KR20160098009A - Apparatus and method for reducing moire fringe - Google Patents

Abstract

Provided are a method for reducing moire fringe and an apparatus for performing the same. The method for reducing the moire fringe comprises the following steps of: measuring the width of the moire fringe for each of different inclined angles between a microlens array and a pixel of a display screen; and determining, to be a final inclined angle between the microlens array and the pixel of the display screen, the inclined angle corresponding to the minimum width among the measured widths of the moire fringe.

Description

[0001] APPARATUS AND METHOD FOR REDUCING MOIRE FRINGE [0002]

The following embodiments relate to a 3D display, and more particularly, to a method and apparatus for reducing the width of a moiré pattern that occurs in a 3D display.

Non-spectacles 3D display technology is developing at a fast pace since 3D images can be viewed without special equipment (for example, polarized glasses or helmets).

Typical glassesless 3D displays include a display screen and a light modulator. The optical modulator includes a slit raster, a columnar lens raster, and a microlens array. Moire patterns can be generated when an optical modulator of a periodically arranged raster structure interacts with a display screen on which pixels are periodically arranged.

It is possible to make the moire pattern dense by rotating the optical modulator at a certain angle. In this case, the optical modulator must estimate the tilt angle between the display screen and the light modulator corresponding to the smallest moiré pattern width. For this purpose, the optical modulator measures the width of the moire pattern at the current tilt angle, then adjusts the tilt angle in consideration of the measured width, and recalculates the width of the moire pattern at the adjusted tilt angle.

According to one embodiment, calculating the width of the moiré pattern for each of the different angles of inclination between the pixels of the microlens array and the display screen, and calculating the final tilt angle between the microlens array and the pixels of the display screen using the calculated moiré pattern widths And determining a tilt angle corresponding to a minimum width of the moiré pattern.

According to one embodiment, calculating the width of the moiré pattern may include calculating a width of the moiré pattern based on the different spacing of the pixels included in the display screen or the different widths of the unit microlenses of the microlens array Reduction method is provided.

According to one embodiment, the different widths of the unit microlenses include a moiré including at least one of a horizontal width of the unit microlenses, a vertical width of the unit microlenses, and a diagonal width of the unit microlenses when the unit microlenses are hexagonal A pattern reduction method is provided.

According to one embodiment, different widths of the unit microlenses are provided, including a horizontal width of the unit microlenses and a diagonal width of the unit microlenses when the unit microlenses are rectangular.

According to one embodiment, calculating the width of the moire pattern includes calculating a width of the moire pattern based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen / RTI >

According to one embodiment, the width of the unit microlenses of the microlens array when projected on the display screen is at least equal to a predetermined user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlenses of the microlens array There is provided a moire pattern reduction method which is determined based on one.

According to one embodiment, the different inclination angles between the pixels of the microlens array and the display screen are different from each other between the vertical spacing of the pixels and the inclination angle between the microlens array and the horizontal spacing of the pixels and the inclination angle of the microlens array. A pattern reduction method is provided.

According to one embodiment, determining the final tilt angle between the pixels of the microlens array and the display screen comprises calculating a moiré pattern width based on the combination of values by creating a combination of values by matching the interval and tilt angle of the pixels Value combination and a moiré pattern width is determined.

According to one embodiment, a moire pattern width calculating section for calculating the width of the moire pattern with respect to each of the different inclination angles between the pixels of the microlens array and the display screen, and the final inclination angle between the pixels of the microlens array and the display screen, There is provided a moiré pattern reducing device including an inclination angle determining section which determines an inclination angle corresponding to a minimum width of moiré pattern widths.

According to one embodiment, the moire pattern width calculating section provides a moire pattern reducing apparatus that calculates the width of the moire pattern based on different intervals of pixels included in the display screen or different widths of unit microlenses of the microlens array do.

According to one embodiment, the moire pattern width calculating section is provided with a moire pattern reducing device for calculating the width of the moire pattern based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen.

According to one embodiment, the width of the unit microlenses of the microlens array when projected on the display screen is at least equal to a predetermined user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlenses of the microlens array There is provided a moire pattern reducing apparatus which is determined based on one.

According to one embodiment, the different inclination angles between the pixels of the microlens array and the display screen are different from each other between the vertical spacing of the pixels and the inclination angle between the microlens array and the horizontal spacing of the pixels and the inclination angle of the microlens array. A pattern reducing device is provided.

There is provided a computer-readable recording medium on which a program for executing a moire pattern reducing method according to an embodiment is recorded.

1 is a view illustrating a structure of a 3D display according to an embodiment.
2 is a view showing a moire pattern according to an embodiment.
3 is a flowchart illustrating an operation performed by the moire pattern reducing apparatus according to an embodiment.
4 is a diagram illustrating a moire pattern reducing apparatus according to an embodiment.
5 is a diagram illustrating a structure of a display screen on which pixels are arranged according to an embodiment.
FIG. 6 is a view showing a microlens array in which a unit microlens according to an embodiment is hexagonal.
7 is a graph showing a plurality of pattern width curves calculated with different combinations of the spacing and the tilt angle of the pixels of the display screen according to one embodiment.
8 is a graph showing a width of a moire pattern according to an inclination angle in a microlens array having a unit microlens shape of a rectangular shape according to an exemplary embodiment.
9 is a graph showing a width of a moire pattern according to an inclination angle in a microlens array having a unit hexagonal shape of a unit microlens according to an exemplary embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.

1 is a view illustrating a structure of a 3D display according to an embodiment. Referring to FIG. 1, a 3D display according to one embodiment includes a display screen 110 and a microlens array 120. According to one embodiment, one or more pixels may be periodically arranged on the display screen 110.

Also, a video display engine 130 may be coupled to the display screen 110. The image display engine 130 may pass signals to the pixels included in the display screen 110. Whereby the image display engine 130 can output the image to the display screen 110. [ As an example of the image display engine 130 which does not limit the embodiment, there is a graphics card.

According to one embodiment, the microlens array 120 may include one or more unit microlenses. The unit microlenses may be arranged periodically. Further, the unit microlenses may be periodically arranged in the vertical direction and / or the vertical direction. Since the microlens array 120 can provide vertical and / or vertical parallax, the user can view 3D stereoscopic images.

According to one embodiment, the unit microlenses may be arranged parallel to the direction in which the pixels of the display screen are arranged. According to another embodiment, the unit microlenses may be arranged with a constant inclination angle with respect to the direction in which the pixels of the display screen are arranged. Since both the microlens array 120 and the display screen 110 include the periodically arranged elements (unit microlenses and pixels), the microlens array 120 and the display screen 110 interact with each other to generate a moire pattern have.

Since the width of the moiré pattern can be changed according to the inclination angle, the width of the moiré pattern can be minimized by adjusting the inclination angle. According to one embodiment, a moire pattern width calculating section for calculating the width of the moire pattern with respect to each of the different inclination angles between the pixels of the microlens array and the display screen, and the final inclination angle between the pixels of the microlens array and the display screen, A moire pattern reducing device including an inclination angle determining portion for determining the inclination angle corresponding to the minimum width of the moire pattern widths can be provided.

According to yet another embodiment, there is provided a method comprising calculating a width of a moiré pattern for each of different angles of inclination between pixels of a microlens array and a display screen and calculating a final angle of inclination between pixels of the microlens array and the display screen, And a step of determining a slanting angle corresponding to a minimum width of the widths of the plurality of wirings.

2 is a view showing a moire pattern according to an embodiment. According to one embodiment, a 3D display may be provided that includes unit microlenses arranged in the direction in which the pixels of the display screen are arranged and at a certain tilt angle. Since both the microlens array and the display screen include the periodically arranged elements (unit microlenses and pixels), the microlens array and the display screen interact with each other to generate a moiré pattern. In FIG. 2, a unit microlens periodically arranged and a periodically arranged pixel are simplified in a straight line to explain a moire pattern.

Referring to FIG. 2, a straight line for a pixel and a microlens can be expressed in a coordinate plane composed of an x-axis and a y-axis. Pixels periodically arranged on a display screen according to one embodiment may be represented by straight lines 221, 222, and 223. 2, the pixels are arranged in a direction parallel to the y-axis direction, and are arranged in an interval of T _{2 in} the x-axis direction. The unit microlenses periodically arranged in the microlens array according to an exemplary embodiment may be represented by straight lines 211, 212, 213, 214, and 215. Referring to FIG. 2, the unit microlenses have a constant inclination angle &thetas; with the y axis, and are arranged at intervals of T ₁ .

Referring to FIG. 2, the pixels of the display screen may be periodically arranged in a direction parallel to the y-axis with a spacing of T ₂ . And unit microlenses may be periodically arranged at intervals of T ₁ . In addition, the unit microlenses can be arranged so as to be inclined by the inclination angle of? And the direction in which the pixels are arranged (parallel to the y-axis).

A straight line in which the x-intercept of the straight line to the unit microlens is the smallest positive number is referred to as a straight line to the unit microlens at the m = 1-th unit. Thereafter, m is incremented by 1 along the x-axis direction. Referring to FIG. 2, the straight line 213 corresponds to the first unit microlens. And the straight line 214 corresponds to the second unit microlens. In this case, the straight line for the m-th unit microlens can be expressed by Equation 1 as follows.

Referring to FIG. 2, equation (231) corresponding to the straight line 213 for the first unit microlens can be obtained by substituting 1 for m in equation (1). In addition, the equation (232) corresponding to the straight line 214 for the second unit microlens can be obtained by substituting 2 for m. Substituting 3 into m, an equation (233) corresponding to the straight line 215 for the third unit microlens can be obtained.

를 만족한다.The intersection of the straight line 223 and the straight line for the m-th unit microlens can be expressed as (T ₂ , y _1m ). 2, the coordinates of the intersection 256 of the straight line 223 with respect to the display screen and the straight line 214 with respect to the second unit microlens is (T ₂ , y ₁₂ ). Similarly, the coordinate of the intersection 259 of the straight line 223 and the straight line 215 to the third unit microlens is (T ₂ , y ₁₃ ). Since these intersections are located on the straight line with respect to the m-th unit microlens, (T ₂ , y _1m )

.

Since the straight line 222 is on the y-axis, the intersection of the straight line 222 and the straight line to the m-th unit microlens can be expressed as (0, _y0m ). 2, the coordinates of the intersection point 258 of the straight line 222 and the straight line 213 with respect to the first unit microlens can be expressed by (0, y ₀₁ ).

2, straight lines 221, 222 and 223 for the display screen and straight lines 211, 212, 213, 214 and 215 for the microlens array intersect each other to form intersections 251, 252, 253, 254, 255, 256, 257, 258, 259). The straight lines 241, 242, and 243 connecting these intersections are straight lines corresponding to the moire pattern. Therefore, the interval T _m between the straight lines 241, 242, and 243 corresponding to the moire pattern corresponds to the period of the moire pattern.

Based on FIG. 2 and Equation (1), Equation (2 ₎ for calculating the period T _m of the moire pattern can be derived. Further, equation (3) for calculating the direction angle alpha of the moire pattern can be derived.

M in Equation (2) is defined by Equation (4), and round () in Equation (4) means a function for performing at least one of rounding, rounding and rounding at a specific digit.

The moire pattern reducing apparatus according to one embodiment can calculate the width of the moire pattern for different inclination angles by changing theta in Equation (2). Based on this, the moire pattern reducing device can detect the inclination angle &thetas; corresponding to the minimum width among the widths of a plurality of moire patterns. And, the moire pattern reducing device can determine the inclination angle &thetas; corresponding to the minimum width as the final inclination angle between the microlens array and the pixels of the display screen.

According to another embodiment, the microlens array and the display screen can be spaced apart. Referring to FIG. 1, a 3D display in which the microlens array 120 and the display screen 110 are separated at regular intervals may be provided. 2, Equation 4 shows that in the embodiment where the straight lines 221, 222 and 223 for the display screen and the straight lines 211, 212, 213, 214 and 215 for the microlens array are arranged in the same coordinate plane It is derived. Accordingly, an error may occur when Equation (4) is applied to the embodiment in which the microlens array and the display screen are spaced apart.

The moire pattern reducing apparatus according to one embodiment can calculate the width of the moire pattern considering the distance between the microlens array and the display screen. The moire pattern reducing apparatus according to an embodiment can calculate the width T _m of the moire pattern based on the width T ₁ 'of the unit microlenses of the microlens array when the microlens array is projected on the display screen. According to some embodiments, the moire fringe reduction device may calculate T ₁ 'based on Equation (5).

P _L is the width of the unit microlenses of the microlens array, and g is the distance between the display screen and the microlens array. D is a predetermined user viewing distance. According to one embodiment, the predetermined user viewing distance may be the distance between the user and the display screen. According to another embodiment, the preset user viewing distance may be selected to an appropriate value based on the 3D display viewing environment.

When the microlens array is projected onto the display screen, the width T ₁ 'of the unit microlenses of the projected microlens array and the interval T ₂ of the pixels of the display screen are located in the same plane. In this case, by modifying Equation (4), Equation (6) that can calculate the width T _m of the moire pattern can be derived. Further, the expression (8) that can calculate the direction angle? Of the moire pattern can be derived from the expression (3).

M in Equation (6) can be defined by Equation (7) based on T ₁ 'and Equation (4). is the inclination angle formed by the unit microlenses projected on the display screen and the pixels of the display screen.

The moire pattern reduction apparatus according to one embodiment can calculate the width of the moire pattern based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen. According to some embodiments, the width of the unit microlenses of the microlens array when projected on the display screen is at least one of a predetermined user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlenses of the microlens array Can be determined based on one.

3 is a flowchart illustrating an operation performed by the moire pattern reducing apparatus according to an embodiment. According to one embodiment, calculating the width of the moiré pattern for each of the different angles of inclination between the pixels of the microlens array and the display screen, and calculating the final tilt angle between the microlens array and the pixels of the display screen using the calculated moiré pattern widths And a moire pattern reducing device for performing the moire pattern reducing method.

Referring to FIG. 3, in step 310, the moire fringe reduction device according to one embodiment may calculate the width T _m of the moire fringe for each of the different inclination angles? Between the pixels of the microlens array and the display screen. According to one embodiment, in step 310, the moire fringe reduction device is configured to reduce the width of the moire pattern based on the different spacing T ₂ of the pixels contained in the display screen or the different width T ₁ of the unit microlenses of the microlens array T _m can be calculated.

In step 310, the moire fringe reduction device according to one embodiment can calculate the width T _m of the moire fringe based on equation (2). According to some embodiments, the moire fringe reduction device can calculate M of Equation (2) based on Equation (4). According to another embodiment, the moire fringe reduction device can calculate the direction angle? Of the moire fringe based on Equation (3).

The moire pattern reduction apparatus according to one embodiment may calculate T ₁ 'based on Equation (5) in step 310. According to one embodiment, the moire pattern reducing device may have a width T ₁ 'of a unit microlens of a microlens array when projected on a display screen is set to a predetermined user viewing distance D, a distance g between the display screen and the microlens array, And the width P _L of the unit microlenses of the lens array.

The moire fringe reduction device according to one embodiment may calculate the width T _m of the moire fringe based on the width T ₁ 'of the unit microlenses of the microlens array when the microlens array is projected onto the display screen in step 310 have. According to one embodiment, the moire fringe reduction device can determine T _m based on Equation (6). According to one embodiment, the moire fringe reduction device may determine M in Equation 6 based on Equation (7). According to some embodiments, the moire fringe reduction device can calculate the direction angle? Of the moire fringe based on Equation (8).

In step 320, reduce moire pattern device can determine the inclination angle corresponding to the minimum width of the microlens array and the width T _m of the moire fringe computing the final inclination angle θ between the pixels of the display screen. According to one embodiment, the moire pattern reduction device can detect the minimum width of the calculated moiré pattern widths T _m . According to one embodiment, the moire fringe reduction device can identify the tilt angle corresponding to the detected minimum width. According to one embodiment, the moire pattern reduction device may be set to an inclination angle that identifies the final tilt angle &thetas;'between the microlens array and the pixels of the display screen.

A typical technician can easily set or adjust the inclination angle? Between the microlens array and the display screen based on the provided embodiment. According to yet another embodiment, the moire pattern reduction device generates a value combination by matching the interval and inclination angle of the pixels in step 320, and then calculates a moire pattern width based on the value combination to calculate a value combination of the moiré pattern width The graph can be determined. According to some embodiments, the moire pattern reduction device may output the determined graph. The graph may be output in the form of a display, a printer, or a computer-readable recording medium, and is not limited to the listed examples.

4 is a diagram illustrating a moire pattern reducing apparatus according to an embodiment. 4, a moire fringe width calculation unit 410 for calculating a fringe pattern width for each of different inclination angles between pixels of the microlens array and the display screen, and a final inclination angle between pixels of the microlens array and the display screen And an inclination angle determiner 420 for determining an inclination angle corresponding to the minimum width among the calculated widths of the moire pattern.

According to one embodiment, the moire fringe width calculation unit 410 can calculate the width T _m of the moire fringe for each of different inclination angles? Between the pixels of the microlens array and the display screen. According to one embodiment, the moiré pattern width calculation unit 410 calculates the moiré pattern width T _{m (} t ₎ based on the different interval T ₂ of the pixels included in the display screen or the different width T ₁ of the unit microlenses of the microlens array Can be calculated.

According to one embodiment, the moire pattern width calculating section 410 can calculate the width T _m of the moire pattern based on the formula (2). According to some embodiments, the moire fringe width calculation unit 410 can calculate M of Formula (2) based on Formula (4). According to another embodiment, the moire pattern width calculating section 410 can calculate the direction angle? Of the moire pattern on the basis of Equation (3).

According to one embodiment, a 3D display in which the microlens array 120 and the display screen 110 are separated at regular intervals can be provided. According to one embodiment, the moire pattern width calculating section 410 can calculate the width T _m of the moire pattern based on the width T ₁ 'of the unit microlenses of the microlens array when the microlens array is projected on the display screen have.

According to one embodiment, the width T ₁ 'of the unit microlenses of the microlens array when projected on the display screen is determined by a predetermined user viewing distance D, a distance g between the display screen and the microlens array, And the width P _L of the lens. Moire pattern width calculating section 410 can calculate T ₁ 'based on equation (5).

According to one embodiment, the moire pattern width calculating section 410 can determine T _m based on Equation (6). According to some embodiments, the moire pattern width calculating section 410 can determine M in Equation 6 based on Equation (7). According to some embodiments, the moire pattern width calculating section 410 can calculate the direction angle? Of the moire pattern on the basis of Equation (8).

According to one embodiment, the tilt angle determination unit 420 may determine the angle of inclination corresponding to the minimum width of the width of the moire pattern T _m calculation the final inclination angle θ 'between the microlens array and the pixels of the display screen. According to one embodiment, the tilt angle determiner 420 may detect the minimum width of the calculated width T _m of the moire pattern. The inclination angle determiner 420 can identify the inclination angle corresponding to the detected minimum width. According to one embodiment, the tilt angle determiner 420 may set an inclination angle that identifies the final tilt angle &thetas;'between pixels of the microlens array and the display screen.

According to another embodiment, the inclination angle determiner 420 may generate a value combination by matching the interval and the inclination angle of the pixels. Further, the inclination angle determiner 420 can calculate the moire pattern width based on the value combination, and determine a graph of the value combination and the moire pattern width. According to some embodiments, the tilt angle determiner 420 may output the determined graph.

5 is a diagram illustrating a structure of a display screen on which pixels are arranged according to an embodiment. According to one embodiment, moiré patterns may occur due to the interaction of the unit microlenses arranged at regular intervals and the pixels arranged at regular intervals.

Referring to the first exemplary structure 510 for the display screen of FIG. 5, a display screen according to one embodiment may include a space between the periodically arranged pixels 511 and the pixels 511. According to one embodiment, the microlens array may interact with the periodically arranged pixels 511 to generate a moiré pattern.

Also referring to the first exemplary structure 510, the pixels 511 may be periodically arranged along the horizontal and / or vertical direction, and the different pixels 511 may be spaced apart. Thus, the periodic horizontal arrangement of pixels and the microlens array can interact to form a moiré pattern, and the periodic vertical arrangement of pixels and the microlens array interact to form a moiré pattern. In addition, the space between the pixels and the microlens array can interact to form a moiré pattern.

The moire pattern reduction apparatus according to one embodiment can calculate the width of the moire pattern for each of different inclination angles between pixels of the microlens array and the display screen. At this time, the different inclination angles between the pixels of the microlens array and the display screen may include at least one of the vertical interval of the pixels, the inclination angle between the microlens array and the horizontal interval of the pixel, and the inclination angle formed by the microlens array.

Referring to FIG. 5, the moiré pattern reducing device according to one embodiment can calculate the width of the moiré pattern based on the horizontal spacing P _PH 512 of pixels and / or the vertical spacing P _PV 513 of pixels. According to one embodiment, the moire pattern reduction apparatus can calculate the width of the moire pattern by substituting P _PH 512 and / or P _PV 513 in T ₂ in Equation (2).

In this case, the inclination angle θ between the microlens array and the pixels of the display screen is assigned different values depending on the T _2. If a horizontal spacing P _PH (512) of pixels is assigned to T ₂ , then θ may be the inclination angle between the horizontal direction of the pixel and the array of microlenses. If T ₂ is the vertical distance of pixels P _PV 513, then θ may be the tilt angle between the vertical direction of the pixel and the array of microlenses.

In addition, since the pixels 511 are periodically arranged, the space between the pixels 511 can also be periodically repeated. Therefore, the space between the pixels 511 and the microlens array can interact with each other to generate a moiré pattern. Since the pixels 511 can be arranged apart from each other, the space between the pixels 511 can also be periodically arranged in the horizontal direction and / or the vertical direction.

The moire pattern reducing apparatus according to one embodiment can calculate the width of the moire pattern considering the horizontal interval and / or the vertical interval formed between the spaces between the pixels 511. [ The display screen according to some embodiments may have the same horizontal spacing between pixel 511 and pixel 511. [ In this case, the horizontal interval formed by the space between the pixels 511 may coincide with the horizontal interval of the pixel 511.

Referring to a second exemplary structure 520 for the display screen of FIG. 5, one pixel may comprise three different color (red, green, blue) subpixels. By adjusting the brightness of three different color subpixels, the display screen can output a color image. In Fig. 5, subpixels of the same color are shown using the same pattern. For example, the red subpixel 521 uses a horizontal pattern, the green subpixel 522 uses a vertical pattern, and the blue subpixel 523 uses a diagonal pattern.

In this case, since the three subpixels form one pixel, the horizontal spacing P _PH '524 of the subpixels may be 1/3 of the vertical spacing P P _PV ' 525 of the pixels. The moire pattern reduction apparatus according to one embodiment can calculate the width of the moire pattern considering that the above-described horizontal interval is 1/3 of the vertical interval.

In addition, in the embodiment where the display screen and the microlens array are spaced apart, the moire pattern reducing device can calculate the width of the moiré pattern based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen have. In this case, the moire pattern reducing apparatus can calculate the width of the unit microlenses projected on the display screen based on Equation (5).

In the embodiment in which the display screen and the microlens array are spaced apart from each other, the Moire pattern reduction apparatus can calculate the width of the moire pattern by substituting P _PH 512 and / or P _PV 513 in T ₂ in Equation (6). Further, the moire pattern reducing apparatus can substitute the width of the unit microlens projected on the display screen into T ₁ 'in Equation (6). In this case,? In Equation (6) may be an inclination angle formed by the unit microlenses projected on the display screen and the pixels of the display screen.

Furthermore, the display screen including the subpixel and the microlens array can be spaced apart from each other. In this case, the moire pattern reducing apparatus can calculate the width of the moiré pattern considering the relationship of the horizontal interval P _PH '(524) of the subpixel to the vertical interval P _PV ' (525) of the pixel. At the same time, the moire pattern reducing device can calculate the width of the moire pattern based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen.

Although only two exemplary structures are described for the display screen, the embodiments may be applied to other types of pixels or other periodic arrangements of pixels. As another form of pixel that does not limit the embodiment, the shape of the pixel or subpixel may be a circle or a hexagon as well as a rectangle. Embodiments may also be applied to other types of pixels or subpixels.

As an example of a periodic arrangement without limiting the embodiment, three circular subpixels may be arranged in triangle, four circular subpixels may be arranged in rhombus, or six circular subpixels may be arranged in hexagon. In addition, the rectangular subpixels may have different areas or may be arranged in different directions. An example in which subpixels are arranged with different areas is a pentile arrangement. The moiré pattern can be generated by interacting with a periodically arranged microlens array if the pixels or subpixels are periodically arranged. Embodiments may also be applied to other types of pixels where moire patterns occur or other periodic arrangements of pixels.

6 is a view showing a microlens array in which the unit microlenses according to an embodiment are hexagonal in shape. According to one embodiment, the unit microlenses may be periodically arranged in the microlens array. In addition, the microlens array may include various types of unit microlenses. Examples of the shape of the unit microlenses in the form of a circle, a quadrangle, and a hexagon can be mentioned. It will be apparent to those of ordinary skill in the art that the examples listed are not intended to limit the embodiments.

Referring to FIG. 6, a microlens array in which hexagonal unit microlenses 610 are periodically arranged is provided. According to one embodiment, the hexagonal unit micro lenses 610 may be periodically arranged in the horizontal direction and / or the vertical direction. The horizontal width, the vertical width and the diagonal width of the hexagonal unit microlenses may be different from each other. Referring to FIG. 6, the horizontal widths P _LH 620 and P _LV 630 may be different from each other.

The moire pattern reduction apparatus according to one embodiment can calculate the width of the moire pattern based on different intervals of pixels included in the display screen or different widths of unit microlenses of the microlens array. According to some embodiments, when the unit microlenses are hexagonal, the different widths of the unit microlenses are the horizontal width P _LH 620 of the unit microlenses, the vertical width P _LV 630 of the unit microlenses, And a diagonal width.

Assume that the microlens array includes a hexagonal unit microlens 610, and that the display screen follows the first exemplary structure 510 of FIG. The moire pattern reduction apparatus according to one embodiment can calculate the width of the moire pattern based on the horizontal spacing P _PH (512) of the pixels and the horizontal width P _LH (620) of the unit microlenses. If a moire pattern reduction apparatus using the equation (2), and the horizontal width P _LH (620) of the unit microlens substituted for T _1, is substituted, the horizontal spacing of the pixels P _PH (512) to T _2. Also, the inclination angle formed by the horizontal direction of the unit microlenses and the horizontal direction of the pixels will be substituted for?.

Further, the moire pattern reducing device can calculate the width of the moire pattern based on the vertical interval P _PV 513 of the pixel and the vertical width P _LV 630 of the unit microlens. If moire pattern reduction device is used, the equation (2), and a vertical width P _LV (630) of the unit microlens substituted for T _1, is substituted for the vertical spacing of the pixels P _PV (513) to T _2. and an inclination angle formed by the vertical direction of the unit microlenses and the vertical direction of the pixels is substituted for?. If moire pattern reduction unit is based on the horizontal distance of the pixel P _PH (512) and components of the vertical width of the microlens P _LV (630) calculates the width of the moire pattern, and a P _PH (512) assigned to the T ₁ T ₂ The P _LV 630 is substituted into the P _LV 630. and an inclination angle formed by the vertical direction of the unit microlenses and the horizontal direction of the pixel is substituted for?.

In addition, the microlens array and the display screen can be spaced apart from each other. In this case, the moire pattern reducing apparatus according to an embodiment can calculate the width of the moire pattern using Equation (6). The moire pattern reducing device can calculate the width of the moire pattern based on the width of the unit microlenses of the microlens array when projected on the display screen.

The width of the moiré pattern can be calculated based on the different widths of the unit microlenses projected on the display screen according to one embodiment. That is, the horizontal width, the vertical width, and the diagonal width of the unit microlenses projected on the display screen can be substituted into T ₁ 'in Equation (6). Further, T ₁ 'may be determined based on at least one of a preset user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlens of the microlens array. According to one embodiment, T ₁ 'may be determined by Equation (7).

In the above-described assumption, the moire pattern reduction device considers the horizontal spacing P _PH (512) of pixels and the vertical spacing P _PV (510) of pixels at different intervals of pixels, The horizontal width P _LH of the lens 620, the vertical width P _LV of the unit microlenses 630, and the diagonal width of the unit microlenses. Therefore, the moire pattern reducing apparatus can calculate the width of the moire pattern in the combination of the intervals of six different pixels and the width of the unit microlenses. Further, the inclination angle &thetas; can be determined by a combination of different intervals of pixels and different widths of unit microlenses.

The moire pattern reducing apparatus according to one embodiment can calculate the width of the moire pattern considering the relationship between the horizontal width and the vertical width of the unit microlens. Referring to hP _LH 640 in FIG. 6, the horizontal width of the unit microlenses may be half the vertical width of the unit microlenses.

Only the embodiment in which the shape of the unit microlenses is hexagonal has been described. However, the apparatus for reducing the moire pattern according to one embodiment can be applied to other types of unit microlenses.

For example, the moire pattern reducing device can be applied to a unit microlens of a rectangular shape. In this case, the moire pattern reducing device can calculate the width of the moire pattern based on different widths of the unit microlenses. Since the unit microlenses are rectangular, different widths of the unit microlenses may include at least one of the horizontal width of the unit microlenses and the diagonal width of the unit microlenses.

In an embodiment of a rectangular unit microlens, suppose that the display screen follows the first exemplary structure 510 of FIG. In this case, the moire pattern reducing device considers the horizontal spacing P _PH (512) of the pixels and the vertical spacing P _PV (510) of the pixels at different intervals of the pixel, and the horizontal width of the unit micro- Width and the diagonal width of the unit microlenses can be considered. Therefore, the moire pattern reducing device can calculate the width of the moire pattern in the combination of the intervals of the four different pixels and the width of the unit microlenses. The inclination angle between the pixels of the microlens array and the display screen is determined by the combination of the pixel interval and the width of the unit microlenses.

According to another embodiment, the moire pattern reducing apparatus can calculate the width of the moire pattern based on the width of the unit microlenses projected on the display screen when the display screen and the microlens array are spaced apart. In this case, the moire pattern reducing device can calculate the width of the moire pattern based on the horizontal width and the diagonal width of the unit microlenses projected on the display screen. The horizontal width and the diagonal width of the unit microlenses projected on the display screen can be determined based on Equation (5).

An embodiment of a display screen according to the first exemplary structure 510 of FIG. 5 and a unit microlens in a hexagonal or rectangular shape has been described. Furthermore, the embodiment can be easily applied to a display screen of another structure and a microlens array of another structure.

7 is a graph showing a plurality of pattern width curves calculated with different combinations of the spacing and the tilt angle of the pixels of the display screen according to one embodiment.

The moire pattern reducing apparatus according to an exemplary embodiment may generate a value combination by matching the interval of the pixels of the display screen and the inclination angle between the pixel and the unit microlenses. The black moiré pattern can occur because the space between the pixels and the microlens array interact. In addition, the color moiré pattern can occur due to the interaction of periodically arranged pixels or subpixels with the microlens array. The moire pattern reducing apparatus according to one embodiment can generate a plurality of value combinations in order to comprehensively consider these various moire patterns.

The moire pattern reduction apparatus according to an embodiment can calculate the moire pattern width based on the generated value combination, and output the correlation between the calculated width and the value combination of the calculated moire pattern as a graph. A plurality of curves for the width of the moire pattern can be calculated according to a plurality of combination of values. The moire pattern reducing apparatus according to one embodiment can output a plurality of curves together as shown in the first graph 710.

The moire pattern reducing apparatus according to one embodiment can take into account the maximum value of the width of the moire pattern to determine the inclination angle that minimizes the width of the moire pattern. Referring to FIG. 7, the moire pattern reducing apparatus according to an embodiment can select a maximum value of the width of the moire pattern according to the inclination angle of the first graph 710. Based on this, the moire pattern reducing apparatus can calculate the second graph 720 composed of the maximum value of the width of the moire pattern.

Referring to the second graph 720, it can be seen that the maximum value of the width of the moire pattern becomes minimum when the inclination angle is 18 to 26 degrees or 65 to 72 degrees. The moire pattern reduction apparatus according to one embodiment can refer to the second graph 720 to determine the final tilt angle between the microlens array and the display screen. That is, the final inclination angle can be determined within a range of 18 to 26 degrees or 65 to 72 degrees.

8 is a graph showing a width of a moire pattern according to an inclination angle in a microlens array having a unit microlens shape of a rectangular shape according to an exemplary embodiment.

According to one embodiment, the moire pattern reducing device can calculate the width of the moire pattern based on different widths of unit microlenses. According to some embodiments, the moire pattern reduction apparatus can calculate the width of the moire pattern based on at least one of the horizontal width of the unit microlenses and the diagonal width of the unit microlenses when the unit microlenses are rectangular. In addition, the moire pattern reduction apparatus according to an exemplary embodiment may generate a value combination by matching different widths and inclination angles of the unit microlenses. The moire pattern reduction apparatus can calculate the moire width based on the combination of values generated, and then output it in the form of a graph.

The moire pattern reduction apparatus according to an embodiment can generate a value combination by matching different widths and inclination angles of a unit microlens having a rectangular shape. The moire pattern reducing device can calculate the width of the moire pattern on the basis of the value combination generated and then select the maximum value of the width of the moire pattern by the inclination angle. The moire pattern reduction apparatus according to an exemplary embodiment may output a graph of a maximum value selected in the form of a graph shown in FIG.

The moire pattern reducing apparatus according to one embodiment can take into account the maximum value of the width of the moire pattern to determine the inclination angle that minimizes the width of the moire pattern. The tilt angle with the smallest maximum value of the width of the moire pattern can be the final tilt angle between the microlens array and the pixels of the display screen.

Referring to FIG. 8, the moire pattern reducing apparatus according to one embodiment can determine the final inclination angle in the range of 18 to 26 degrees. Based on this, the moire pattern reducing device can adjust the inclination angle formed between the display screen and the microlens.

9 is a graph showing a width of a moire pattern according to an inclination angle in a microlens array having a unit hexagonal shape of a unit microlens according to an exemplary embodiment.

According to one embodiment, the moire pattern reducing device can calculate the width of the moire pattern based on different widths of unit microlenses. According to some embodiments, the moire pattern reducing device is configured to reduce the width of the moire pattern based on at least one of a horizontal width of the unit microlenses, a vertical width of the unit microlenses, and a diagonal width of the unit microlenses when the unit microlenses are hexagonal Can be calculated.

The moire pattern reduction apparatus according to an embodiment can generate a value combination by matching different widths and inclination angles of hexagonal unit microlenses. The moire pattern reducing device can calculate the width of the moire pattern on the basis of the value combination generated and then select the maximum value of the width of the moire pattern by the inclination angle. The moire pattern reduction apparatus according to an exemplary embodiment may output a graph of a maximum value selected in the form of a graph shown in FIG. In addition, the moire pattern reduction apparatus according to an exemplary embodiment may consider the maximum value of the width of the moire pattern to determine the inclination angle that minimizes the width of the moire pattern.

Referring to FIG. 9, the moire pattern reducing apparatus according to one embodiment can determine the final inclination angle between the display screen and the microlens in the range of 13 to 17 degrees or 43 to 47 degrees. Based on this, the moire pattern reducing device can adjust the inclination angle formed between the display screen and the microlens.

The methods according to embodiments may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the embodiments or may be available to those skilled in the art of computer software.

Although the present invention has been fully described by way of example with reference to the accompanying drawings, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities.

Therefore, the above description should not be construed as being limited to the embodiments described, but should be determined by equivalents to the appended claims, as well as the following claims.

410: moire pattern width calculating section
420:

Claims (14)

Calculating a width of the moire pattern for each of the different inclination angles between the pixels of the microlens array and the display screen; And
Determining a final tilt angle between pixels of the microlens array and the display screen as an tilt angle corresponding to a minimum width of the calculated moiré pattern widths
/ RTI > The method according to claim 1,
The step of calculating the width of the moire pattern includes:
Wherein the width of the moiré pattern is calculated based on different intervals of the pixels included in the display screen or different widths of unit microlenses of the microlens array. 3. The method of claim 2,
Wherein the different widths of the unit microlenses include a moiré pattern including at least one of a horizontal width of the unit microlenses, a vertical width of the unit microlenses, and a diagonal width of the unit microlenses when the unit microlenses are hexagonal Reduction method. 3. The method of claim 2,
Wherein the different widths of the unit microlenses include at least one of a horizontal width of the unit microlenses and a diagonal width of the unit microlenses when the unit microlenses are rectangular. The method according to claim 1,
The step of calculating the width of the moire pattern includes:
Wherein the width of the moiré pattern is calculated based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen. 6. The method of claim 5,
The width of the unit microlenses of the microlens array when projected on the display screen is smaller than the width of the unit microlenses of the microlens array,
A predetermined user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlenses of the microlens array. The method according to claim 1,
The different inclination angles between the pixels of the microlens array and the display screen,
Wherein the microlens array includes at least one of a vertical interval of the pixels, an inclination angle formed by the microlens array, and a horizontal interval between the pixels and an inclination angle formed by the microlens array. The method according to claim 1,
Determining a final tilt angle between the microlens array and pixels of the display screen,
Determining a value combination by matching the interval of the pixels with the inclination angle; And
Calculating a moiré pattern width based on the combination of values and determining a graph of the value combination and the moiré pattern width
/ RTI > A moire pattern width calculating unit for calculating a width of the moire pattern for each of different inclination angles between pixels of the microlens array and the display screen; And
An inclination angle determiner for determining a final inclination angle between pixels of the microlens array and the display screen as an inclination angle corresponding to a minimum width of the calculated moiré pattern widths,
The moire pattern reduction device comprising: 10. The method of claim 9,
The moire pattern width calculating unit may calculate,
Wherein the width of the moiré pattern is calculated on the basis of different intervals of the pixels included in the display screen or different widths of unit microlenses of the microlens array. 10. The method of claim 9,
The moire pattern width calculating unit may calculate,
Wherein the width of the moiré pattern is calculated based on the width of the unit microlenses of the microlens array when the microlens array is projected on the display screen. 12. The method of claim 11,
The width of the unit microlenses of the microlens array when projected on the display screen is smaller than the width of the unit microlenses of the microlens array,
A predetermined user viewing distance, a distance between the display screen and the microlens array, and a width of the unit microlenses of the microlens array. 10. The method of claim 9,
The different inclination angles between the pixels of the microlens array and the display screen,
Wherein the microlens array includes at least one of a vertical interval of the pixels, an inclination angle formed by the microlens array, and a horizontal interval between the pixels and an inclination angle formed by the microlens array. A computer-readable recording medium on which a program for executing the method of any one of claims 1 to 8 is recorded.

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