EP1960987A1 - Display device having a plurality of pixels and method for displaying images - Google Patents

Abstract

The invention relates to a display device (1) having a plurality of pixels (13) and comprising an image signal generating device (2) which is used to generate colour and luminosity values for a plurality of pixels (13), a light modulation device (3) which is coupled to an image signal generating device (2) in order to modulate the plurality of pixels (13) based on colour and luminosity values, and an illumination device (4) for back-lighting the light modulation device (3). The invention is characterised in that the illumination device (4) comprises a control device (11) for controlling a plurality of light sources (12) and the control device (11) is coupled to the image signal generating device (2) or the light modulation device (3), such that the control device (11) can control, according to the luminosity values, a predetermined group of light sources (12) for back-lighting a partial area of the light modulation device (3) for enhancing the contrast. The invention also relates to a method for displaying images on a display device (1) having a plurality of pixels (13).

Description

description

Display device with a plurality of pixels and method for displaying images

The invention relates to a display device with a plurality of pixels, comprising a

An image signal generating device for generating color and brightness values for the plurality of pixels, a light modulation device coupled to the image signal generation device for modulating the plurality of pixels based on the color and brightness values, and a lighting device for backlighting the light modulation device.

Display devices, in particular flat screens, of the type mentioned above are widely known. They are particularly suitable for use as a computer monitor or as a screen for extra-flat TV sets. Light emitted from a light source is used to backlight a modulation device having a plurality of pixels, typically a liquid crystal display (LCD). By driving the individual pixels of the light modulation device with color and brightness values generated from an image signal generating device only a portion of the incident light through the light modulation device through, so that bright and dark or different colored pixels can be generated, which then join together for a viewer to form an overall picture.

Especially in display devices in the field of consumer electronics is a particularly high Contrast range desirable. Because movies often contain scenes with a large contrast range, where contrast is the ratio between the difference between maximum and minimum brightness and a minimum displayable brightness gradation.

For a true-to-life mapping, it is therefore important to be able to depict very fine brightness gradations on the one hand and the entire range between full luminous intensity of a white pixel and no luminous intensity, ie a black pixel. This occurs, for example, in scenes with very uneven lighting, such as the simultaneous display of indoor and outdoor shots or light and shadow areas.

Commercially available display devices often have a contrast ratio of significantly less than 1: 1000. The human eye, however, is capable of resolving a much wider range of contrast. Therefore, for the faithful reproduction of films

Display devices with contrast ranges of more than 1: 1000 desirable.

From US 6,891,672 B2 a screen with an increased contrast range is known. Light emitted by a light source is first modulated by a first and then by a second modulation device. As a result, very high-contrast images can be displayed, so that, for example, even dark image areas can still be displayed finely graduated in brightness.

A disadvantage of using two light modulation devices is in particular in the high cost of light modulation devices that significantly affect the cost of a video. In addition, the second modulation device and an image signal generating device required therefor require additional power. Furthermore, the series connection of two light modulation devices absorbs a larger proportion of the incident light, so that a particularly powerful light source must be used, which in turn requires more energy.

Object of the present invention is to describe a display device of the type mentioned, which has a particularly high contrast range. In this case, the display device should be inexpensive to manufacture and economical in energy consumption.

The object is achieved by a display device of the type mentioned at the beginning, in which the lighting device has a drive device for driving a multiplicity of light sources and the drive device is coupled to the image signal generation device or the light modulation device, so that a predetermined group of light sources, which are used to backlight a partial region of the light source Light modulation device is arranged, can be controlled by the driving device in dependence of the brightness values for contrast enhancement.

By the targeted control of groups of light sources, which are set up for the backlighting of partial areas of the light modulation device, the illumination of particularly dark image areas can be reduced, so that the contrast range of the illustrated Overall picture increases. The darkening of groups of light sources additionally provides energy savings through more efficient use of light.

According to the invention, a high contrast can advantageously be achieved with only one light modulator by partially dimming the illumination device, ie the predetermined group of light sources. Due to the dimming darker display areas can be darkened more, which has a greater contrast result.

In a preferred embodiment of the invention, each light source of the plurality of light sources can be controlled individually by the drive device. In this way, even small image areas can be darkened individually.

A display device according to the present invention advantageously operates according to a method of displaying images on a display device having a plurality of pixels, comprising the steps of:

Receiving an image signal having color and brightness values for the plurality of pixels,

Calculating luminance characteristics for a plurality of different predetermined groups of pixels constituting an image to be displayed,

- Modulating the pixels by a

Light modulation device based on the color and brightness values, and

- Illuminating the different predetermined groups of pixels by a respective light source or a predetermined group of light sources in dependence on the brightness characteristic calculated for the respective predetermined group of pixels.

In an advantageous embodiment of the method, corrected color and brightness values for modulating the predetermined groups of pixels are calculated on the basis of the received color and brightness values of the image signal, taking into account the calculated brightness characteristics.

By correcting the color and brightness values used for the light modulation on the basis of the calculated brightness characteristics, the weaker backlighting of predetermined groups of pixels can be taken into account in the modulation, so that, for example, details in darkened image areas can be represented particularly well.

Further advantageous details and refinements and developments of the invention are specified in the subclaims.

Further advantages, advantageous refinements and developments emerge from the exemplary embodiment explained in more detail below in conjunction with the drawings. In the drawings show:

1 shows a schematic structure of a screen according to an embodiment of the invention,

FIG. 2 shows a flow chart for a method for displaying images, 3A to be displayed, exemplary brightness values,

FIG. 3B shows actual brightness values displayed according to the prior art,

FIG. 3C shows brightness characteristics for the exemplary brightness values,

Figure 3D corrected brightness values, and

Figure 3E actually displayed brightness values according to an embodiment of the invention.

Figure 1 shows in schematic form a structure of a display device 1, in the embodiment of a flat panel, according to an embodiment of the invention in cross section.

The screen 1 has an image signal generating device 2, a light modulation device 3 and a lighting device 4. Between the

Lighting device 4 and the light modulation device 3, a diffuser 5 is optionally arranged, which distributes the light of the lighting device 4 for the backlighting of the light modulation device 3. In front of the light modulation device 3, a ground glass 6 is additionally arranged, which scatters the translucent light through the light modulation device 3 and at the same time protects the light modulation device 3 from contact. The ground glass 6 or the diffuser 5 can also serve to select light of a predetermined polarization direction. The image signal generating device 2 has an image signal decoder 7, an image memory 8, a processing unit 9 and a selection means 10. The lighting device 4 has a drive device 11 and a plurality of light sources 12, in the exemplary embodiment, light-emitting diodes. The light modulation device 3 comprises a plurality of pixels 13 suitable for modulating the incident light. In this case, the individual pixels 13 are composed of subpixels 14, for example one subpixel 14 each for the three primary colors red, green and blue, which allow only the light of the respective primary color to pass through corresponding filters.

The drive device 11 of the lighting device 4 is set up to control each of the light sources 12 individually, so that the individual light sources 12 spatially assigned groups of pixels 15A, 15B and 15C can be backlit differently. The modulator 5 has three mutually delimited areas, so that light of a light source 12 backlit only one group of pixels 15A, 15B or 15C. Alternatively, illumination of adjacent groups 15A, 15B or 15C may also be considered by the processing unit 9.

In practice, display devices 1 naturally have substantially more pixels 13 and light sources 12 used for their illumination than can be shown in FIG. For example, to illuminate a 32 "screen with several hundred thousand pixels 13, an illumination device 4 with approximately 200 light-emitting diodes can be used as the light sources 12 are arranged, for example, strip or kacheiförmig.

Figure 2 illustrates a method for displaying images on a display device 1 according to an embodiment of the invention.

In the exemplary embodiment, in a first step 21, initially an image signal, for example a television signal, is received by the image signal decoder 7, which contains the color and brightness values I _so ii contained therein for the pixels 13. The decoded image and brightness values I _so ii are stored in the image memory 8 for further processing.

In a second step 22, luminance characteristics I _Char for predetermined groups of pixels 15 are calculated on the basis of the color and brightness values I _so ii stored in the image memory 8. In the exemplary embodiment shown in simplified form in FIG. 1, the screen 1 has three groups 15A, 15B and 15C of picture elements. The upper, middle and lower groups 15A, 15B and 15C are each assigned to one of the light sources 12 and illuminated by them.

In the exemplary embodiment, it is recognized by the processing unit 9 in the second step 22 that the lower screen area corresponding to the lower group of pixels 15C represents a particularly dark image area. This information is then stored in the brightness characteristic I _C har generated for the group 15C. In a third step 23, the plurality of pixels 13 are modulated by the light modulation device 3 in consideration of the decoded color and brightness values Isoii. For example, by applying different voltages to the individual pixels 13 of the light modulation device 3, the permeability of the pixels 13 or of the subpixels 14 for individual colors can be influenced in such a way that an overall image is created for a viewer. Usually, crystals of a liquid crystal display are deflected by generating an electric field such that their polarization direction changes so that the light of a predetermined polarization is either transmitted or absorbed.

In a preferred embodiment of the invention, the processing unit 9 takes into account the previously calculated brightness characteristic I _Char in the actual actual modulation of the pixels 13. To this end, the color and brightness values corrected from the received color and brightness values I _{so are} ii taking into account the calculated brightness characteristic I _C har Ikorr used to modulate the pixels 13 of the light modulation device 3.

In parallel, in a fourth step 24, the lighting device 4 with the associated drive device 11 is controlled by the processing device 9 such that the illumination of the individual groups of pixels 15A, 15B and 15C corresponds to the previously determined brightness characteristics I _C har. For this purpose, in the given example, in which the lower image area of Screen 1 contains a particularly dark image portion, the group of pixels 15C are darkened by darkening the associated lower light source 12.

Depending on a refresh rate of the image to be displayed, the described process is repeated after a predetermined time, so that both the pixels 13 of the light modulation device 3 and the light sources 12 of the lighting device 4 are continuously driven according to the needs of each current image signal.

FIG. 3A shows brightness values I _so II for each of the pixels 13 to be represented by the screen 1. For the sake of simplicity, in FIG. 3A and in the following figures, only brightness values I _{so are} considered alone, but no color information. In practice, the calculation described below is performed for each of the illustrated colors, such as red, green and blue.

In the illustrated example, the three first pixels 13 of the first group of pixels 15A are intended to represent a very bright image area. The next three pixels 13 of the second group of pixels 15B represent a medium-bright image area. The last three pixels 13 of the last group 15C represent a very dark image area. In FIG. 3A, in each case a brightness value I is _such for each of the pixels to be displayed 13 in percent.

FIG. 3B shows the actually displayed brightness intensity I _S dτ of a screen 1 according to FIG State of the art with an exemplary contrast ratio of 1:10. In this example, a light modulation device 3 can only represent ten different brightness levels.

The brightness values shown in FIG. 3A can only be displayed correctly in the regions of the first and second group of pixels 15A and 15B. The very low brightness in the area of the third group of pixels 15C no longer allows a signal and thus realistic representation. In FIG. 3B, this image area is completely darkened, so that details contained therein are no longer displayed.

FIG. 3C shows luminance characteristics I _Char determined according to an embodiment of the invention. In the illustrated example, the respective maximum value of a group of pixels 15A, 15B or 15C is used as the brightness characteristic.

Accordingly, in the example, the first light source 12 of the first group 15A is driven at 100 percent of the possible power, the second light source 12 at 60 percent of the possible power, and the third light source 12 at only one percent of the possible power. Since the luminous intensity of light-emitting diodes used as light source 12 in the exemplary embodiment increases substantially linearly with an operating current, the individual light sources 12 can be controlled as required, for example, by current control.

FIG. 3D shows corrected brightness values Ikorr for driving the modulation device 3, which are calculated by the processing unit 9, for example. in the Embodiment yield the corrected brightness values Ikorr by dividing the displayed brightness values I _so ii of Figure 3A by the calculated brightness characteristic I _C har of Figure 3B.

In FIG. 3E, the brightness _values I _lst perceived by a viewer on the screen 6 are shown. Since the brightness _values I visible on the _{ground glass} 6 essentially result from multiplication of the illumination intensity corresponding to the brightness characteristic I _C har shown in FIG. 3C with the corrected brightness _values I _kOrr of FIG. 3D used for the modulation, the brightness _values I _{illustrated in FIG} For each of the individual pixels 13, the brightness values I contained in the image signal are exactly the _same . Thus, a true-to-life rendition of the image signal is possible.

According to a further embodiment of the invention, individual image areas can also be specifically darkened or lightened with the aid of the selection means 10. For example, it is possible to lighten or darken an image area with a group 15 of pixels 13 by prescribing a user, for example to make the subtitles shown in the lower area of the image easier to read or hide by shading.

For example, if white subtitles are displayed on a black background in a lower image area of a motion picture film in which no image information is contained, by lowering or turning off the associated light source 12 of the group of pixels 15C, the display of the disturbing subtitles on the screen 6 can be prevented. Although in the illustrated embodiment, a screen 1 is used to display the image signal, the method of the invention can of course be used in other display methods and devices, for example, in a projection or rear projection, such as a video projector or so-called Datenbeamer. In this case, it is also possible to use a reflective one instead of a filtering light modulation device 3 such as a liquid crystal display

Modulation device 9 such as a matrix of controllable mirrors (Digital Mirror Device - DMD) to use.

Likewise, instead of the light-emitting diodes used in the exemplary embodiment, it is also possible to use other light sources 12, in particular small-area light sources, which are suitable for illuminating individual groups of pixels 15. It is advantageous if the light sources

12 are formed such that their luminous area or radiation characteristic to the backlit pixels

13 spatially assigned. For example, it is also possible to use organic, surface-emitting light-emitting diodes (OLEDs) with a luminous area of less than 5 mm ² .

LIST OF REFERENCE NUMBERS

1 screen

2 imaging device

3 light modulation device

4 lighting device

5 diffusers

6 screen

7 image signal decoder

8 image memory

9 processing unit

10 selection means

11 drive device

12 light source

13 pixel

14 subpixel

15 group of pixels

21 to 24 process steps

I _so ii to be displayed brightness value

I _sd i displayed brightness value (prior art)

I _char brightness characteristic

I _kO rr corrected brightness value

I _lst displayed brightness value ( _{according to the} invention)

Claims

claims

1. Display device (1) with a plurality of pixels

(13), comprising:

- An image signal generating device (2) for generating color and brightness values (I _so n) for the plurality of pixels (13), coupled to the image signal generating device (2) light modulation device (3) for the modulation of the plurality of pixels (13) based on the color and brightness values (I _so ii) and

- A lighting device (4) for backlighting the light modulation device (3), characterized in that the lighting device (4) comprises a drive device (11) for driving a plurality of light sources (12), in particular light-emitting diodes, and

- The drive device (11) with the image signal generating device (2) or the light modulation device (3) is coupled, so that a predetermined group of light sources for the backlighting of a portion of the

Light modulation device (3) is arranged, by the driving device (11) in dependence of the brightness values (I _so ii) for contrast enhancement is controllable.

2. Display device (1) according to claim 1, characterized in that

- Between the lighting device (4) and the light modulation device (3) a diffuser (5) is arranged, the light of the predetermined group of light sources (12) to a predetermined group (15) of Distributed pixels (13) of the sub-area of the light modulation device (3), and

- The image signal generating device (2) calculates a brightness characteristic (I _char ) of the group of pixels (15), so that the group of light sources as required by the drive device

(11) is controllable.

3. Display device (1) according to claim 1 or 2, characterized in that

- Each light source (12) of the plurality of light sources (12) individually controllable by the drive device (11).

4. Display device (1) according to one of claims 1 to 3, characterized in that the light sources (12) are surface-emitting light sources, in particular organic light-emitting diodes.

5. A method of displaying images on a display device (1) having a plurality of pixels

(13) comprising the steps of: receiving an image signal having color and brightness values (I _so ii) for the plurality of pixels

(13)

Calculating luminance characteristics (I _cha r) for a plurality of different predetermined groups (15) of pixels (13) composing an image to be displayed,

- Modulating the pixels (13) by a light modulation device (3) on the basis of the color and brightness values (I _so n) and - Illuminating the different predetermined groups of pixels (15) by a respective light source (12) or a predetermined group of light sources (12) in dependence on the brightness characteristic calculated for the respective predetermined group of pixels (15)

(Ichar) •

6. The method according to claim 5, characterized in that

- based on the received color and brightness values (Isoii) of the image signal taking into account the calculated brightness characteristics (I _cha r) corrected color and brightness _values (I _kO rr) are calculated to modulate the predetermined group of pixels (13).

A method according to claim 5 or 6, characterized in that the calculation of the brightness characteristics (I _char ) is performed on the basis of the minimum, the average or the maximum of the predetermined group of pixels (15) associated brightness values (I _so ii).