DE102010042980A1 - Color filter for use in device for color-enabled display, consists of filter areas arranged in row- and column shape, and multiple different filter areas form filter group - Google Patents

Abstract

The color filter consists of filter areas arranged in row- and column shape. Multiple different filter areas form a filter group, which serve for assigning to a color-enabled, particularly completely color-enabled color pixel (14). Four adjacent filter areas with different filter characteristics form a filter group. An independent claim is also included for a device with a barrier mask.

Description

The invention relates to a color filter according to the preamble of claim 1 and to a device with a color filter.

State of the art

In the case of flat screens (also referred to below as displays), color filter areas assigned to individual pixels are used to produce colored images, which color filters are realized on a transparent substrate, for example a glass substrate, to match the pixel structure. To generate a color pixel (color pixel), three subpixels (subpixels) with associated color filters red - green - blue (abbreviated RGB) are regularly combined.

To increase the brightness in an RGB display, it is also known instead of three subpixels to combine four subpixels to a color pixel, the fourth subpixel has no color filter, so "white" light passes. This results in an RGBW display, where "W" stands for "white". For the subpixel, which eliminates the color filter, light can not pass through any color filter, so that this subpixel has up to over three times the light transmission as compared to a color filtered subpixel.

RGBW subpixel groups are sequenced in a row sequentially and form colorable color pixels.

In a known DualView display, a display that can provide a viewer from two different viewing directions two different image content, a barrier mask or a lens system is used, each of which defines visible pixels from the right or left. This mask is typically executed in a checkerboard pattern, so that from line to line a viewer can still have a complete RGB pixel available for each page. This leads to the viewer to a comparable to a conventional display reproduction of colors and lines.

If an RGBW layout is used for the application in a DualView display, due to the quad array, the color filters for the subpixels, which together form the color pixel, a checkerboard-shaped barrier mask or a functionally equivalent lens system can no longer be applied because This would cause color information to be lost from line to line.

Disclosure of the invention

The invention has for its object to provide a color-capable DualView display of the type described in the introduction, which has a comparatively simpler structure.

This object is solved by the features of claim 1 or 10 or 11.

In the dependent claims advantageous and expedient developments of the invention are given.

The invention is based on a color filter for a color-capable display, which can provide a viewer with two different image contents from two different viewing directions. The color filter consists of line-and-column-shaped filter regions, wherein a plurality of adjacent different filter regions each form filter groups which can serve for assignment to a color-capable, in particular fully color-capable, color pixel.

The essence of the invention is that each four adjacent filter areas with different filter characteristics form a filter group, wherein in each group the same four different filter areas are provided, but the order of the different color filter areas in a group from group to group is different. In particular, a same order within a group occurs periodically in a series of groups, for example alternating.

As a result of this measure, it is possible to use a conventional barrier mask as a barrier mask in the design of the display, which has a simple checkerboard structure with regard to the arrangement of the individual subpixels. In addition, a conventional lens system equivalent in function to a barrier mask can be used.

As a result, not only can this structure remain unchanged. In addition, no change in the hardware is necessary in the control. Thus, although the use of a fourth subpixel to achieve a higher brightness of the same and thus cost-effective design as in an RGB display are used.

This advantage arises in particular when the order of the different filter areas in a group differs from group to group in one row, in particular an identical sequence in a group occurs periodically in groups in a row, in particular alternately.

In a preferred embodiment of the invention, the first two filter areas and the third and fourth filter areas are exchanged relative to an order within a group in a group adjacent to one row in a row to the preceding group. In this case, the order of the filter areas of the groups in a row is, for example, RGBW, GRWB, RGBW, GRWB, etc. The order of the filter areas of a group in a row is thus alternately different. By such an arrangement, in turn, a known barrier mask with a checkerboard structure or a known lens system can be used.

For example, the "W" stands for a white pixel, that is, a pixel that has no color filter.

The use of a known barrier mask or a known lens system is also possible for a preferred embodiment in which, based on an order within a group in a group adjacent to a group in a row, the sequence is the same except for a filter area. For example, a first group has the order WRGB. The adjacent group has the order of RGBW and the group adjacent to it has WRGB etc.

The scheme of how to change the order within a group, that is, for example, by swapping the first two and third and fourth filter areas, respectively, or maintaining the order of at least three filter areas may also be combined within a color filter. For example, within a line follows a first group pair of a first system for the order and an adjoining further group pair of a second system for the order.

As a result, image artifacts, which arise through periodic application of an always identical law, may be avoided.

Preferably, a color filter group comprises at least the colors red - green - blue, ie RGB and a fourth filter area. This can either be configured without a filter or, for example, have a filter region with a transmission advantageous for the image content, as is the case, for example, for the color yellow.

In a device having a color filter and a barrier mask or a lens system, another core aspect of the invention is that each four adjacent filter areas with different filter properties form a filter group, wherein in each group the same four color filter areas are provided, wherein the barrier mask or the lens system A stripe mask or an equivalent lens assembly is and wherein the order of the color filter areas in a row perpendicular to the strips of the stripe mask or the equivalent lens structure is the same. This embodiment also makes it possible to use a dual-view display with a fourth color pixel for image enhancement and at the same time to be able to use a simple barrier mask or a simple lens system. The groups are strung together along the strips. This also limits, although the use of a fourth subpixel, an additional hardware cost compared to an RGB arrangement. Preferably, the filters of the subpixels are red - green - blue, and a fourth filter area is provided which, for example, has no color filter at all. Also conceivable as the fourth color filter, as described above, is a yellow filter or a filter with high light transmittance.

drawings

Several embodiments of the invention are illustrated in the figures and are explained in more detail below, giving further details and advantages. By way of illustration, in the figures, the additional subpixel is implemented as a white pixel, that is to say without a color filter (RGBW).

1a - 1e in a schematic representation in each case 2 × 2 pixels for a first variant of a pixel with four subpixels, of which one subpixel has no color filter, in a basic form ( 1a ), with a designation of the assignment for the left and right viewer ( 1b ), with an overlying barrier mask ( 1c ), in a form for illustrating the actual impression for a left viewer ( 1d . 1e );

2a - 2e in a schematic representation, in each case 2 × 2 pixels for a second variant of a pixel with four subpixels, of which one subpixel has no color filter, in a basic form ( 2a ), with a designation of the assignment for the left and right viewer ( 2 B ), with an overlying barrier mask ( 2c ), in a form for illustrating the actual impression for a left viewer ( 2d . 2e );

3a a color filter structure with four sub-pixels for one color pixel;

3b a possible associated barrier mask;

3c the color filter after 3a in combination with the barrier mask 3b ;

4a - 4c a non-functional arrangement of sub-color pixel filtering areas relative to a checkered barrier mask, to illustrate the operation of the invention;

5a - 5e Arrangements illustrating the state of the art of a color filter mask with three color filter areas in conjunction with a checkerboard-shaped barrier mask.

In prior art DualView displays, for example, a barrier mask is used which defines the pixels visible from the right or left, respectively. In the 5a and 5e is a section 1 a conventional color filter mask shown in which three subpixels 8th . 9 . 10 a color pixel 5 with the colors red - green - blue form. The subpixel 8th So it has a red, the subpixel 9 a green and the subpixel 10 a blue color filter.

The cutout 1 shows two columns S1 and S2 and two rows Z1 and Z2, the intersection of which four color pixels 5 Are defined. The subpixels 8th . 9 . 10 will now according to 5b organized by, for example, the row Z1 over the two columns S1 and S2 across the subpixels alternately assigned to a left viewer and the other time a right viewer. The assignment for the left and right viewers of the subpixels is indicated by an "L" for the left viewer and an "R" for the right viewer.

In the underlying line Z2, the labeling takes place in principle in the same way, but the assignment for the left and right viewers with respect to the subpixels is just reversed. Will now be a checkerboard-like barrier mask 6 , as in 5c visible over this section 1 For the left viewer, only the pixels marked "L" are visible, so that a picture impression is created, as in the 5d and 5e illustrated. A full-color pixel relevant to a viewer is in 5e with a box 7 characterized. The underlying arrangement in the line Z2 also forms a fully color-capable pixel, but the subpixels have a different order to the overlying pixel in the line Z1.

The barrier mask 6 is, as in particular in the 5d and 5e should be illustrated, exactly like a checkerboard.

Will you now such a checkerboard-like barrier mask 6 Applying to a color mask that does not consist of three, but consists of four subpixels for a full color pixel, creates a non - functioning structure, which the 4a . 4b and 4c to clarify.

In 4a is a section 12 the color mask as a sectional area of two columns S1, S2 and two lines Z1, Z2 shown. The cutout 12 contains four full color pixels. Will over such a section a barrier mask 6 laid with a checkerboard structure (see 4b ) with an alternating assignment of the subpixels 8th . 9 . 10 . 11 to the left or right, as state of the art according to the 5b and 5c is realized, you get as a result color pixels for a viewer with a color arrangement, for example, for the left viewer, as in 4c clarified. In the line Z1 and in the line Z2, a fully color-capable pixel should be included with the same all subpixel types. On the other hand, only the colors red and blue (subpixels 8th . 10 ) and in line Z2 the colors green and white (subpixel 9 . 11 ). This would lead to a significant color distortion in the representation of color images.

A solution to this problem is illustrated by the 1a to 1e ,

For all representations, the designation of the subpixels with the reference numerals 8th . 9 . 10 . 11 synonymous colors red - green - blue - white.

The starting point is again a section 13 a color mask, the intersection of two columns S1 and S2 and two lines Z1 and Z2 four color pixels 14 contains. Every pixel 14 contains four subpixels 8th . 9 . 10 . 11 but where in one row is the order of the subpixels of clashing pixels 14 is different. In particular, the sequences alternate in such a way that the first pixel has the order red - green - blue - white, an adjoining pixel has the order green - red - white - blue. That is, the order of the first two sub-pixels and the subsequent third and fourth sub-pixels of adjacent pixels 14 in a row is reversed.

Will now, as in 1b alternating with such a subpixel structure, an assignment of the subpixels for the left viewer (marked "L") and for the right viewer (marked "R") and as in 1c a still checkered barrier mask 6 superimposed, results in an assignment for example, the left viewer, as in the 1d and 1e illustrated. A full color pixel for the left viewer is in 1e with the box 15 characterized. Included are all four subpixels 8th . 9 . 10 . 11 , Similarly, in the underlying line Z2 is not missing about subpixels, but there are all four possible subpixel types included (green - white - red - blue). The left viewer thus receives an unadulterated color image. Similarly, a structure results for the right viewer, as well as in each pixel, as for the pixel with the box 15 labeled, all four subpixel types are included.

In the embodiment according to the 1a to 1e the first two subpixels and the third and fourth subpixels were swapped in successive groups of four subpixels. The 2a to 2e now show another possibility.

In the pixel 14 (please refer 2a ) are again four subpixels 8th . 9 . 10 . 11 arranged in the order red - green - blue - white. In the pixel following in the row, the order is subpixel 8th . 9 . 10 , so for the colors red - green - blue the same, but is now in the first place, the white subpixel 11 moved. The result is an assignment for the left and right viewer and an overlying checkerboard-like barrier mask 6 (please refer 2 B respectively. 2c ) is shown by way of example for the left viewer, a true color impression, as in the left viewer associated full color pixels, through the box 15 in 2e illustrates all four sub-color pixel types are included. This applies equally to the left viewer to the underlying line Z2, although here the order is different.

Another way of interleaving a simple barrier mask with a color filter containing four subpixels with the colors red - green - blue and white is in the 3a to 3d illustrated.

3a shows a section 16 a color filter with 24 subpixels. In lines Z1, Z2 and Z3, the same subpixel types always follow 8th . 9 . 10 . 11 for the colors red - green - blue and the white subpixel on each other. In the lines below, however, the subpixels are each offset by one to the right, so that below the red subpixel 8th not a red subpixel is arranged, but the white subpixel 11 , The order is the same.

The same applies to the next line Z3.

Now about this structure of a color filter according to the section 16 a stripe mask 17 With stripes 18 placed, the left viewer sees in a cutout 19 , corresponding 3c , arranged in columns full color pixels, in which each necessary four subpixel types are included. The first full color pixel results in the column S2 from the visible color pixels 8th . 11 . 10 . 9 in lines Z1, Z2, Z3 and Z4, the other full color pixels in column S4 etc.

Claims (13)

Color filter for a color-capable display, which can provide a viewer with two different image contents from two different viewing directions, consisting of line and column-shaped filter regions, with several adjacent different filter regions ( 8th . 9 . 10 . 11 ) each form filter groups which are suitable for assignment to a color-capable, in particular fully color-capable, color image point ( 5 . 14 Can be used), characterized in that in each case four adjacent filter areas ( 8th . 9 . 10 . 11 ) with different filter properties a filter group ( 14 ), where in each group ( 14 ) the same four different filter areas ( 8th . 9 . 10 . 11 ), but the order of the different filter areas ( 8th . 9 . 10 . 11 ) in a group ( 14 ) of group ( 14 ) to group ( 14 ) is different. Color filter according to claim 1, characterized in that the order of the different filter areas ( 8th . 9 . 10 . 11 ) in a group ( 14 ) of group ( 14 ) to group ( 14 ) is different. Color filter according to one of the preceding claims, characterized in that, relative to an order within a group ( 14 ) in a group adjacent to a row ( 14 ) the first two filter areas ( 8th . 9 ) And the third ( 11 ) and fourth ( 10 ) Filter area are exchanged. Color filter according to one of the preceding claims, characterized in that, relative to an order within a group ( 14 ) in a group adjacent to a line, the sequence except for one color filter area ( 11 ) is equal to. Color filter according to claim 3 and 4, characterized in that there are group pairs which follow the law of claim 3 and 4 within a color filter. Color filter according to claim 3 and 4, characterized in that the group pairs of the law of claim 3 and 4 follow alternately. Color filter according to one of the preceding claims, characterized in that a color filter group ( 14 ) comprises at least the colors red green blue (RGB) and a fourth filter area. Color filter according to one of the preceding claims, characterized in that the fourth color filter area ( 11 ) is formed without a filter. Color filter according to one of the preceding claims, characterized in that the fourth color filter region is a yellow filter. Device with a color filter according to one of the preceding claims and a barrier mask ( 6 ), the checkered filter areas ( 8th . 9 . 10 . 11 ) or with a lens system comparable to a checkerboard-like barrier mask. Device with a color filter according to the preamble of claim 1 and a barrier mask or a lens system, characterized in that in each case four adjacent filter areas ( 8th . 9 . 10 . 11 ) form a filter group with different filter properties, wherein in each group the same four color filter areas ( 8th . 9 . 10 . 11 ), wherein the barrier mask is a strip mask ( 17 ) or an equivalent lens arrangement and wherein the order of the color filter areas ( 8th . 9 . 10 . 11 ) in a row perpendicular to the strips ( 18 ) of the stripe mask ( 17 ) or the equivalent lens structure is the same. Apparatus according to claim 11, characterized in that a color filter group comprises at least the colors RGB and a fourth filter region. Apparatus according to claim 11 or 12, characterized in that the fourth filter area is designed without a filter.

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