KR101807820B1 - Method and apparatus for quantifying perceived intensity of color moires - Google Patents

Abstract

In order to allow a processor to quantify the recognition intensity of color moire generated in a three-dimensional image display device, it calculates the period of the color moire formed as the pattern of a first linear grating by the pixel of a display panel overlaps the pattern of a second linear grating by a viewing zone forming optics, calculates the relative brightness of a color-changed image which causes the color moire for the entire image within the period, calculates the brightness decrease rate of the image within the period, and then quantifies the perceived intensity of the color moire by using the relative brightness of the color-changed image and the brightness decrease rate of the image.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a method and an apparatus for quantizing color moiré recognition intensity,

The present invention relates to a method and an apparatus for quantifying a color moiré recognition intensity, and more particularly, to a three-dimensional image display apparatus for creating viewing zone forming optics by superimposing a viewing zone forming optics on an image panel, The present invention relates to a method and an apparatus for quantifying the visual perception intensity of a color moire that is naturally formed by superposition of panels based on brightness of an image.

The moire is a mixture of lines that make up one pattern and lines that make up another pattern when mixed with two periodic patterns in a single pattern, dense and sparse) are periodically formed.

Generally, in a contact type three-dimensional image display apparatus, an optical plate for viewing zone forming, that is, an optical plate for forming a field of view is superimposed on a display panel, A moiré is formed when a lens or a slit forms an equivalent periodic linear grating pattern and pixels of the display panel form a two-dimensional linear grating pattern.

However, since each pixel of the display panel is composed of three sub-pixels displaying red (R), green (G) and blue (B) colors, To be a color moiré.

Since a color moiré has a linear lattice pattern narrower than a line width such as a lenticular lens, since the image itself is bright, the relative brightness of the display image of the color moiré to the entire image is low, The recognition strength of color moiré is low. However, in the case of a linear lattice pattern in which the line width is equal to the period of the color moiré, such as the parallax barrier plate, the brightness of the image itself is dark, but the relative brightness of the display image of the color moiré is high The recognition strength of color moiré is high.

Such color moiré is a major factor for lowering the image quality of a contact type three-dimensional image display device.

However, since the color moiré is generated not only by the periodicity of the pattern formed by the display panel and the viewing area optical plate but also by the two-dimensional linear lattice formed by the pixels constituting the display panel, the color moiré Removal is not possible.

On the other hand, it is possible to minimize the recognition intensity of the color moiré by adjusting the overlapping angle, adjusting the moiré period, or using a diffuser plate. However, in order to classify the degree of minimization, it is necessary to quantify the recognition strength of the moiré .

In addition, when minimizing the moiré using the overlap angle or the maximization of the period, it is necessary to set the allowable limit of the moiré in order to minimize the interference noise, because these methods cause interference noise Do. This tolerance may vary depending on the observer, but can be defined through quantification of the moire.

The quantification of the color moiré enables quantification of the image quality of the contact type three-dimensional image display device, so that it is possible to standardize the three-dimensional image display device by comparing the relative image quality of the image display device and standardizing the image quality.

Despite this importance, quantitative methods of color moiré have not been developed so far.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a color moiré recognition intensity quantification method and apparatus capable of quantifying the recognition intensity of a color moiré.

According to one embodiment of the present invention, a method is provided for quantifying the perceived intensity of a color moiré occurring in a three-dimensional image display at a processor. Calculating a period of color moiré which is formed as a pattern of the first linear grating by the pixels of the display panel overlaps with a pattern of the second linear grating by the optical axis forming optical plate, Calculating a relative brightness of an image in which a hue change caused by a color moiré of a whole image is calculated, calculating a rate of decrease in brightness of the image within the period, and calculating a relative brightness of the hue, And quantifying the recognition intensity of the color moiré using the rate of decrease.

The step of calculating the relative brightness of the color-changed image may include calculating a width of an image in which the hue causing the color moiré is changed within the period, and excluding the line width of the second linear grid pattern within the period And calculating the width of the entire image.

The width of the entire image may be calculated by subtracting a value obtained by multiplying the line width by the line number of the second linear grid in the period in the pixel width of the period.

The width of the image in which the hue is changed may be calculated from the sum of the values obtained by subtracting the line width by the second linear grid from the width of each pixel whose hue is changed within the period.

The step of calculating the rate of decrease in brightness may include calculating the rate of decrease in brightness using the number of lines and the line width of the second linear grid in the period.

The brightness reduction rate may be calculated as a value obtained by multiplying the line number by the second linear grid within the period by the line width, and dividing the value by the pixel width of the period.

The recognition strength of the color moiré may be calculated from the product of the relative brightness of the image in which the hue is changed and the rate of decrease in brightness of the image.

The recognition strength of the color moiré may be calculated from the product of the relative brightness of the image in which the hue is changed and the rate of decrease in brightness of the image.

The step of calculating the period of the color moiré may include calculating the repeatability of the color using the number of lines of the second grid pattern.

The viewing area forming optical plate may include one of a parallax barrier, a lenticular lens array, and a microlens array.

The recognition strength may be a value between 0 and 1.

According to another embodiment of the present invention, there is provided an apparatus for quantifying a recognition strength of a color moire occurring in a three-dimensional image display apparatus. The color moire recognition intensity quantification device may include a processor and a memory. The processor calculates the period of the color moiré which is formed as the pattern of the first linear grating by the pixels of the display panel and the pattern of the second linear grating by the optical system for visual field forming overlap, The relative brightness of the image in which the color caused by the color moiré is changed and the rate of decrease in brightness of the image within the period are calculated and the recognition intensity of the color moiré using the relative brightness of the changed image and the rate of decrease in brightness of the image Quantitatively. And the memory stores instructions for performing quantification of the recognition strength of the color moiré in the processor.

The processor may calculate the relative brightness by dividing the pixel width of the hue changed image by the pixel width of the entire image.

Wherein the processor calculates a pixel width of the entire image from a value obtained by multiplying a line number by the second linear grid in the period by a pixel width of the period minus a value obtained by multiplying the line number by the line width, A value obtained by subtracting the line width by the second linear grid from the width of each pixel is calculated, and then the pixel width of the image whose color is changed from the sum of the obtained values can be calculated.

The processor may calculate the brightness reduction rate from a value obtained by multiplying the line number by the second linear grid in the period by the line width divided by the pixel width of the period.

The processor may calculate the recognition strength of the color moiré from the product of the relative brightness of the image with the hue changed and the rate of brightness decrease of the image.

The processor may quantify the recognition strength to a value between 0 and 1.

The viewing area forming optical plate may include one of a parallax barrier, a lenticular lens array, and a microlens array.

According to the embodiment of the present invention, it is possible to provide a basis for quantifying the image quality of the image display device through quantification of the moiré which has the greatest influence on the image quality of the contact type three-dimensional image display device. In addition, since quantization of color moiré enables quantification of the image quality of the contact type three-dimensional display device, it is possible to standardize the three-dimensional display device by comparing the relative image quality of the three-dimensional display device and image quality standardization.

1 is a view illustrating an example of a three-dimensional image display apparatus to which the present invention is applied.
2 is a view showing an example of a linear grid pattern of an optical plate for field-of-view formation according to an embodiment of the present invention.
3 and 4 are views for explaining the principle of generating a color moiré in a three-dimensional image display apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating a method of quantifying recognition strength of color moiré according to an embodiment of the present invention.
Figs. 6 and 7 are diagrams for explaining the color moiré recognition intensity in the case where the line width of the linear lattice formed by the optical axis for forming the field of view according to the embodiment of the present invention is different from Fig.
8 is a diagram illustrating an apparatus for quantifying the recognition strength of a color moiré according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects,

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification and claims, when a section is referred to as "including " an element, it is understood that it does not exclude other elements, but may include other elements, unless specifically stated otherwise.

Now, a method and an apparatus for quantifying color moiré recognition intensity according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a view illustrating an example of a three-dimensional image display apparatus to which the present invention is applied.

1, a three-dimensional image display apparatus 10 according to a parallax barrier system includes a display panel 100 and a parallax barrier 20 disposed on the front surface of the display panel 100. As shown in Fig.

The display panel 100 includes a plurality of pixels arranged in a plurality of rows and a plurality of columns. Each pixel includes a plurality of sub-pixels. The sub-pixel displays, for example, any one of red (R), green (G) and blue (B) colors. Pixel is a minimum image display unit in which at least one sub-pixel is combined to express complete color information. For example, three sub-pixels each displaying red (R), green (G) and blue (B) Pixel.

The parallax barrier 20 selectively transmits an image of a multi-point barrier to form a parallax barrier so that different images can be seen in both eyes of the observer. To this end, the parallax barrier 20 includes a plurality of light-transmitting slits 110 and a plurality of light-shielding slits 120 corresponding to the plurality of pixels of the display panel 100, respectively.

The parallax barrier 20 may include a transparent substrate 130 and a barrier pattern 125 formed on the transparent substrate 130. At this time, the portion where the barrier pattern is formed constitutes the light-shielding slit 120, and the portion where the barrier pattern 125 is not formed constitutes the light-transmitting slit 110. The parallax barrier 20 is fixed to the front surface of the display panel 100 by the adhesive layer 140.

Alternatively, the lenticular-type three-dimensional image display device may be replaced with a parallax barrier 20 by a lenticular lens array.

In the case of the parallax barrier 20, the boundary line separating the light-transmitting slits 110 is formed at the boundary of the display panel 100 Shielding slit 120 corresponding to a non-transparent portion which hardly transmits the image of the light-shielding slit 120. The width of the light-shielding slit 120 corresponds to 2/3 to 3/4 of one barrier pattern period .

Therefore, it can be seen that the optical plate for viewing area formation has a linear grid pattern of one-dimensional or two-dimensional arrangement of equivalent periodic straight lines.

In general, a moiré is a periodic pattern created when another periodic pattern is superimposed on one periodic pattern. When superimposed, the two patterns are mixed and appear as one pattern. Depending on the periodicity of the lines constituting each pattern, the densities of the lines constituting the mixed pattern periodically appear.

1, a parallax barrier 20, a lenticular lens array, or an optical plate for a field of view formation such as a two-dimensional microlens array is placed on a display panel 100 in a three-dimensional image display device 10, Since the optical elements such as the lenses and the slits arranged in the optical axis forming optical plate form an equivalent periodic linear lattice pattern and the pixels of the display panel 100 form a two dimensional linear lattice pattern, Are overlapped to form a moiré.

In the three-dimensional image display apparatus 10, the color moiré is projected through the viewing zone forming optical plate by partially obscuring the pixels of the lower display panel 100 by the linear grid pattern of the viewing zone forming optical plate located at the upper part The color of the image is different from the color of the actual image, and the variation of the color is periodically repeated.

The line width of the linear grating is very narrow in the case of the lenticular lens and the microlens, and is wide in the case of the parallax barrier 20. If the viewing zone forming optical plate is overlapped on the display panel 100, the portion corresponding to the line width of the linear grid is hidden from the pixels of the display panel, and the pixel of the display panel 100 is visible only through the transparent portion between the lines do. Therefore, the brightness of the image is reduced by the ratio of the line width to the period of the linear lattice pattern.

If the width of the transparent portion of the linear grid is larger or smaller than the integer multiple of the pixel, a part of the pixel is obscured or viewed. Therefore, the color of the pixel is the color of the original image . This is given as a color moiré.

Therefore, a moiré is a part of a panel image that is transmitted through an optical plate for viewing area formation, which is an image that can not be separated from an image.

2 is a view showing an example of a linear grid pattern of an optical plate for field-of-view formation according to an embodiment of the present invention.

2, patterns of various linear gratings G1, G2, G3, G4 and G5 can be formed by arranging the lenses or slits arranged in the viewing zone optical plate.

For example, the period of the grating may be T1, and the pattern of the linear gratings G1 to G5 may be formed in which the line widths of the gratings are D1 to D5, respectively.

The line widths D1 to D5 of the linear gratings G1 to G5 can be determined according to the structural characteristics of the optical elements of the viewing zone optical plate.

3 and 4 are views for explaining the principle of generating a color moiré in a three-dimensional image display apparatus according to an embodiment of the present invention.

3, the display panel 3 includes pixels 2, 3, 4, 5, 6 each composed of three sub-pixels 4, 5, 6 for displaying red (R), green (G) All the pixels of the display panel 3 display white (9).

If the pattern of the linear grid G1 formed by the viewing zone optical plate on the display panel 3 shown in Fig. 3 is superimposed, the display panel 3 is displayed as shown in Fig. If the width 1 of one pixel 2 is 3/5 of the lattice period T1 and the line width D1 of the lattice is 1/6 of the width 1 of the pixel, D1) is 1/2 of the width of the sub-pixel.

When the pattern of the linear grid G1 is superposed on the display panel 3, the line width D1 of the grid hits one half of one sub-pixel. The brightness of the sub-pixel obscured by the line width D1 of the grating falls to 1/2. Pixels including the green subpixel 11, the red subpixel 13 and the blue subpixel 15 whose half of one subpixel is masked by the line width D1 of the lattice are respectively connected to the light purple 12, , A light blue 14 and a soft yellow 16, while the uncovered pixel 7 represents a white 17.

As described above, the pixels whose hue is changed are centered on the lines constituting the lattice, and the colors of some pixels are changed to the light purple 12, the soft blue 14 and the soft yellow 16 by the overlap of the grid G1 . A new color pattern 18 is formed in which the change of the color is periodically repeated.

The new color pattern 18 includes a lightened purple 12, a white 17 and a lattice G1 in which the white 17 and the line width D1 of the original image are overlapped and the color is changed, The line width D1 of the grid G1 is overlapped with the color of the soft blue 14 and the line width D1 of the grid G1 is overlapped and the color is changed.

Thus, a periodic change in color forms a color moiré, and a repeated combination of changed colors is a period (T2) of the color moiré. That is, the color moiré refers to an image of a pixel whose color changes periodically.

The period T2 of the color moiré can be easily obtained by using color repetition by counting line numbers of the lattice pattern and can be obtained formally by a more complex pattern.

FIG. 5 is a flowchart illustrating a method of quantifying a recognition strength of a color moire according to an embodiment of the present invention, and a recognition intensity quantification method based on the color moire shown in FIG. 4 will be described.

Referring to FIG. 5, when a color moiré is formed as a result of superimposing a linear lattice pattern by pixels of a display panel and a linear lattice pattern by an optical plate for viewing area formation (S500) The period T2 is calculated (S510). Referring to FIG. 4, since there are fifteen sub-pixels in the period T2 of the color moiré, the period T2 of the color moiré corresponds to the width corresponding to five pixels.

The apparatus for quantifying the recognition strength of the color moiré calculates the width and the number of lattices of the pixels within the period (T2) of the color moiré (S520). 4, there are three lines having a line width D1 within the period T2 of the color moiré, two pixels representing white and a light purple 12 portion corresponding to 5/6 of one pixel width, A light blue (14) portion, and a light yellow (16) portion.

Next, the apparatus for quantifying the recognition strength of color moiré calculates the relative brightness B0 of the changed image causing the color moire for the entire image using the width and the number of lattices of the pixel within the period T2 of the color moire (S530 ). The relative brightness (B0) of the color moiré for the entire image can be calculated as shown in Equation (1).

At this time, the width of the entire image can be calculated as shown in Equation (2). That is, the width B1 of the entire image can be calculated by excluding the line width D1 by three lines within one period T2 of the color moiré.

Here, C represents the pixel width in the cycle of the color moiré, and is the number of pixels included in the main color moiré. N represents the number of lattices in the period (T2) of the color moiré, and M represents the line width of the lattice.

The width B2 of the changed image caused by the color moiré can be calculated from the sum of the values obtained after excluding the line width by the grid G2 from the width of each pixel whose hue is changed. For example, if the linewidths of the grid G2 included in the pixels having the changed hue are all the same as shown in Fig. 4, the width B2 of the changed image causing the color moire can be calculated as shown in Equation (3) .

4, there are three gratings having a line width D2 in the period T2 of the color moiré, the line width of the grating corresponds to 1/6 of the pixel width, and the period of the color moiré is 5 pixels Width. That is, since C = 5, N = 3, and M = 1/6, the width of the entire image is 4.5 [= 5- (3 x (1/6))] pixels as shown in Equation 3.

In the period (T2) of the color moiré, there are two pixels representing white and a light purple (12) portion, a light blue (14) portion and a pale yellow (16) portion corresponding to 5/6 of a pixel width .

Therefore, the width of the changed image which caused color moire has a width of 2.5 [= (5/6) x 3] pixels.

Therefore, the relative brightness (B0) of the changed image that caused the color moire for the entire image can be calculated as 5/9 [= 2.5 / 4.5].

Next, the apparatus for quantifying the cognitive intensity of color moiré calculates the brightness decrease rate D of the image within the period (T2) of the color moiré (S540). The brightness decrease rate D of the image within the period T2 of the color moiré may be calculated as shown in Equation 4. " (4) "

4, the brightness decrease rate D of the image in the cycle T2 of the color moiré is 1/10 [= (3 x (1/6)) / 5].

The recognition intensity intensity of the color moiré is calculated by using the relative brightness (B0) of the changed image causing the color moire of the whole image and the brightness decrease rate (D) of the image within the period of the color moire (D) P) (S550). The recognition strength P of the color moiré can be calculated as shown in Equation (5).

When the recognition intensity P of the color moiré is calculated in this way, the recognition intensity P of the color moiré shown in Fig. 4 becomes 1/18 (= 5/9 x 1/10).

Figs. 6 and 7 are diagrams for explaining the color moiré recognition intensity in the case where the line width of the linear lattice formed by the optical axis for forming the field of view according to the embodiment of the present invention is different from Fig.

Referring to Fig. 6, when the pattern of the linear grid G2 formed by the viewing zone optical plate on the display panel 3 shown in Fig. 3 is superimposed, color moiré is formed on the display panel 3. Fig. If the width 1 of one pixel 2 is 3/5 of the lattice period T1 and the line width D2 of the lattice is 1/3 of the width 1 of the pixel, D2 are the widths of one sub-pixel.

When the pattern of the linear grid G2 is superposed on the display panel 3, one subpixel is covered by the line width D2 of the grid. Pixels covered with the green subpixel, the red subpixel, and the blue subpixel due to the line width D2 of the lattice represent purple, sky blue, and yellow, respectively, and pixels not covered by the line width D2 of the lattice represent white.

As described above, the pixels whose hue is changed are centered on the lines constituting the lattice, and the colors of some pixels are changed into purple, sky blue and yellow by overlapping of the grid G2, A color pattern 28 is formed. This periodic color change forms a color moiré.

At this time, the period T3 of the color moiré corresponds to five pixel widths, the line width D2 of the lattice is one-third pixel width, and the number of lattices in the color moiré period T3 is three. And the changed image resulting in color moiré are purple, light blue and yellow portions corresponding to a pixel width of 2/3 of the color moiré period (T3).

Therefore, the width B1 of the entire image is 4 (= 5- (3 x 1/3)) pixel width, and the width B2 of the changed image causing color moire is 2 (= (1-1 / 3 ) X 3) pixel width. Accordingly, the relative brightness B0 of the color moiré to the whole image becomes 1/2 (= 2/4). The recognition intensity of the color moiré due to the overlapping of the grid G2 is 1/10 (= 1/2 X 1/3) / 5, 5).

7, a color moiré is formed on the display panel 3 when the pattern of the linear grid G4 formed by the viewing zone optical plate is superimposed on the display panel 3 shown in Fig. 3 . At this time, if the width 1 of one pixel 2 is 3/5 of the lattice period T1 and the line width D4 of the lattice is 2/3 of the width 1 of the pixel, D2 are two sub-pixel widths.

When the pattern of the linear grid G4 is superposed on the display panel 3, two sub-pixels are obscured by the line width D4 of the grid. A new color pattern 38 is formed by the line width D4 of the lattice as shown in Fig. This periodic color change forms a color moiré.

At this time, the period T4 of the color moiré corresponds to five pixel widths, the line width D4 of the lattice is 2/3 pixel width, and the number of lattices in the color moiré period T4 is three. The changed image resulting from the color moiré is a blue color corresponding to a pixel width of 2/3 in the color moiré period (T4), a red color (R) corresponding to a 1/3 pixel width, a blue color corresponding to a 1/3 pixel width B) and a yellow portion corresponding to 2/3 pixel width.

Therefore, the width B1 of the entire image is 3 (= 5 - ((1/3) 2 + (2/3) 2) pixel width, and the width B2 of the changed image, Becomes 2 (= ((1 / 3x2) + (2 / 3x2))) pixel width. Therefore, the relative brightness (B0) of the color moiré to the entire image is 2/3. (= 3 x (2/3)) / 5), the intensity of recognition of the color moiré by the superposition of the grating G4 is 4/15 (= 2/3 x 2 / 5).

As described above, the recognition strength of the color moiré increases as the line width of the linear grating formed by the optical plate for viewing area formation increases, and can be numerically expressed as a value between 0 and 1 by the method according to the embodiment of the present invention.

8 is a diagram illustrating an apparatus for quantifying the recognition strength of a color moiré according to an embodiment of the present invention.

8, an apparatus 800 for quantifying the recognition strength of a color moiré includes a processor 810, an input / output interface 820, and a memory 830.

When the color moiré is formed as a result of superimposing the linear grid pattern by the pixels of the display panel and the linear grid pattern by the optical plate for the field of view formation, the processor 810 determines that the recognition intensity of the color moiré The recognition intensity of the color moiré is calculated. Such a processor 810 may refer to a central processing unit (CPU), a graphics processing unit (GPU), or a dedicated processor on which methods in accordance with embodiments of the present invention are performed.

The input / output interface 820 is connected to the processor 810 and can communicate with the outside. For example, information about the width of a pixel, the period of the linear grid by the optical plate for forming the field of view, and the like can be inputted through the input / output interface 820.

The memory 830 stores instructions for performing operations in the processor 810 or temporarily loads and stores instructions from a storage device (not shown), and the processor 810 is stored in the memory 830 Execute the loaded command.

The embodiments of the present invention are not limited to the above-described apparatuses and / or methods, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, Such an embodiment can be readily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (18)

A method for quantifying the perceived intensity of a color moire occurring in a three-dimensional image display device in a processor,
Calculating a period of color moiré formed as a pattern of the first linear grating by the pixels of the display panel overlaps with a pattern of the second linear grating by the optical axis for forming the field of view,
Calculating a relative brightness of an image in which a hue causing a color moire for the entire image has changed in the period,
Calculating a rate of brightness decrease of the image within the period, and
Quantifying the recognition intensity of the color moiré using the relative brightness of the image of which the hue is changed and the rate of decrease of brightness of the image
/ RTI > wherein the color moiré recognition intensity is calculated using the color moiré recognition intensity. The method of claim 1,
The step of calculating the relative brightness of the hue-
Calculating a width of a color-changed image caused by the color moiré within the period, and
And calculating a width of the entire image by excluding a line width of the second linear grid pattern within the period. 3. The method of claim 2,
Wherein the width of the entire image is calculated by subtracting a value obtained by multiplying a line width by a line number by the second linear grid in the period in a pixel width of the period. 3. The method of claim 2,
Wherein the width of the image of which the hue is changed is obtained by subtracting the line width by the second linear grid from the width of each pixel whose hue is changed within the period, and then calculating the color moire recognition intensity from the sum of the obtained values . The method of claim 1,
Wherein the step of calculating the brightness reduction rate comprises calculating the brightness reduction rate using the number of lines and the line width by the second linear grid in the period. The method of claim 5,
Wherein the brightness reduction rate is calculated by multiplying a line number by the second linear grid in the period by a line width, and dividing the value by a pixel width of the period. The method of claim 1,
Wherein the recognition strength of the color moiré is calculated from a product of a relative brightness of the image in which the hue is changed and a rate of decrease in brightness of the image. delete The method of claim 1,
Wherein calculating the period of the color moiré comprises calculating the repeatability of the color using the number of lines of the pattern of the second linear grating. The method of claim 1,
Wherein the field plate forming optical plate includes one of a parallax barrier, a lenticular lens array, and a microlens array. The method of claim 1,
Wherein the recognition intensity is a value between 0 and 1. An apparatus for quantifying the recognition strength of a color moire occurring in a three-dimensional image display apparatus,
The period of the color moiré formed as the pattern of the first linear lattice by the pixels of the display panel and the pattern of the second linear lattice by the optical axis of the visual field forming optical sheet are overlapped and the color moiré And calculating a rate of decrease in brightness of the image within the period and quantifying the intensity of recognition of the color moiré using the relative brightness of the changed image and the rate of decrease in brightness of the image, , And
A memory for storing instructions for performing quantization of the recognition strength of the color moiré in the processor,
And a color moiré recognition intensity meter. The method of claim 12,
Wherein the processor calculates the relative brightness by dividing the pixel width of the color-changed image by the pixel width of the entire image. The method of claim 13,
Wherein the processor calculates a pixel width of the entire image from a value obtained by multiplying a line number by the second linear grid in the period by a pixel width of the period minus a value obtained by multiplying the line number by the line width, Calculating a width of each pixel excluding a line width by the second linear grid, and calculating a pixel width of the image whose color is changed from a sum of the obtained values. The method of claim 12,
Wherein the processor calculates the brightness reduction rate from a value obtained by multiplying a line number by the second linear grid in the period by a line width and a pixel width of the period. The method of claim 12,
Wherein the processor calculates the recognition intensity of the color moiré from the product of the relative brightness of the hue changed image and the brightness decrease rate of the image. The method of claim 12,
Wherein the processor quantifies the recognition intensity to a value between 0 and 1. The method of claim 12,
Wherein the viewing area forming optical plate includes one of a parallax barrier, a lenticular lens array, and a microlens array.

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