / output characteristics. It is created in the primary processing unit 37. Further, the color collector unit 35 processes the image using the set lookup tables 43R, 43G, and 43B.

In setting the input / output characteristics, the central processing unit 11 forms a window W1 to display this characteristic curve L1 as shown in Fig. 3B, and furthermore, according to the conditions set by the operator. Images before and after the process are displayed by different windows W1 and W2, respectively.

At this time, the central processing unit 11 changes the display of these characteristic curves L2 in response to an operator's operation, and sets the lookup tables 43R, 43G, 43B of the primary processing unit 37, and the like. It is made to repeat, and by this, the mouse 17 is operated, confirming the process result with the monitor apparatus 14, and it becomes possible to change the conditions of a primary process interactively.

The result of primary processing by the primary processing unit 37 of the color collector unit 35 is set to gamma value 2.51 for the source video image of the over-iris tendency as shown in FIG. 4. Fig. 6 shows the results of the primary processing by setting the gamma value at 0.79 and shows the result of the primary processing by setting the gamma value at 0.32. With respect to the source video image shown in Fig. 4, in the primary processing set to the gamma value 2.51, the processing result of the over iris state is obtained. In the primary processing set to the gamma value 0.79, the processing result of the proper iris state is obtained. In addition, as a primary process set to a gamma value of 0.32, a processing result of a low iris state was obtained. In this manner, the primary processing unit 37 of the color collector unit 35 can freely set gamma to obtain a natural processing result.

In addition, FIG. 8 illustrates the result of the first process by setting the white level to 127 gradations for the source video image illustrated in FIG. 4, and the result of the first process by setting the black level to 127 gradations in FIG. 9. 10 shows the results of the first process by setting the white level and the black level to 0 gray and 255 gray levels, and also set the white level and black level to 0 gray only for the red color data. The processing result is shown in FIG. As is clear from Figs. 8 to 10, in the primary processing unit 37 of the color collector unit 35, it is possible to correct the signal level without causing any unsuitable problems such as deterioration of image quality by greatly changing the gray scale. have. As is also apparent from FIG. 11, the red color elimination effect is also obtained in the primary processing unit 37 of the color collector unit 35.

In the editing apparatus 100, the secondary processing unit 38 includes, for example, a coordinate conversion circuit 51, a lookup table 52, and an addition circuit, as shown in a specific configuration example in FIG. The secondary processing unit 50 consisting of (54Y, 54U, 54V) is used.

In this secondary processing unit 50, the coordinate conversion circuit 51 is supplied with color difference data U and V output from the primary processing unit 37. This coordinate conversion circuit 51 is configured to sequentially input color difference data U and V.

θ = arctan (V / U)

The arithmetic processing is performed to convert the respective color difference data U and V into data of the color θ.

In addition, the lookup table 52 includes, in advance, comprehensive correction value data ΣΔY, corresponding to an angle θ (0 ° ≦ θ ≦ 360 °) calculated by the central processing unit 11 of the computer 10. Is a memory for storing ΣΔU and ΣΔV). The lookup table 52 outputs the total correction data (ΣΔY, ΣΔU, ΣΔV) of the corresponding source vector by using the data of the color θ obtained by the coordinate conversion circuit 51 as an address. .

The adder circuits 54Y, 54U, and 54V are arranged in the lookup table 52 in luminance data Y _s and source difference color U _s and V _s of the source color output from the primary processor 37. By adding the comprehensive correction value data ΣΔY, ΣΔU, ΣΔV read out from the above, luminance data Y and color difference data U and V of the destination color are generated.

Here, the principle of the correction processing in the secondary processing unit 50 having the configuration shown in FIG. 12 will be described.

The correction processing in the secondary processing unit 50 is a comprehensive correction value data (ΣΔY, ΣΔU, Σ calculated in response to the color (0 ° ≤θ≤ 360 °) constituting the input signals U and V. The method of adding ΔV to the input signals (Y _s , U _s , V _s ) is adopted, and the relationship between the inputs (Y _s , U _s , V _s ) and the output (Y _d , U _d , V _d ) Is,

Y _d = Y _s + Σ △ Y

U _d = U _s + Σ △ U

V _d = V _s + Σ △ V

Represented as In addition, Y _s , U _s , and V _s are the luminance level and each color difference level of the source vector. In addition, Y _d , U _d , and V _d are the luminance level and each color difference level of the destination vector.

Here, the comprehensive correction data (ΣΔY, ΣΔU, ΣΔV) will be described. The color collector device of the present invention is configured to be able to set not only one source vector, but also any 1 to n source vectors and any n destination vectors respectively corresponding to the n source vectors. Thus, the accumulation of all the correction data (ΔY ₁ to ΔY _n ) of the luminance components corresponding to the first to nth source vectors is defined as the comprehensive correction data (ΣΔY) for the luminance component, and the first Accumulating all the correction data (ΔU ₁ to ΔU _n ) of the color components corresponding to the nth to nth source vectors is defined as the comprehensive correction data (ΣΔU) for this color component, and is applied to the first to nth source vectors. Accumulating all the correction data (ΔV ₁ to ΔV _n ) of the corresponding color components is defined as the comprehensive correction data (ΣΔV) for this color component.

Therefore, the relationship between individual correction data and comprehensive correction data is

△ Y = △ Y ₁ + △ Y ₂ + ... + △ Y _n

△ U = △ U ₁ + △ U ₂ + ·· + △ U _n

ΔV = ΔV ₁ + ΔV ₂ + ... + ΔV _n

Can be represented as:

First, attention is paid to the luminance component Y _{s of} the source vector and the Y _d of the first destination vector corresponding to the source vector in order to obtain comprehensive correction data ΣΔY relating to the luminance component.

Here, among the n vectors set by the operator, the luminance component of the first source vector is Y _s1 , and the first destination vector is Y _d1 . Further, the correction data for correcting the luminance component of the first source vector to the luminance component of the first destination vector is ΔY ₁ , and any weighting function set for this first source vector is K ₁ (θ). In other words, the relationship between Y _s1 , Y _d1 , ΔY _1, and K ₁ (θ) is

△ Y ₁ = K ₁ (θ) × (Y _d1 -Y _s1 )

It can be represented as.

Incidentally, the weighting function K ₁ (θ) will be described later in detail.

As already explained, since the color collector apparatus of the present invention is configured to set n source vectors and destination vectors, it is the same as equation (5) obtained by obtaining correction data (ΔY ₁ ) for the first source vector. Think about all source vectors up to nth and destination vectors,

△ Y ₁ = K ₁ (θ) × (Y _d1 -Y _s1 )

△ Y ₂ = K ₂ (θ) × (Y _d2 -Y _s2 )

△ Y ₃ = K ₃ (θ) × (Y _d3 -Y _s3 )

···

△ Y _n = K _n (θ) × (Y _dn -Y _sn )

It can be seen that the relation

Therefore, when ΔY ₁ to ΔY _1n of Formula (6) are substituted into Formula (4),

Σ △ Y = △ Y ₁ + △ Y ₂ + ·· + △ Y _n

= K ₁ (θ) × (Y _d1 -Y _s1 ) + K ₂ (θ) × (Y _d2 -Y _s2 )

+ ···

+ K _n (θ) × (Y _dn -Y _sn )

It becomes

The color components U _s and V _s of the source vector are obtained in order to obtain the comprehensive correction data (ΣΔU and ΣΔV) for the color components U and V in the same manner as the calculation obtained by the equation (7) with respect to the luminance component. And focusing on the color components U _d and V _d of the destination vector, the same as in Equation (7),

_{Σ △ U = △ U 1 +} △ U 2 ··· + △ U n

= K ₁ (θ) × (U _d1 -U _s1 ) + K ₂ (θ) × (U _d2 -U _s2 )

+ ···

+ Kn (θ) × (U _dn -U _sn )

_{Σ △ V = △ V 1 +} △ V 2 ··· + △ V n

= K ₁ (θ) × (V _d1 -V _s1 )

+ K ₂ (θ) × (V _d2 -V _s2 )

+ ···

+ Kn (θ) × (V _dn -V _sn )

Is established.

The central processing unit 11 performs comprehensive correction data (ΣΔY) every 1 ° with respect to θ having a value of 0 ° to 360 ° based on the equations (7), (8) and (9). , ΣΔU, ΣΔV) are calculated. That is, 360 comprehensive correction data (ΣΔY, ΣΔU, ΣΔV) corresponding to all angles are generated. The calculated total correction data ΣΔY, ΣΔU, ΣΔV are stored in the lookup table 52 so as to be addressed by the respective angles θ.

Next, the weighting function K (θ) mentioned above is demonstrated. This weighting function K ([theta]) is a function for setting the gain of the correction value in each source vector. Since it is a function set for each source vector so as to be equal to the correction data described above, the first to nth weighting functions K ₁ (θ) to K _n (θ) exist.

As the parameters of the weighting function K (θ), color range data W and gain level data G indicating a weighting function range are set. In accordance with the set color gamut data and the gain level, this weighting function K (θ) is determined.

Hereinafter, referring to FIGS. 13A and 13B, the setting of the first weighting function K ₁ (θ) set for the first source vector SV ₁ will be described as an example. Fig. 13B shows the color space by a two-dimensional vector scope. In the example shown in FIG. 13B, the color of the point P _S1 represented by the first source vector SV ₁ is converted into the color of the point P _d1 represented by the first destination vector DV ₁ . It is an example showing that.

As shown in FIG. 13A, the color gamut data [theta] _w is data set such that the color angle [theta] _s1 of the first source vector SV ₁ is centered. A first weighting function K ₁ (θ) is the gain in the hue angle (θ _s1) of the first source vector is "1" hue angle (θ _s1 -θ _w / 2 and θ _s1 + θ _w / 2) This is a function where the gain becomes "0".

That is, this function K ₁ (θ) is in the range of θ _s1 -θ _w / 2≤θ <θs ₁ ,

And, in the range of _{θ s1 ≤θ≤θ s1 + θ w /} 2,

In addition, θ> θ _s1 -θ _w / 2 and θ _s1 + θ _w / 2 <θ

to be.

Next, how to convert the color when this first weighting function is used will be described with reference to Figs. 13A and 13B.

In FIG. 13, the color of the point P _s1 represented by the first source vector SV ₁ is converted into the color of the point P _d1 represented by the first destination vector DV ₁ . data, the color of dots (P _d1 (θ _w), the first source vector (SV ₁₎ point (P _s1), in the vicinity of the inside is converted to a), a in the set color hue range data (θ _w) The color of the point P _s1 ″ away from one source vector SV ₁ is converted into the point P _d1 ″.

The coordinates of each point are

P _s1 (Y _s1 , U _s1 , V _s1 )

P _d1 (Y _s1 + △ Y1 (θ _s ),

U _s1 + △ U1 (θ _s ),

V _s1 + △ V1 (θ _s ))

P _s1 '(Y _s1 ', U _s1 ', V _s1 ')

P _d1 '(Y _s1 ' + K (θ ') × △ Y ₁ (θ _s ),

U _s1 '+ K (θ') × △ U ₁ (θ _s ),

V _s1 '+ K (θ') × △ V ₁ (θ _s ))

P _s1 ”(Y _s1 ”, U _s1 ”, V _s1 ”)

P _d1 ”(Y _s1 ” + K (θ ”) × △ Y ₁ (θ _s ),

U _s1 ”+ K (θ”) × △ U ₁ (θ _s ),

V _s1 ”+ K (θ”) × △ V ₁ (θ _s ))

It can be represented as.

As can be understood from this FIG. 13A, the closer the point P _s1 ′ is to the vicinity of the first source vector SV1, the larger the value of the weighting function K (θ ′). In addition, as can be understood from Equation (14), the point of the conversion destination is obtained by multiplying the weighting function K (θ ') by the correction data ΔY ₁ (θ _s ) from the source vector to the destination vector. The position of (P _d1 ') is determined. That is, as the point P _s1 ′ is closer to the first source vector SV ₁ , that is, the closer θ 'is to θ _s , the point P _d1 ′ at the point of conversion of the point P _s1 ′ before conversion. Is close to the destination vector. As a result, the color can be converted not only for the pixel having the color on the source vector but also for the pixel having the color around the source vector, such as the point P _s1 ′. In addition, the present color collector apparatus uses a weighting function K (θ) with the color angle θ as a function, so that when the color of the point P _s1 ′ close to the source vector is converted, the point P of the conversion destination is _d1 ') is not converted into a color on the destination vector, but becomes a color of the intermediate color between the color on the destination vector and the color of the point P _s1 ' before conversion, so that a more natural color conversion can be realized.

On the other hand, as can be understood from FIG. 13A, the further the point P _s1 ″ is away from the first source vector, the smaller the value of the weighting function K (θ ”). In addition, as can be understood from the above equation (15), the value obtained by multiplying the weighting function K (θ '') by the correction data ΔY ₁ (θ ″) from the source vector to the destination vector is obtained. The position of the point P _d1 ″ is determined. Therefore, as the point P _s1 ″ is farther from the first source vector SV ₁ , that is, the farther θ ”is from θ _s , the point P _d1 ″ of the destination is converted to the point P before conversion. _s1 ”).

That is, the fact that the point P _d1 ″ of the conversion destination is close to the point P _s1 ″ before conversion means that the color of the point P _s1 ″ does not change significantly by the color correction process. Accordingly, the color correction apparatus, by using the weighting function K (θ) by the hue angle (θ) as a function, if the receding conversion of the color of the point (P _s1 ") in from the source vector, the point (P _s1 ”) Is converted into the color of the point P _d1 ” close to this point itself, so that a more natural color conversion can be realized.

This weighting function K ([theta]) is not limited to the function as shown in FIG. 13A, but a weighting function as shown in FIG. 14A or 14B may be used depending on the image to be converted.

By the secondary processing unit 50 of the configuration shown in FIG. 12 used as the secondary processing unit 38 of the color collector unit 35, the saturation degree 71 and the color 115 for the source video image as shown in FIG. The result of the secondary process by assigning a degree (luminance level of 107 gradations) to the source vector, setting the color 87 degrees to the destination vector is shown in FIG. 16, and performing the secondary process by setting the color 308 ° to the destination vector. The results are shown in FIG. 17, and the results of secondary processing by setting the color 222 ° to the destination vector are shown in FIG. As is apparent from Figs. 15 to 18, the secondary processing unit 50 makes it possible to greatly change the color without following an unintended change in color.

Further, in the secondary processing unit 38 of the color collector unit 35 in the image processing apparatus 30, for example, in place of the color collector unit 50 having the configuration shown in FIG. You may use the color collector part 60 of the structure as shown in the following figure. The secondary processor 60 shown in FIG. 19 includes a coordinate conversion circuit 61, first and second lookup tables 62 and 63, and first to fourth multiplication circuits 64, 65, 66, 67 and The addition circuit 68 is comprised.

In this secondary processing unit 60, the coordinate conversion circuit 51 is configured to supply color difference data U and V output from the primary processing unit 37. The coordinate conversion circuit 37 is configured to sequentially input color difference data U and V.

θ = arctan (V / U)

r = U / cosθ

= (U ² + V ² ) ^1/2

By performing the arithmetic processing, the respective color difference data U and V are converted into data of color? And saturation r. As a result, the secondary processing unit 60 expresses the video signals sequentially input in the polar coordinate format on the color plane. At this time, the first coordinate conversion circuit 61 generates data of 14 bits of color θ and data of 11 bits of saturation r from the color difference data U and V of 10 bits. This ensures sufficient resolution in subsequent processing. Data of the color θ generated by the coordinate conversion circuit 61 is supplied to the lookup tables 62 and 63, and data of the saturation degree r is supplied to the first multiplication circuit 64. do.

The first lookup table 62 is formed by accumulating the comprehensive correction data ΣΔR, ΣΔX, and ΣΔY previously calculated by the central processing unit 11 of the computer 10. And the first to third multiplication circuits 64, 65, and the plurality of correction data ΣΔR, ΣΔX, and ΣΔY corresponding to the color θ calculated by the coordinate conversion circuit 61 to the address. 66).

The first multiplication circuit 64 multiplies the saturation r calculated by the coordinate conversion circuit 61 by the correction data ΔR of the saturation r output from the first lookup table 62, The multiplication output is supplied to the second and third multiplication circuits 65 and 66.

Further, the second multiplication circuit 65 supplies correction data DELTA X formed from the U-axis component of the vector of color θ output from the first lookup table 62 from the first multiplication circuit 64. Multiply the output saturation r. Further, the first multiplication circuit 66 corrects the V-axis component of the vector of the color? Output from the first lookup table 62 to the saturation r output from the first multiplication circuit 64. The data DELTA Y is multiplied by the saturation degree r output from the first multiplication circuit 64. As a result, the second and third multiplication circuits 65 and 66 output respective multiplication outputs as color data U _d and V _d of the destination vector.

In addition, the second lookup table 63 includes, in advance, a comprehensive gain ΣΔGAIN and an offset amount ΣΔOFF of the luminance level for each color θ calculated by the central processing unit 11. Is formed by accumulating the sigma, and the color gain? Outputted from the first coordinate conversion circuit 61 is converted into an address gain ΣΔGAIN and an offset amount ΣΔOFF by the fourth multiplication circuit 67 and the addition circuit. Output to (68).

The fourth multiplication circuit 67 multiplies the gain ΣΔGAIN supplied from the second lookup table 63 by the luminance data Y sequentially input from the primary processor 37, and multiplies the multiplied output thereof. Is supplied to the addition circuit 68.

The addition circuit 68 adds an offset amount ΣΔOFF to the output data of the fourth multiplication circuit 67 and outputs it. In this way, the fourth multiplication circuit 67 and the addition circuit 68,

Y _d = Σ △ GAIN × Y _s + Σ △ OFF

The arithmetic processing is executed to correct the luminance level with respect to the range W of the object to be processed by the characteristics set by the operator.

Here, the comprehensive correction data (ΣΔU, ΣΔV and ΣΔR) will be described. As described in FIG. 12, the color collector device of the present invention can set not only one source vector, but also any 1 to n source vectors and any n destination vectors respectively corresponding to the n source vectors. Consists of. Therefore, the comprehensive correction data obtained by the correction data (ΔU ₁ to ΔU _n ) of the components in the U-axis direction corresponding to the first to nth source vectors is defined as ΣΔU, and the first to nth sources are defined. Comprehensive correction data obtained by correction data (ΔV ₁ to ΔVn) of the component in the V-axis direction corresponding to the vector is defined as ΣΔV, and correction data in the saturation direction corresponding to the first to nth source vectors. The comprehensive correction data obtained by (ΔR ₁ to ΔR _n ) is defined as ΣΔR.

Incidentally, the secondary processing unit shown in Fig. 19 is not UV coordinates, and color collection processing is performed using polar coordinates. Therefore, the conversion data for converting the color angles of the first to nth source vectors from the color angles of the first to nth destination vectors are defined as Δθ ₁ to Δθ _n , respectively. If the comprehensive correction data on the color angle corresponding to the source vector is Δθ,

Σ △ θ = Δθ ₁ + △ θ ₂ + ·· + Δθ _n

_{Σ △ R = △ R 1 +} △ R 2 + ··· + △ R n

It can be expressed as

Next, in order to obtain the comprehensive correction data ΣΔθ for the color angle, the color of the first source vector SV ₁ set by the operator is θ _s1 as shown in FIG. 20A, and the first source vector ( The color angle of the first destination vector DV ₁ set to correspond to SV ₁ ) is θ _D1 . In addition, a weighting function set for the first source vector SV ₁ is set to K ₁ (θ). Therefore, the correction data (Δθ ₁ ) regarding the color for changing the color of the pixel in the vicinity of the first source vector SV ₁ to the color of the pixel in the vicinity of the first destination vector DV ₁ is obtained.

Δθ ₁ = (θ _D1 -θ _S1 ) × K ₁ (θ)

It can be expressed as

In addition, as described in equation (6), the color collector device of the present invention is configured to be able to set any n source vectors. Therefore, as shown in Equation (6), assuming that the first to nth source spectra are set,

Δθ ₁ = (θ _D1 -θ _S1 ) × K ₁ (θ)

Δθ ₂ = (θ _D2 -θ _S2 ) × K ₂ (θ)

···

Δθ _n = (θ _Dn -θ _Sn ) × K _n (θ)

Equation

Therefore, substituting Δθ ₁ to Δθ _n of equation (20) into equation (18),

Σ △ θ = Δθ ₁ + △ θ ₂ + ·· + Δθ _n

= (θ _D1 -θ _S1 ) × K ₁ (θ)

+ (θ _D2 -θ _S2 ) × K ₂ (θ)

+ ···

+ (θ _Dn -θ _Sn ) × K _n (θ)

Becomes

Since this comprehensive correction data ((DELTA) (theta)) is data of the polar coordinate system in UV space, this data must be converted into the data of the rectangular coordinate system in UV space. Therefore, if the data in the U-axis direction represented by the rectangular coordinate system in the UV space is ΔU and the data in the V-axis direction are ΔV,

ΔX = cos (θ + ΣΔθ)

= cos (θ + (θ _D1 -θ _S1 ) × K ₁ (θ)

+ (θ _D2 -θ _S2 ) × K ₂ (θ)

+ ···

+ (θ _Dn -θ _Sn ) × K _n (θ)

ΔY = sin (θ + Σ △ θ)

= sin (θ + (θ _D1 -θ _S1 ) × K ₁ (θ)

+ (θ _D2 -θ _S2 ) × K ₂ (θ)

+ ···

+ (θ _Dn -θ _Sn ) × K _n (θ)

Becomes

Next, in order to obtain the comprehensive correction data ΣΔR relating to the saturation degree, as shown in FIG. 20, the saturation degree of the first source vector SV ₁ set by the operator is set to “R _S1 ”, and the first destination vector The degree of saturation of (DV ₁ ) is referred to as "R _D1 ". Therefore, the ratio of saturation between the first source vector SV ₁ and the destination vector DV ₁ may be represented by R _D1 / R _S1 .

Similarly to the calculation of the color angle, when the weighting function set for the first source vector SV ₁ is K ₁ (θ), the color of the pixel near the first source vector SV ₁ is defined as the first destination vector. Correction data (ΔR ₁ ) relating to saturation for changing to the color of the pixel in the vicinity of (DV ₁ ),

ΔR ₁ = (R _D1 / R _S1 ) × K ₁ (θ)

Becomes

Further, the correction data ΔR ₁ ΔR _n set as corresponding to the first to nth source vectors, respectively,

ΔR ₁ = (R _D1 / R _S1 ) × K ₁ (θ)

△ R ₂ = (R _D2 / R _S2 ) × K ₂ (θ)

···

ΔR _n = (R _Dn / R _Sn ) × K _n (θ)

Becomes

Therefore, if each correction data (ΔR ₁ to ΔR _n ) of equation (24) is substituted into equation (18),

Σ △ R = (R _D1 / R _S1 ) × K ₁ (θ)

+ (R _D2 / R _S2 ) × K ₂ (θ)

+ ···

+ (R _Dn / R _Sn ) × K _n (θ)

Becomes

The central processing unit 11 uses the equations (22) and (25) to calculate the total correction data ΣΔX, ΣΔY, ΣΔR for each 1 ° with respect to θ having a value of 0 ° to 360 °. ) Is calculated. That is, 360 comprehensive correction data (ΣΔX, ΣΔY, ΣΔR) corresponding to the full angle is generated. These calculated total correction data ΣΔX, ΣΔY, ΣΔR are stored in the lookup table 62 so as to be addressed by each angle θ.

Next, the comprehensive correction data (ΣΔGAIN and ΣΔOFF) stored in the lookup table 63 will be described.

The color collector device of the present invention is configured to set arbitrary correction gains (GAIN ₁ to GAIN _n ) and offset values (OFF ₁ to OFF _n ) with respect to luminance signals of arbitrary first to nth source vectors, respectively. It is. Thus, the comprehensive correction data obtained by the gains GAIN ₁ to GAIN _n relating to the luminance signals of the first to nth source vectors is defined as ΣΔ GAIN and the luminance signal set for the first to nth source vectors. Comprehensive correction data obtained based on offset data (OFF ₁ to OFF _n ) relating to is defined as ΣΔOFF.

Here, considering the weighting function K (θ) described above, the correction data (ΔGAIN ₁ to GAIN _n ) relating to the gain of the luminance signals of the first to nth source vectors is

△ GAIN ₁ = GAIN ₁ × K ₁ (θ)

△ GAIN ₂ = GAIN ₂ × K ₁ (θ)

···

△ GAIN _n = GAINn × K ₁ (θ)

Becomes Therefore, the comprehensive correction data (ΣΔGAIN) regarding the gain of the luminance signal is

Σ △ GAIN = △ GAIN ₁ + △ GAIN ₂

+ ··· + △ GAIN _n

= GAIN ₁ × K ₁ (θ)

+ GAIN ₂ × K ₁ (θ)

+ ···

+ GAIN _n × K ₁ (θ)

Becomes

Similarly, considering the weighting function K (θ), the correction data ΔOFF ₁ to ΔOFF _n regarding the offset of the luminance signals of the first to nth source vectors

△ OFF ₁ = OFF ₁ × K ₁ (θ)

△ OFF ₂ = OFF ₂ × K ₁ (θ)

···

△ OFF _n = OFF _n × K _l (θ)

Becomes Therefore, the comprehensive correction data (Σ △ OFF) regarding the offset of the luminance signal is

Σ △ OFF = △ OFF ₁ + △ OFF ₂ + ·· + △ OFF _n

= OFF ₁ × K ₁ (θ) + OFF ₂ × K _l (θ)

+ ·· + OFF _n × K ₁ (θ)

Becomes

Based on these equations (27 and 29), the central processing unit 11 calculates the comprehensive correction data (ΣΔGAIN, ΣΔOFF) for each 1 ° with respect to θ having a value of 0 ° to 360 °. do. That is, 360 comprehensive correction data (ΣΔGAIN and ΣΔOFF) corresponding to the full angle are generated. These calculated total correction data ΣΔGAIN and ΣΔOFF are stored in the lookup table 63 so as to be addressed by the angles θ.

Here, the editing apparatus 100 in which the secondary processing unit 60 having the configuration shown in FIG. 19 described above is used as the secondary processing unit 38 of the color collector unit 35 in the image processing apparatus 30. In the above, when an operator selects a menu for setting conditions relating to secondary processing by the secondary processing unit 60, the central processing unit 11 of the computer 10 displays a display screen such as the display screen of FIG. The still image before and after the process is displayed by the windows W2 and W3. The still image after the processing in this case is processed by the color collector unit 35 according to the selection of the operator, according to the default characteristic or the characteristic stored in the storage means.

Further, the central processing unit 11 displays a predetermined color swatch, and when an operator clicks the mouse 17 on a still image before processing, the color of the source vector based on the color and saturation of the clicked pixel Data θ _s1 and saturation R _D1 are calculated. Further, the central processing unit 11 displays the source vector selected by the operator, and calculates the color data θ _D1 and the saturation degree R _D1 of the destination vector corresponding to the source vector in the same manner as in the case of the source vector. .

Further, the central processing unit 11 receives the gain G of the processing of the color range θ _w of the weighting function K (θ) and the weighting function K ₁ (θ) with respect to the source vector. The central processing unit 11 also generates the weighting function K ₁ (θ) of this source vector based on the input range W and gain G of the processing target.

The weighting function K (θ) is created in a shape obtained by cutting out an isosceles triangular shape having the bottom and height of the range W and the gain G, respectively, as the height 1, for example, the gain G. When this is 1 or less, the weighting function K (θ) is represented by the above formulas (10 to 12).

Further, the central processing unit 11 simultaneously accepts correction values of the luminance levels in the source vector at this time. This correction is represented by gain GAIN ₁ and offset amount OFF ₁ .

The central processing unit 11 sets a desired parameter for the first to nth source vectors and the destination vector in response to an operator's operation. That is, the central processing unit 11 executes the next arithmetic processing when all parameters are input to the first to nth source vectors and the destination vector corresponding thereto.

The central processing unit 11 calculates correction data (Δθ ₁ to Δθ _n , ΔR ₁ to ΔR _n ) transferred to each source vector based on equations (20 and 24), and then calculates The correction data are weighted by the corresponding weighting function K (θ). Further, the central processing unit 11 calculates the comprehensive correction data ΣΔθ and ΣΔR based on Equation (18).

The central processing unit 11 sends the comprehensive correction data Δθ and ΔR calculated in this way to the image processing unit controller 31 of the image processing apparatus 30 to look up the color collector unit 35. The table 62 is stored.

In addition, the central processing unit 11 similarly weights the correction amount ΔY for the luminance level based on equations (27 and 29) with the weighting function K (θ), so that the comprehensive correction in each color is performed. Data (ΣΔGAIN, ΣΔOFF) is calculated. As a result, the central processing unit 11 simultaneously corrects the luminance level with respect to the range W of the processing target, and effectively avoids the occurrence of discomfort by changing the color. At this time, also in the correction of the luminance level, the comprehensive correction data is stored in the look-up table 63 of the color collector 35 in the same manner as in the case of the hue and saturation.

When the correction amount is calculated in this way, the central processing unit 11 calculates each correction amount with 14 bits and 11 bits, respectively, with respect to the color θ and the saturation r, and further calculates the total correction amount ΣΔ (θ). Calculate In this case, the video signal is a digital video signal in a so-called 4: 2: 2 format, and luminance data and color difference data are each formed by 10 bits.

That is, when 10-bit color difference data in the 4: 2: 2 format is represented by the color difference plane, θ ₁ = arctan (5ll / 5l0)

= 45.056 117 ° and θ ₁ = arctan (511/511)

Since it is = 45.000000 °, the highest resolution θ _MAX is θ _MAX = θ ₁ −θ ₂ = 0.061 117 °.

When it is difficult to secure the resolution of this angle of 0.056117 °, when the color is corrected, the color that has changed in the original screen is changed in steps. Therefore, in order to secure the resolution of the angle 0.056117 °, it is necessary to express the color? In 14 bits.

In addition, in the saturation degree r, as shown in FIG. 21, when the saturation degree r sequentially changes in the oblique direction in the pixels P1, P2, P3, and P4 continuous in the horizontal direction and the vertical direction, Also in the image after correction, it is necessary to maintain the change of the saturation degree r in this slippery inclination direction. That is, it is necessary to change the saturation between the pixels Pl and P4 adjacent to the oblique direction in response to the change in the saturation between the pixels Pl, P2, P1 and P3 adjacent to the horizontal direction and the vertical direction.

For this reason, if the change in the saturation between the pixels P1 and P2, P1 and P3 adjacent to the horizontal direction and the vertical direction is set to the value 1, 1: 2 ^1/2 = 2 ¹⁰ : X, X ≒ 1448

For this reason, it is necessary to express saturation r with 11 bits with respect to the color difference data represented by 10 bits.

Therefore, the central processing unit 11 expresses the color and saturation of the source vector, the color and the saturation of the destination vector in 14 bits and 11 bits, and sequentially changes the color? Calculate the correction amount (ΣΔ (θ)) of color and saturation with 11 bits. In addition, the bit lengths such as the weighting function K (θ) are also set to correspond to them.

Here, for the source video image as shown in FIG. 22 by the secondary processing unit 60 of the configuration shown in FIG. 19 used as the secondary processing unit 38 of the color collector unit 35, the saturation degree 71 is used. , The color 115 ° (luminance level 107) is specified as the source vector, the color 87 ° is set as the destination vector, and the secondary processing results are shown in FIG. 23, and the color 308 ° is set as the destination vector. FIG. 24 shows the result of the secondary processing, and FIG. 25 shows the result of the secondary processing by setting the color 222 ° as the destination vector. As is clear from Figs. 22 to 25, the secondary processor 60 shows a very slight change in the source video image in the flesh portion near the color 115 ° of the source vector. Can be obtained.

In addition, the secondary processor 60 designates the source video image as shown in FIG. 26 as the source vector, and the secondary processing by setting the green as the destination vector. 28 shows the results of secondary processing by designating red as the source vector, green as the destination vector, green as the source vector, and red as the destination vector. 29 shows the results of secondary processing by designating red, green, and blue as source vectors, and setting green, red, and yellow as destination vectors. As can be seen from Figs. 26 to 29, according to the secondary processing unit 60, even if the sequential source vector is increased, the processing can be executed without affecting the image of the processing result at all.

In addition, the secondary processing unit 60 shows the result of secondary processing on the source video image as shown in FIG. 30 by emphasizing the saturation of the blue, yellow, and red components in FIG. 32 shows the result of secondary treatment with reduced yellow component under the above conditions. As is clear from Figs. 30 and 31, the secondary processing unit 60 processes the image of the glow of the evening glow, thereby increasing the difference in the clarity of the sky, producing a scene of a clear rising picture or a scene just before the sunset. You can do it.

In addition, as the secondary processing unit 38 of the color collector unit 35 in the image processing apparatus 30, for example, in place of the color collector unit 60 having the configuration shown in FIG. The color collector unit 70 having the configuration as shown in 33 may be used.

The secondary processor 70 shown in FIG. 33 includes a first coordinate conversion circuit 71, first and second lookup tables 72 and 73, and first to third multiplication circuits 74 and 75, respectively. 76), the addition circuit 77 and the second coordinate conversion circuit 78.

In this secondary processing unit 70, the first coordinate conversion circuit 71 is configured to supply color difference data U and V output from the primary processing unit 37. The coordinate conversion circuit 37 executes the arithmetic processing of the above-described formula (16) with respect to the color difference data U and V sequentially inputted, thereby converting the color difference data U and V into the color? And the saturation r. Is converted into the data. As a result, the secondary processing unit 70 expresses the video signals sequentially input in the polar coordinate format on the color plane. At this time, the first coordinate conversion circuit 71 generates data of 14 bits of color θ and data of 11 bits of saturation r from the color difference data U and V of 10 bits. This ensures sufficient resolution in subsequent processing. The data of the color θ generated by the first coordinate conversion circuit 71 is supplied to the respective lookup tables 72 and 73, and the data of the saturation degree r are supplied to the first and second multiplication circuits 74. , 76).

Further, the first lookup table 72 is formed by accumulating correction data ΔX and ΔY calculated in advance by the central processing unit 11 of the computer 10, and converting the first coordinates. The correction data ΔX and ΔY corresponding to the color θ calculated by the circuit 61 are output to the first and second multiplication circuits 74 and 75.

The first multiplication circuit 74 is correction data (Δ) that is a horizontal axis component of the color θ output from the first lookup table 72 at the saturation r calculated by the first coordinate conversion circuit 71. Multiply X) and supply the multiplication output to the second coordinate conversion circuit 78. Further, the second multiplication circuit 75 performs correction data (which is a vertical axis component of the color θ output from the first lookup table 72) to the saturation r output from the first coordinate conversion circuit 71. The multiplication is performed, and the multiplication output is supplied to the second coordinate conversion circuit 78.

The second coordinate conversion circuit 69 converts data based on the horizontal axis and the vertical axis of the color θ output from the first and second multiplication circuits 74 and 75 into color difference data U and V. Convert and output

In addition, the second lookup table 73 includes, in advance, a comprehensive gain ΣΔGAIN and an offset amount ΣΔOFF of the luminance level for each color θ calculated by the central processing unit 11. ), And the gain ΣΔGAIN and the offset amount ΣΔOFF are converted into the third multiplication circuit 76 by using the color θ output from the first coordinate conversion circuit 71 as an address. It outputs to the addition circuit 77.

The third multiplication circuit 76 multiplies the luminance data Y sequentially input from the primary processor 37 by the gain ΣΔGAIN supplied from the second lookup table 73 to multiply its multiplied output. The addition circuit 77 supplies it.

The addition circuit 77 adds an offset amount ΣΔOFF to the output data of the third multiplication circuit 76 and outputs it. In this way, the calculation process of Formula (17) mentioned above is performed, and the luminance level is correct | amended according to the characteristic set by the operator about the range W of a process target.

That is, the secondary processing unit 70 shown in FIG. 33 omits the correction process regarding the saturation degree r in the secondary processing unit 60 having the configuration shown in FIG. 19 described above, and the saturation degree r While maintaining the constant, only the color θ is changed and the secondary processing is performed.

In the secondary processing unit 70 having such a configuration, by eliminating the correction processing for the saturation degree r, the setting work of the first lookup table 72 can be completed in a short time by that amount, and the configuration is simplified. can do.

Here, the secondary processor 60 specifies saturation 71 and color 115 ° (luminance level 107 gradations) as the source vector for the source video image as shown in FIG. 34, and destination color 87 °. 35 shows the result of the secondary processing by setting it as a vector, FIG. 36 shows the result of the secondary processing by setting the color 308 ° as the destination vector, and sets the color 222 ° as the destination vector. 37 shows the result of the secondary processing. In the secondary processing unit 70, when the color 308 ° is set as the destination vector, the flesh portion near the color 308 ° of the source vector becomes magenta, When continuity was observed, the continuity of color was better than the secondary processing part 60 of the structure shown in FIG. 19 mentioned above.

As described above, in the secondary processing unit 60 having the configuration shown in Fig. 19, the source vector and the destination vector are shown on the plane based on the color as shown in Fig. 38. In the secondary processing unit 70 shown in FIG. 33, the source vector and the destination vector in the plane based on the color, as shown in FIG. It is thought to be caused by correcting color and saturation by making arcs in between.

Next, the editing processing operation by the editing apparatus 100 having such a configuration will be described.

The central processing unit 11 of the computer 10 in the editing apparatus 100 secures the work area in the random access memory (RAM) 13 as described above, and uses the keyboard 16 of the editing operator and the like. In response to the operation of the mouse 17, by executing a series of processing procedures stored in the read-only memory (R0M) 12, a hard disk device (not shown), and the like, the operation of the editing apparatus 100 is controlled to edit. When the start of the editing processing by the operator is instructed, the editing processing module (software program) is started to display a predetermined editing processing GUI (Graphical User Interface) on the screen of the monitor device 14.

The editing operation in this editing apparatus 100 is executed as follows on the editing processing GUI.

First, the central processing unit 11 displays time information on the material to be edited on the timeline of the GUI. That is, the editing operator uses a plurality of materials (for example, one material is recorded on one tape) recorded in the hard disk device 20 by an operation of the mouse 17 or the like. When one material is selected, the central processing unit 11 displays time information about this material on the timeline of the GUI.

The central processing unit 11 then determines whether an event has been set. That is, the editing operator designates the edit start point (in point) and the edit end point (out point) for the work displayed on the timeline by the operation of the mouse 17 or the like. As a result, one event (also called a scene) defined by the edit start point and the edit end point is set. Of course, not only one event but also a plurality of events may be set. The central processing unit 11 determines whether or not an event is set by this operation.

Further, the central processing unit 11 determines whether or not one frame for color correction processing is selected. That is, the editing operator selects one scene from a plurality of scenes displayed on the timeline by the operation of the mouse 17 or the like, and selects one frame from the scenes. The central processing unit 11 determines whether or not one frame for color correction processing is selected by this operation.

The order of setting the event and selecting one frame may be reversed or simultaneous.

Next, the central processing unit 11 determines whether or not color correction processing is specified. That is, the editing operator designates the color correction process by clicking the color correction button on the GUI, for example. The central processing unit 11 determines whether or not color correction processing is specified for the event selected by this operation.

When the color correction processing is designated, the central processing unit 11 activates the editing processing module to display a predetermined color correction GUI on the screen of the monitor device 14.

The disk unit controller 21 of the hard disk device 20 is supplied with a playback command for instructing playback of a designated frame from the central processing unit 11 to thereby play back video data of a designated frame from the hard disk array 22. do. In addition, the image processing unit controller 31 of the image processing apparatus 30, in response to the control command from the central processing unit 11, relates to the video data reproduced by the hard disk apparatus 10, wherein the 1 The primary processing unit 37 executes the primary processing as described above. The video data first processed for opening temperature is converted by the image processing unit controller 31 into an AVI (Audio Visual lnteractitve) file format and transmitted to the computer 100 via a local bus. .

The central processing unit 11 uses the video data in the AVI (Audio Visual Interactitve) file format transmitted from the image processing unit controller 31 via a local bus to display the image of the end of the first processing on the GUI for color correction. Display in the car video display window.

In this case, the central processing unit 11 converts all pixel data of the first-processed video data into luminance data Y and color difference data U and V. FIG. That is, since the video data of the AVI file format transmitted from the image processing unit controller 31 via the local bus is represented in the RGB format, the central processing unit 11

According to the conversion equation shown in FIG.

The central processing unit 11 then displays the video data converted into the YUV format in a vector scope on the color correction GUI. The vector scope uses only the color difference data (U, V) of the data in YUV format, and displays the data of all supplied pixels with one pixel as one light point (display point), thereby showing the distribution in the UV plane. to be.

Here, an actual example of the condition setting screen of the secondary processing displayed on the screen of the monitor device 14 is shown in FIG. 40, and a schematic diagram thereof is shown in FIG. 41. The condition setting screen of the secondary processing includes 1; An image confirmation unit AR1 having a secondary video display window and a secondary video display window, a vector scope unit AR2, a vector selection unit AR3, and a system setting unit AR4 are formed.

The central processing unit 11 applies a still image (primary processing) before the secondary processing to the primary video display window and the secondary video display window of the image confirming unit AR1 on the condition setting screen of the secondary processing. It consists of the received still image, and displays the still image (Secondary) after the secondary process. That is, the central processing unit 11 performs the secondary processing by processing the still image of one frame designated by the editing operator from the editing target specified by the editing start point and the editing end point in the primary processing unit 37 as described above. It displays as a previous still image. The central processing unit 11 sequentially updates the contents of the above-described lookup table of the secondary processing unit 38 according to this condition when the editing operator variously changes the processing condition through this condition setting screen. The secondary processing result by this updated content is displayed as the still image after a primary process. As a result, the editing apparatus 100 can set various processing conditions while visually confirming the processing result, so that the color collector can be processed with a high degree of freedom with a simple operation.

Further, in the image confirmation unit AR1 of the condition setting screen of the secondary processing, the display switching button FB is disposed on the upper part of the still image before the secondary processing and after the secondary processing, respectively. When this button FB is clicked by a mouse, the central processing unit 11 sends a still image before or after the secondary processing to the dedicated monitor device by execution of an event registered to this button FB. Change the overall behavior to display. For this reason, the processing result can be examined in detail as needed, and the processing with high precision can be performed by that much.

Further, the central processing unit 11 acquires the coordinate data of the clicked position when the editing operator clicks the mouse 17 in the still image before the secondary processing displayed in the primary video display window. The image data of the position clicked from the coordinate data is acquired by the 20 primary processing units 37 of the image processing apparatus. As shown by an arrow A in Fig. 41, the central processing unit 11 marks markers on adjacent vector scopes AR2 according to the luminance Y and the color V, V of the image data. (M) is displayed. The vector scope AR2 is a display unit configured to visually check the relationship between the color of each pixel and the processing range. This makes it possible to easily and surely check the relationship between the color and the processing range of the place to be changed and the color and the processing range of the place to be excluded from the change process as necessary, so that the operation is as simple as that. The color collector can be processed with a high degree of freedom.

Here, the vector selection unit AR3 and the system setting unit AR4 of the condition setting screen of the secondary processing are schematically shown in FIG. 42 together with a part of the vector parameter setting unit AR5. As shown in FIG. 42, in the vector selection unit AR3, ten buttons B0 to B9 for selecting a source vector are arranged side by side in the horizontal direction, and on both sides of these buttons B0 to B9, the switching is performed. The buttons BL and BR are arranged. Further, following the switching button BR on the right side, a button B11 for selecting all previously selected source vectors is arranged, and a display portion A1 for displaying the number of the selected source vector is formed subsequently.

When the central processing unit 11 displays this condition setting screen, the central processing unit 11 displays the number of the source vector by the sequential numbers 1 to 10 on the ten buttons B0 to B9. When the switching buttons BL and BR are clicked on by the mouse 17, the buttons B0 are displayed in the direction of the triangular shape displayed on the buttons BL and BR by the execution of the events of the buttons BL and BR. To B9) in order.

When the central processing unit 11 clicks on any one of the buttons B0 to B9 by the mouse 17, the central processing unit 11 executes an event registered to the buttons B0 to B9, and the number set to each button. Is displayed on the display portion A1. In addition, the central processing unit 11 displays the source vector of this number in the vector scope unit AR2 and the vector parameter setting unit AR5, and also the vector scope unit AR2 and the vector parameter for the source vector of this number. The operation of the setting unit AR5 is accepted and, thereby, input of a parameter is received with respect to the source vector of this number. Incidentally, at the start of the operation, the central processing unit 11 displays the source vector of this number in the vector scope unit AR2 and the vector parameter setting unit AR5 rather than the default value, and changes the default value thereon. Accepts input of parameters.

In addition, the central processing unit 11 sets the look-up table of the secondary processing unit 38 by executing the above-described calculation processing only with respect to the source vector of the selected number, and based on the set contents, the image confirmation unit The secondary video display window display at AR1 is updated. On the other hand, when the button B11 for selecting all the source vectors is clicked by the mouse 17, the selection / non-selection button B12 arranged in the system setting unit AR4 among the first to the 100th source vectors. With respect to all source vectors selected by the operation of the above), the above-described calculation processing is executed by the parameters set in these selected source vectors, and the lookup table of the secondary processing unit 38 is set to confirm the image by the set contents. The display of the subarray AR1 is updated.

As a result, the editing apparatus 100 sets the processing conditions while confirming the processing results relating to the individual source vectors, and selects the source vectors by the operation of the selection / non-selection button B12 as necessary. By operating the button B11 for selecting all the source vectors, the overall processing result can be confirmed. Therefore, even when the individual source vectors are freely set, and the parameters of the plurality of source vectors are variously set and the color collector is processed at a high degree of freedom, the overall processing results are visually checked and the parameters appropriately selected. It is possible to change and to select and correct the source vector, thereby allowing the desired processing to be executed by a simple operation.

In the vector parameter setting unit AR5, a button B12 constituting the toggle switch of the selection / non-selection is arranged, and a button OK for instructing completion of all settings is arranged in the system setting unit AR4. When the selection / deselection button B12 is clicked by the mouse 17, the central processing unit 11 switches selection / deselection with respect to the source vector of the number displayed on the display section A1. Under the button of the source vector corresponding to this number (the first button B0 in FIG. 42), the letter of Act indicating the selected state is displayed, and the display is stopped. Further, when the button OK instructing the completion of all the settings is clicked by the mouse, the central processing unit 11 executes the above-described calculation processing by the parameters set in all the selected source vectors, so that the secondary processing unit 38 The lookup table is set and the display of the condition setting screen is finished. In addition, a button cancel for canceling the operation of the button OK is arranged in the system setting unit AR4.

43 is a diagram schematically showing a vector parameter setting unit AR5 of the condition setting screen of the secondary processing. The central processing unit 11 accepts parameter settings for the source vector selected through the vector selection unit AR3 by operating the control bar arranged in the vector parameter setting unit AR5.

That is, in the vector parameter setting unit AR5, a default button Bl3 is disposed adjacent to the select / non-select button B12, and the central processing unit 11 selects a vector when the button Bl3 is operated. The parameter of the source vector selected by the part AR3 is reset to a default value. In this case, the central processing unit 11 is a parameter of each source vector, and the range of the color, the saturation, the luminance, the color, the saturation, the luminance, and the weighting function K (θ) of each source vector ( W) and the gain G, the multiplication value and the offset value of the luminance level are accepted. Among them, the color, saturation, and luminance of the source vector are set as the default value corresponding to the number of each source vector, and in particular, the color set in the conventional color collector is the default value. It is configured to be set as. As a result, in the editing processing apparatus 100, even an editing operator familiar with the conventional color collector can be operated without discomfort.

On the other hand, the hue, saturation, and luminance of the destination vector are set to the same hue, saturation, and intensity as the corresponding source vectors, respectively, and the range (W) and gain (G) of the weighting function K (θ) are set as default values. Regarding, the predetermined value is set as a default value. In addition, as the multiplication value of the luminance level, the value 1 is set as the offset value of the luminance level and the value 0 is set as the default value.

The central processing unit 11 accepts the setting of the parameters from the default values in this way with respect to each source vector, changes these values, and switches the display of the image confirming unit ARl, and thereby the button B13. When this operation is performed, the parameter thus changed is returned to the default value, and the display of the image confirmation unit AR1 is switched.

Here, a scroll bar C1 and scroll buttons C2 and C3 are disposed at the right end of the vector parameter setting unit AR5, and the central processing unit 11 includes these scroll bars Cl or scroll buttons ( When C2 and C3 are operated by the mouse 17, the display of the control bar is scrolled.

As shown in Fig. 43, nine control bars are allocated to the vector parameter setting unit AR5, and the central processing unit 11 operates the scroll bar C1 or the scroll buttons C2 and C3. 6 of these nine control bars are displayed on the vector parameter setting part AR5.

44 shows the relationship between these control bars and the color correction process.

Of the nine control bars, three control bars from the top are assigned the color (Scr Hue), saturation (Scr Sat), and luminance (Scr Lum) of the source vector, respectively, and the central processing unit 11 is placed on these control bars. When the button 17 is caught by the mouse, the display of this button is moved left and right in response to the operation of the mouse 17. In addition, the color, saturation, and luminance of the source vector are updated according to the position of the button, respectively, and the values of the color, saturation, and luminance arranged on each button are updated. In addition, the display of the image confirming unit AR1 is switched in conjunction with these processes.

The three subsequent control bars are each assigned a color (Dst Hue), a saturation (Dst Sat), and a luminance (Dst Lum) of the destination vector, and the central processing unit 11 has a button disposed on the control bar. When it is caught and operated, the display of the buttons is similarly shifted left and right, and the hue, saturation, and luminance of the destination vector are updated, and the values of the hue, saturation, and luminance arranged on each button are updated. In addition, the display of the image confirming unit AR1 is switched in conjunction with these processes.

Further, as shown in FIG. 45, the subsequent control bar is assigned a range W (Win) of the weighting function K ([theta]), and the central processing unit 11 has a button disposed on the control bar. When the mouse 17 is caught and operated, the display of the button is similarly moved left and right, and the values of the range W of the weighting function K (θ) and the range W arranged on the button are updated. . In addition, the display of the image confirming unit AR1 is switched in conjunction with these processes.

In addition, two successive control bars are assigned a multiplier (Mul Lum) and an offset value (Add Lum) of the luminance level, and the central processing unit 11 operates so that the buttons arranged on the control bar can be caught by the mouse. Similarly, the display of the button is shifted left and right, and the multiplication value and offset value of the luminance level are updated. In addition, the display of the image confirming unit AR1 is switched in conjunction with these processes.

On the other hand, a control bar for arranging the gain G (Gain) of the weighting function K (θ) is disposed below the vector scope AR2, and the central processing unit 11 has a button disposed on these control bars. In the same way, the display of the button is moved left and right, and the gain G of the weighting function K (θ) is updated. In addition, the display of the image confirming unit AR1 is switched in conjunction with these processes.

The vector parameter setting unit AR5 is provided with a display unit A3 of the weighting function K (θ) on the right side of the control bar of this gain G (Gain). When the control bar is operated with respect to the range W and the gain G of the weighting function K (θ) and changes these ranges W and the gain G, the central processing unit 11 further includes a vector scope unit which will be described later. When these ranges W and gains G are similarly changed by the operation of AR2, the display of this display unit A3 is switched.

In the display unit A3, the central processing unit 11 displays the vertical line VL1 at the center of the weighting function K (θ) by the same color as the cursor display of the source vector in the vector scope AR2. In addition, similarly, the vertical line VL2 at the point where the weight function K (θ) rises to the value 0 by the same color as the cursor display in the range W of the weight function K (θ) is displayed. In addition, horizontal lines corresponding to the value 1 and the value 0 of the weighting function K (θ) are simultaneously displayed. Thus, in this embodiment, the setting of the range W and the gain G can be visually grasped so that a high degree of freedom can be executed by a simple operation.

In addition, the central processing unit 11 switches the operation of the whole, similarly to the case where these control bars are operated by the mouse 17, by numerical input input through the keyboard 16, whereby as required. You can set parameters by various operations.

Fig. 46 is a schematic diagram showing the vector scope unit AR2. The vector scope unit AR2 displays a color distribution display unit D1 indicating a color distribution of the still image to be subjected to secondary processing, and a color ring R1 indicating the color of the color swatch so as to surround the color distribution display unit D1. ) And color ring R2 are represented in duplicate.

The central processing unit 11 displays, on the color distribution display unit Dl, a black and white image formed by projecting each pixel of a still image distributed in a three-dimensional color space onto a UV plane, as indicated by the symbol F. At the same time, the range W of the source vector, the destination vector, and the weighting function K (θ) is displayed on the color distribution display unit D1, and the parameter setting is accepted through the color distribution display unit D1.

That is, the rgb color system and yuv color system provided in the display of the still image in the image confirmation unit AR1

Represented by The color that can be displayed in this rgb color system is defined in a rectangular area disposed obliquely to the yuv color system, as shown in FIG.

By projecting each pixel of a still image distributed in the three-dimensional color space constituted by the y u v color system onto the UV plane, the color of the still image can be expressed by a color having no brightness and saturation. Specifically, when the color and saturation degree are expressed on the UV plane with respect to each color of the color bar serving as the color reference of the imaging device, as shown in FIG. 48, black and white are expressed on the origin where the UV axes intersect. Will be. Here, the processing of the color collector changes the color in response to the operation of the editing operator, thereby expressing the distribution of colors on the UV plane, and simultaneously displaying the source vector, the destination vector, and the like. It is possible to visually grasp the relationship between the color and the color that you do not want to change, improving the convenience of use. In this case, when the projection and overlapping pixels are set in accordance with the number of overlapping pixels, the brightness of the pixels on the uv plane is set to visually grasp the distribution of colors.

Thus, when the central processing unit 11 displays the condition setting screen, the central processing unit 11 executes the processing procedure shown in FIG. 49 to form a basic display image of the color distribution display unit D1.

That is, in the processing procedure shown in FIG. 49, in step SP1, the area of the image memory corresponding to this color distribution display unit D1 is set to black, and in step SP2, one pixel of the still image is continued. Get u and v values. Further, the central processing unit 11 selectively inputs image data U and V output from the secondary processing unit 37 to obtain u and v values of still images.

In subsequent step SP3, only the predetermined value is increased for the luminance level (brightness) with respect to the contents of the image memory corresponding to the acquired u and v values. In the next step SP4, it is determined whether or not the processing for all the pixels is completed. If a negative result is obtained here, the said central processing unit 11 will return to step SP2.

Thereby, the said central processing unit 11 repeats the process of step SP2-SP3, and sequentially updates the content of the image memory corresponding to the color distribution display part D1 about each pixel which comprises a still image, Each pixel of a still image is projected on a UV plane sequentially, and the brightness of the projected pixel according to the number of overlapping pixels at this time is set. Further, when the central processing unit 11 completes the projection for all the pixels and displays the contents of the image memory on the color distribution display unit D1, an affirmative result is obtained in step SP5, thereby completing this processing procedure. Quit.

Then, when the central processing unit 11 displays the basic image shown in FIG. 46, for example, on the color distribution display unit D1 in this way, the color rings R1 and R2 are displayed before and after. do.

Here, the color ring R1 and the color ring R2 are rings which display the color in this color distribution display part D1 by actual color, and the ring R2 of the outer peripheral side shows the state before color correction. On the other hand, the ring R2 on the inner circumferential side shows a state after color correction. If any one of the vectors is selected in the vector selection unit AR2, the central processing unit 11 changes the display color according to the parameter set for the selected source vector with respect to the color ring R1 on the inner circumferential side. do.

In this manner, the central processing unit 11 senses which color is corrected to which color by setting the parameter by contrasting the color ring R2 on the outer circumference side and the color ring Rl on the inner circumference side so that the parameter can be set. consist of. In particular, in this editing apparatus 100, a plurality of source vectors can be selected as necessary, so that any color is any color due to the contrast between the outer ring color ring R2 and the inner ring color ring Rl. By making it possible to sense sensibly whether or not to be corrected, the processing result can be confirmed visually and accurately, thereby improving the convenience of use.

In addition, when any source vector is selected in the vector selection unit AR2, the central processing unit 11 displays the selected source vector and the corresponding destination vector on the color distribution display unit D1. Here, the central processing unit 11 displays a circular marker MSV at a position corresponding to the color, saturation, and luminance set by the vector parameter setting unit AR5 and the like, thereby representing the source vector. Moreover, the cursor of the straight line which connects this circular marker MSV and an origin is displayed.

Further, the central processing unit 11 has the same circular marker MW1 around the circular marker MSV in accordance with the width W of the weighting function K (θ) set by the vector parameter setting unit AR5 or the like. And MW2) in close proximity to the color ring R1. In addition, a cursor of a straight line connecting each marker MW1 and MW2 with the origin is displayed. As a result, the central processing unit 11 corrects the color in a certain range centering on one color by contrast between the color ring R1 and the color ring R2 and these markers MSV to MW2. The vector scope part AR2 is formed so that it can be grasped simply and reliably. On the contrary, the vector allows the user to easily and reliably grasp in which range of the still image the color is corrected by contrast between the color distribution displayed on the color distribution display unit D1 and the markers MSV to MW2. The scope portion AR2 is formed.

At this time, the central processing unit 11 moves a cursor of a straight line connecting the respective markers MSV to MW2 and the origin to the weight function K (θ) in the display unit A3 of the vector parameter setting unit AR5. Displayed in the same color as the cursors VLl and VL2 at the center and both ends. As a result, the central processing unit 11 forms a display image so that the correspondence between the vector scope AR2 and the display unit A3 can be easily grasped.

In addition, the central processing unit 11 similarly displays a destination vector corresponding to this source vector on the color distribution display unit D1. Here, the central processing unit 11 displays the circular marker MDV at a position corresponding to the color, saturation, and luminance of the destination vector set by the vector parameter setting unit AR5 or the like, and thereby the destination vector. Express In addition, according to the width W of the weighting function K (θ), the same circular markers M1 and M2 are displayed centering on the circular marker MDV. At this time, the central processing unit 11 arranges the markers M1 and M2 such that the distance from the origin to the markers Ml and M2 is equal to the distance from the origin to the marker MDV.

As a result, the central processing unit 11 can easily determine to which color the color designated by the source vector SV or the like is corrected based on the contrast between the color rings R1 and R2 and these markers MDV to M2. The vector scope part AR2 is formed so that it can be grasped | ascertained firmly and reliably. On the contrary, the vector scope can be easily and reliably grasped the distribution of pixels in the processing result by contrast between the color distribution displayed on the color distribution display section D1 and the markers MDV to M2. Form part AR2.

At this time, the central processing unit 11 connects the origin and the markers M1 and M2 in a straight line, and also connects the markers M1 and M2 by means of an arc, and displays them by contrast with the cursor on the source vector side. For example, the vectorscope AR2 is formed so as to sense how the saturation changes due to the correction.

In addition, the central processing unit 11 responds to this change when the parameters are changed by the operation of the vector parameter setting unit AR5 or by keyboard input while displaying the markers M1 to MDV in this way. The display of the markers M1 to MDV is updated, and the color ring R1 is updated.

Further, the central processing unit 11 displays the marker M at the position corresponding to the pixel at the clicked position when the editing operator clicks the mouse 17 on the still image before the secondary processing. Thereby, the central processing unit 11 simply and reliably confirms the relationship between the color of the place to be changed and the processing range and the relationship between the color of the place to be excluded from the change processing and the processing range as necessary. The vector scope part AR2 is formed so that a process of a color collector can be performed with a high degree of freedom with such a simple operation.

Further, when the markers Ml to MDV relating to these source vectors and destination vectors are captured by the mouse, the central processing unit 11 displays the display positions of these markers M1 to MDV in accordance with the movement of the mouse 17. In addition, the parameter is changed in accordance with the change of the display position, and the display of the color ring R2 and the display of the image confirmation unit AR1 are changed.

That is, as shown in Fig. 50, when the mouse MSV of the source vector is caught by the mouse 17, and the mouse 17 is operated according to the cursor connecting the marker MSV and the origin, the arrow Fl As indicated by, the saturation of the source vector is changed. Similarly, when the mouse 17 is operated along the color ring R1, the marker MSV is maintained while maintaining the relative relationship between the marker MSV and the markers MW1 and MW2, as indicated by the arrow F2. Change the color by and change the color of the source vector correspondingly.

On the other hand, as shown in FIG. 51, when the markers MW1 or MW2 corresponding to the range W of the weighting function K (θ) are caught by the mouse 17, as indicated by arrows F3A and F3B. Similarly, as the mouse 17 moves, the display positions of these markers RMWl and MW2 are changed in accordance with the color ring Rl, and in conjunction with this, the range W is changed. Further, according to this range W, as indicated by arrows F3C and F3P, the position of the marker M1 or M2 on the destination vector side corresponding to the markers MW1 and MW2 is determined according to the color ring Rl. Change it.

Similarly, on the destination vector side, when the markers M1 or M2 corresponding to the markers MW1 and MW2 are operated by the mouse 17, the display positions of the markers Ml and M2 are changed and weighted. The range W of the function K (θ) is changed. In conjunction with this, the markers MW1 and MW2 on the source vector side are changed.

On the other hand, as shown in Fig. 52, when the marker MDV of the destination vector is picked up by the mouse 17, and the mouse 17 is operated in accordance with the cursor connecting the marker MDV and the origin, an arrow is displayed. As shown by (F4), the saturation degree of the destination vector is changed. Similarly, when the mouse 17 is operated according to the color ring Rl, as shown by the arrow F5, the marker MDV is maintained while the marker MDV and the markers M1 and M2 maintain a relative relationship. Change the color by and change the color of the destination vector correspondingly.

In addition, the central processing unit 11 determines the source vector and the destination when the source vector of the selected number is kept at the default value and when the source vector is reset to the default value by the operation of the default button B13. By setting the color, saturation, and luminance of the vector to match, the markers MSV to MW2 related to the source vector are displayed on the markers MDV to M2 related to the destination vector, above the display. In this way, when the mouse 17 is operated in the color distribution display unit D1 while the display of the color distribution display unit D1 is formed, the display of the marker related to the destination vector and the display of the marker related to the source vector are performed. In response to this operation of the mouse 17, the vertical relationship is sequentially switched cyclically. In addition, when the operation of the above-described parameter change mouse 17 is performed at the marker display point, the central processing unit 11 responds to the operation of the mouse 17 with respect to the marker displayed on the upper side. To change.

For this reason, in this editing apparatus 100, by the operation of the mouse 17 on the color distribution display part Dl, visually confirming the still object of a process object and a process result in the image confirmation part AR1, It is made to set various conditions of color correction processing.

When the editing operator executes the color correction process, after selecting this condition setting screen, as shown in FIG. 53, in step SP11, the color corrected from the still image displayed on the image confirming unit ARl is shown. And the color after the correction. Subsequently, it moves to step SP12 and selects the source vector of the number which was not yet selected by operation of the vector selection part AR3, and in step SP13, the original image in the image confirmation part AR1 ( On the secondary image), the mouse 17 clicks on the place to be corrected. Thereby, the position of the color corrected by display of the marker M in the color distribution display part D1 of the vector scope part AR2 is confirmed.

Subsequently, it moves to step SP14 and sets the range W of the source vector and the weighting function K (θ) so as to surround this marker M, and sets the gain by the operation of the vector parameter setting unit AR5. do. Subsequently, the process proceeds to step SP15, sets the destination vector for the color of the correction target, and then moves to step SP16 to determine whether the expected processing result has been obtained through the image confirming unit AR1. Determine whether or not. If a negative result is obtained here, the editing operator executes the operation of step SP17.

Here, the editing operator clicks again on the original image where the correction is desired to be corrected, if it is not corrected with the mouse 17. If the editing operator is corrected to the point where the correction is not desired, then again. The extra correction on the original image is clicked on with the mouse 17 to confirm the threshold of the range corrected by the display of the marker M on the color distribution display unit D1. This again changes the method of the marker for the source spectrum to change the parameters. On the other hand, in the case where it differs from a desired color, the marker regarding a destination vector, the gain G of the weighting function K ((theta)), the range W, etc. are changed.

When the gain and the like are finely adjusted in this way, the editing operator moves to step SP16 to determine whether or not the expected processing result is obtained again. As a result, the editing operator repeats the processing steps of steps SP16 and SP17 by operating the marker in the color distribution display unit D1 and by operating the button in the vector parameter setting unit AR5. Even when the colors of various original images are changed by high degrees of freedom, the desired processing can be executed by simple operation. When the expected processing result is obtained, the process moves from step SP16 to step SP18.

Here, the editing operator judges whether or not the color correction has been completed for all the desired places, and returns to step SP12 if a negative result is obtained here. As a result, the editing operator sets the source vector and the like again, changes the weighting function K (θ) and the like in various ways, and when the setting is completed for all desired places, the process moves from step SP18 to step SP19 to perform this processing. End the procedure.

In this manner, in the editing apparatus 100, the editing operator can set various processing conditions with high degrees of freedom by simple operation.

Claims (67)

In the color correction device for correcting a plurality of pixel colors constituting the source video image, Parameter setting means for setting a plurality of parameters for specifying a source color and a destination color, and correction data for color correction from the source color to the destination color using the plurality of parameters set by the parameter setting means. Calculation means for calculating, Storage means for storing correction data calculated by the calculation means; And color correction means for correcting the color of the pixel corresponding to the source color included in the source video image to the destination color using the correction data stored in the storage means. The color correction apparatus according to claim 1, wherein the calculation performed by said calculating means is performed by a software program, and the processing performed by said color correction means is performed by hardware. The color correction apparatus according to claim 1, wherein said storage means is a look-up table which adds and stores the color of said pixel and said correction data correspondingly. 2. The color compensator of claim 1, wherein the source color and the destination color are represented by a vector in a color space. The color correction apparatus according to claim 1, wherein said parameter setting means includes means for setting parameters relating to color angle and saturation as parameters relating to the source color and the destination color, respectively. 6. The apparatus according to claim 5, wherein said parameter setting means further comprises gain setting means for setting a parameter relating to a gain inch of said correction data, wherein said calculating means is adapted by said parameter setting means to determine the source color and destination color. And the correction data are calculated using the parameters relating to the color angle and the saturation set as parameters and the parameters relating to the gain inch set by the gain setting means. 6. The apparatus according to claim 5, wherein said parameter setting means further comprises color range setting means for setting a parameter relating to a color range of said source color, wherein said calculating means includes a color included in said source video image for said color range setting means. If it is within the color range set by, the data representing the color of the pixel, the parameter relating to the color angle and the saturation set as parameters of the source color and the destination color by the parameter setting means, and the gain setting means. And calculating the correction data by using the parameter relating to the gain inch set by. In the color correction device for correcting the color of the plurality of pixels constituting the source video image, Parameter setting means for setting a plurality of parameters for defining a source color range and a destination color range in a color space; Calculation means for calculating correction data for correcting a color included in the source color range to a color included in the destination color range, using a plurality of parameters set by the parameter setting means; When the color of the pixel constituting the source video image is a color included in the source color range, the color of the pixel is set to a color corresponding to the destination color range based on the correction data calculated by the calculating means. A color correction device having color correction means for correction. The color correction apparatus of claim 8, wherein the color direction of the source color range is defined as a source vector on a color space, and the color direction of the destination color range is defined as a destination vector on a color space. 9. The apparatus of claim 8, wherein the parameter setting means comprises a plurality of parameters for defining the source color range, means for setting at least a parameter relating to a source color direction, a source color range, and a source saturation; And a means for setting at least a parameter relating to a destination color direction and a destination saturation, as a plurality of parameters for specifying. 11. The apparatus according to claim 10, wherein said parameter setting means further comprises gain setting means for setting a parameter relating to a gain inch of said correction data, wherein said calculating means includes a source color direction and a source color range set by said parameter setting means. And the correction data is calculated using parameters relating to source saturation, parameters relating to destination color direction and destination saturation, and parameters relating to the gain inch set by the gain setting means. 12. The method of claim 11, wherein the gain setting means increases the gain inch as the color angle to be calculated is closer to the color direction of the color range, and the color angle to be calculated is farther from the color direction of the color range. And the get inch is set for each color so that the get inch becomes smaller as it increases. 12. The method of claim 10, wherein the calculating means increases the value of the correction data as the color angle to be calculated is closer to the color direction of the color range, and the color angle to be calculated is at the color direction of the color range. And calculating the correction data for each color such that the value of the correction data becomes smaller as the distance increases. The color of the pixel of claim 10, wherein the color correction means converts the color of the pixel into a color having a color angle closer to the destination color direction as the color angle of the pixel is closer to the source color direction. And the angle is away from the source color direction, the color of the pixel is converted into a color having a color angle closer to that of the pixel. 11. The apparatus of claim 10, wherein the calculating means comprises: a source algorithm for correcting a color of the pixel corresponding to the source color range to a color corresponding to the destination color range while maintaining the source saturation constant; Color correction, wherein the correction data is computed using a destination algorithm for correcting the color of the pixel corresponding to the source color range to a color corresponding to the destination color range while varying the saturation degree. Device. The color correction apparatus according to claim 10, comprising a computer including said parameter setting means and said calculating means, and an image processing unit including said color correction means. 17. The computer program product of claim 16, wherein the computer further comprises: a parameter setting window for interactively setting parameters relating to the source color direction, the source color range, the source saturation, the destination color direction, and the destination saturation; And a graphic interface configured to display on the computer monitor a graphical interface consisting of a video window before color correction processing and a view window for displaying the video image after color correction by means of the correction means. In the color correction method for correcting the color of the plurality of pixels constituting the source video image, Set a number of parameters to define the source and destination color ranges in the color space, Calculating correction data for correcting a color included in the source color range to a color included in the destination color range, When the color of the pixel constituting the source video image is a color included in the source color range, the color of the pixel is corrected to a color corresponding to the destination color range based on the correction data. Color correction method. 19. The apparatus according to claim 18, wherein at least a parameter relating to a source color direction, a source color range and a source saturation is set as a plurality of parameters for defining the source color range, And at least a parameter relating to a destination color direction and a destination saturation as a plurality of parameters for defining the destination color range. 20. The apparatus of claim 19, wherein a parameter relating to a gain inch of the correction data is set, and the parameter relating to the source color direction, the source color range, the source saturation, the destination color direction and the destination saturation, and the parameter relating to the gain are used. And calculating the correction data. 21. The method of claim 20, wherein the closer the color angle to be calculated to be closer to the color direction of the color range, the larger the gain inch, and the farther from the color direction of the color range to the color angle to be calculated. And the gain is set corresponding to each color angle so as to be smaller. 20. The method of claim 19, wherein the closer the color angle to be calculated is closer to the color direction of the color range, the larger the value of the correction data is, and the farther away from the color direction of the color range is to be calculated. And correcting the correction data for each color angle so that the value of the correction data becomes small. The method of claim 19, wherein the closer the color angle of the pixel is to the source color direction, the more the color of the pixel is converted to a color having a color angle closer to the destination color direction, wherein the color angle of the pixel is the source color. And a color angle of the pixel is converted into a color having a color angle closer to that of the pixel as the distance from the direction increases. 20. The method of claim 19, further comprising: a source algorithm for correcting a color of the pixel corresponding to the source color range to a color corresponding to the destination color range while maintaining the source saturation constant, and changing the source saturation rate. And calculating the correction data by selectively using a destination algorithm for correcting a color of the pixel corresponding to the source color range to a color corresponding to the destination color range. In the color correction device for correcting the color of the plurality of pixels constituting the source video image, Parameter setting means for setting a first to Nth source vector and a parameter relating to the first to Nth destination vectors respectively added to the first to Nth source vectors in the color space; From the first correction data for correcting the color represented by the first source vector to the color represented by the first destination vector, the color represented by the Nth source vector is defined by the Nth destination vector. Calculation means for calculating the comprehensive correction data based on the plurality of correction data up to the Nth correction data for correcting with the displayed color; When the color of the pixels constituting the source video image is the color on any one of the first to Nth source vectors, the color of the pixel is based on the comprehensive correction data calculated by the calculating means. And color correction means for correcting the color of the destination vector added to the source vector. The parameter setting means according to claim 25, wherein the parameter setting means sets a parameter relating to a first to Nth color window for indicating a color range of the source vector, and a parameter relating to a gain inch of the first to Nth correction data. And means for setting each of the first to Nth source vectors, respectively. 27. The apparatus of claim 26, wherein the calculating means comprises: the first to Nth source vectors, the first to Nth destination vectors, the first to Nth color windows, and the first to Nth correction data. And calculating the comprehensive correction data based on a parameter relating to a gain inch. 27. The method of claim 26, wherein the parameter setting means makes the gain inch larger as the color angle to be calculated becomes closer to the source vector and decreases the gain inch as the color angle to be calculated becomes farther from the source vector. Color setting device, characterized in that for setting the parameters relating to the gain for each color. 27. The method of claim 26, wherein the calculating means increases the value of each correction data as the color angle to be calculated is closer to the source vector, and the angle correction data as the color angle to be calculated is farther from the source vector. Color correction apparatus for calculating the correction data according to the distance to the source vector so that the value of. 27. The method of claim 26, wherein the color correction means converts the color of the pixel into a color having a color angle closer to the destination vector as the color angle of the pixel is closer to the source vector. And the color of the pixel is converted into a color having a color angle closer to that of the pixel as the distance from the source vector increases. 27. The apparatus of claim 26, wherein the calculating means comprises: a first algorithm for correcting the pixel color corresponding to the first color range to a color corresponding to the second color range while keeping the source vector constant; Calculating the correction data by selectively using a second algorithm for correcting a color of the pixel corresponding to the first color range to a color corresponding to the second color range while changing a source vector Color Corrector. 27. The color correction apparatus according to claim 26, comprising a computer including said parameter setting means and said calculating means, and an image processing unit including said color correction means. 33. The computer-readable medium of claim 32, wherein the computer further comprises: a parameter setting window for interactively setting the color range of the source vector and the destination vector, a video image before color correction processing by the color correction means, and color corrected. And a graphical interface configured to display on a computer monitor a graphical interface comprising a view window for displaying a later video image. In the color correction method for correcting a plurality of pixel colors constituting the source video image, In the color space, parameters for the first to Nth source vectors and the first to Nth destination vectors respectively added to the first to Nth source vectors respectively are set. From the first correction data for correcting the color represented by the first source vector to the color represented by the first destination vector, the color represented by the Nth source vector is defined by the Nth destination vector. Comprehensive correction data is calculated on the basis of the plurality of correction data up to the Nth correction data for correcting with the appearing color, When the color of a pixel constituting the source video image is a color on any one of the first to Nth source vectors, the color of the pixel is added correspondingly to the source vector based on the comprehensive correction data. Color correction method characterized by correcting the color of the destination vector. 35. The method according to claim 34, wherein the parameters relating to the first to Nth color windows for indicating the color range of the source vector, and the parameters relating to the gain inch of the first to Nth correction data are determined from the first to the first. And setting in correspondence to the Nth source vector. 36. The method of claim 35, wherein the first to Nth source vectors, the first to Nth destination vectors, the first to Nth color windows, and the first to Nth correction data are obtained in inches. And calculating the comprehensive correction data based on the relevant parameters. 36. The method according to claim 35, wherein the gain inch becomes larger as the color angle to be calculated becomes closer to the source vector, and the gain inch becomes smaller as the color angle to be calculated becomes farther from the source vector. A color correction method comprising setting a parameter for each color angle. 36. The method of claim 35, wherein the value of each correction data increases as the color angle to be calculated is closer to the source vector, and the value of each correction data is smaller as the color angle to be calculated is farther from the source vector. Calculating correction data according to the distance from the source vector. 36. The method of claim 35, wherein the closer the color angle of the pixel is to the source vector, the color of the pixel is converted to a color having a color angle closer to the destination vector, so that the color angle of the pixel is farther from the source vector. And converting the color of the pixel into a color having a color angle closer to that of the pixel. 36. The method of claim 35, further comprising: a first algorithm for correcting a color of the pixel corresponding to the first color range to a color corresponding to the second color range while keeping the source vector constant; Varying, and calculating the correction data by selectively using a second algorithm for correcting the color of the pixel corresponding to the first color range to the color corresponding to the second color range. . In the color correction device for correcting the color of the plurality of pixels constituting the source video image, Means for vector designating a plurality of source vectors and a plurality of destination vectors added to each of the plurality of source vectors in a color space; Calculating means for calculating comprehensive correction data for correcting the colors on the plurality of source vectors with the colors of the plurality of destination vectors added to the plurality of source vectors, respectively; When the color of the pixels constituting the source video image is a color on any one of the plurality of source vectors, the color of the pixel is added to the source vector based on the comprehensive correction data. And a color correction means for correcting the color of the nation vector. Data correction means having a look-up table and correcting and outputting the input data by the look-up table; Table updating means for updating the contents of the lookup table, And the lookup table holds data corresponding to a color difference signal of an image signal. 43. The apparatus of claim 42, wherein the data correction means has polar coordinate conversion means for converting the color difference signal into polar coordinates and generating angle data corresponding to the color difference signal with reference to a predetermined reference axis, wherein the lookup table includes the angle And outputting data in which data is held as an address. The image processing apparatus according to claim 42, wherein the polar coordinate converting means outputs the angle data by the number of bits larger than the color difference signal. 43. The apparatus of claim 42, wherein the lookup table outputs correction data for correcting the image signal by using color data of the image signal as an address. The data correction means includes polar coordinate conversion means for polarizing the color difference signal and outputting data of the color of the color difference signal to the lookup table; And arithmetic processing means for correcting said chrominance signal by said correction data. 43. The apparatus of claim 42, wherein the lookup table outputs correction data for correcting color and saturation of the video signal by using the data of the color of the video signal as an address. The data correction means comprises polar coordinate conversion means for polarizing the color difference signal and outputting data of the color of the color difference signal to the lookup table; And arithmetic processing means for correcting said chrominance signal by said correction data. 43. The apparatus of claim 42, wherein the lookup table outputs correction data for correcting luminance and color of the image signal by using color data of the image signal as an address. The data correction means comprises polar coordinate conversion means for polarizing the color difference signal and outputting color data of the color difference signal to the lookup table; And arithmetic processing means for correcting said chrominance signal by said correction data. 43. The apparatus according to claim 42, wherein the table updating means has input means for inputting at least a color of a processing target and a color of a processing target, and data generating means for generating data stored in the lookup table, The data generating means generates data for storing in the lookup table to correct the color of the processing target in the video signal to the color of the processing target based on the color of the processing target and the color of the processing target. An image processing apparatus, characterized in that. 43. The apparatus according to claim 42, wherein the table updating means has input means for inputting at least a color and saturation degree of a processing target and a color and saturation degree of a processing target, and data generating means for generating data to be stored in the lookup table, The data generating means is configured to correct the color and saturation of the processing target in the video signal to the color and saturation of the processing target based on the color and saturation of the processing target and the color and saturation of the processing target. And image data stored in a lookup table. 43. The apparatus according to claim 42, wherein the table updating means has input means for inputting at least a range of a processing target, and data generating means for generating data stored in the lookup table, Wherein said data generating means adds a correction value by a weighting function maintained at a valid value in the range of said processing target to generate data for storing in said lookup table to correct the color of said processing target with the color of the processing target. An image processing apparatus. 43. The apparatus according to claim 42, wherein the table updating means has input means for inputting at least a degree of processing, and data generating means for generating data stored in the lookup table, And said data generating means generates data for storing in said lookup table so as to correct a color of said processing target to a color of a processing target by weighting a correction value by a predetermined function. 43. The apparatus according to claim 42, wherein the table updating means has input means for inputting a plurality of sets of at least a color of a processing target and a color of a processing target, and data generating means for generating data stored in the lookup table, The data generating means generates correction data so as to correct the color of the processing target with the color of the processing target with respect to each pair of the color of the processing target and the color of the processing target, and aggregates the correction data of the respective sets into the lookup table. An image processing apparatus characterized by generating data to be stored. First data correction means having a first lookup table and correcting and outputting the input data by the first lookup table; Second data correction means having a second lookup table and correcting and outputting the input data by the second lookup table; Table updating means for updating contents of the first and second lookup tables, And the first lookup table holds data corresponding to a luminance level of an image signal, and the second lookup table holds data corresponding to a color difference signal of an image signal. In the image processing apparatus for correcting the color of the processing target image, Color correction means for weighting a predetermined correction value by a weighting function maintained at a valid value in a range based on a predetermined reference color, and correcting the color of each pixel of the processing target image to a color of a processing target; Image display means for displaying a color distribution image that projects the pixels of the processing target image represented by the three-dimensional color space onto a u v plane; And updating processing means for changing a condition for correcting the color by designation on the color distribution image. A condition according to claim 54, wherein said updating processing means displays the range of correction by said weighting function as said color distribution image, and corrects said color by changing said range of correction by designation on said color distribution image. The image processing apparatus, characterized in that for changing. The image processing apparatus according to claim 55, wherein the update processing unit accepts designation of a pixel on the processing target image, and displays a marker on the color distribution image at a location corresponding to the received pixel. 55. The apparatus according to claim 54, wherein said updating processing means displays said reference color on said color distribution image, and changes the condition for correcting said color by changing said reference color by designation on said color distribution image. An image processing apparatus. The image processing apparatus according to claim 57, wherein said update processing means accepts a designation of a pixel on said processing target image and displays a marker in the color distribution image corresponding to the received pixel. 55. The apparatus according to claim 54, wherein said update processing means displays the correction target color corresponding to said reference color as said color distribution image, and changes said correction amount by changing the color of said correction target by designation on said color distribution image. And changing a condition for correcting the color. 60. The image processing apparatus according to claim 59, wherein the update processing unit accepts designation of pixels on the processing target image, and displays a marker on the color distribution image display in a place corresponding to the received pixel. In the image processing method for correcting the color of the processing target image, A predetermined correction value is given by a weighting function maintained at a valid value in a range based on a predetermined reference color to correct the color of each pixel of the processing target image to the color of the processing target, Displaying a color distribution image formed by projecting pixels of the processing target image represented by a three-dimensional color space onto an uv plane, And a condition for correcting the color by designation on the color distribution image. 62. The apparatus according to claim 61, wherein a range of correction by said weighting function is displayed on said color distribution image, And a condition for correcting the color by changing the range of correction by designation on the color distribution image. 63. The apparatus according to claim 62, wherein the designation of pixels is accepted on the processing target image, And a marker is displayed in the color distribution image corresponding to the received pixel. 62. The apparatus of claim 61, wherein the reference color is displayed on the color distribution image, And the condition for correcting the color by changing the reference color by designation on the color distribution image. 62. The image processing method according to claim 61, wherein designation of a pixel is accepted on the processing target image, and a marker is displayed in the color distribution image corresponding to the received pixel. 63. The method of claim 61, wherein the color of the correction target corresponding to the reference color is displayed on the color distribution image, And a condition for correcting the color by changing the color of the correction target by changing the color on the color distribution image and changing the correction amount. 67. The apparatus according to claim 66, wherein designation of a pixel is accepted on the processing target image; And a marker is displayed in the color distribution image corresponding to the received pixel.