WO2011077772A1 - Compensated lcd display system and methods - Google Patents

Compensated lcd display system and methods Download PDF

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Publication number
WO2011077772A1
WO2011077772A1 PCT/JP2010/060697 JP2010060697W WO2011077772A1 WO 2011077772 A1 WO2011077772 A1 WO 2011077772A1 JP 2010060697 W JP2010060697 W JP 2010060697W WO 2011077772 A1 WO2011077772 A1 WO 2011077772A1
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WO
WIPO (PCT)
Prior art keywords
display
image
input image
liquid crystal
crystal layer
Prior art date
Application number
PCT/JP2010/060697
Other languages
French (fr)
Inventor
Xiao-Fan Feng
Scott J. Daly
Original Assignee
Sharp Kabushiki Kaisha
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sharp Kabushiki Kaisha filed Critical Sharp Kabushiki Kaisha
Priority to CN201080057969.2A priority Critical patent/CN102713734B/en
Priority to BR112012017119A priority patent/BR112012017119A2/en
Priority to RU2012130097/28A priority patent/RU2012130097A/en
Priority to JP2012542708A priority patent/JP5502209B2/en
Priority to EP10839009A priority patent/EP2504734A4/en
Publication of WO2011077772A1 publication Critical patent/WO2011077772A1/en

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Classifications

    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/34Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
    • G09G3/36Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source using liquid crystals
    • G09G3/3611Control of matrices with row and column drivers
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G3/00Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes
    • G09G3/20Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters
    • G09G3/34Control arrangements or circuits, of interest only in connection with visual indicators other than cathode-ray tubes for presentation of an assembly of a number of characters, e.g. a page, by composing the assembly by combination of individual elements arranged in a matrix no fixed position being assigned to or needed to be assigned to the individual characters or partial characters by control of light from an independent source
    • G09G3/3406Control of illumination source
    • G09G3/342Control of illumination source using several illumination sources separately controlled corresponding to different display panel areas, e.g. along one dimension such as lines
    • G09G3/3426Control of illumination source using several illumination sources separately controlled corresponding to different display panel areas, e.g. along one dimension such as lines the different display panel areas being distributed in two dimensions, e.g. matrix
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2320/00Control of display operating conditions
    • G09G2320/06Adjustment of display parameters
    • G09G2320/0626Adjustment of display parameters for control of overall brightness
    • G09G2320/0646Modulation of illumination source brightness and image signal correlated to each other
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2320/00Control of display operating conditions
    • G09G2320/06Adjustment of display parameters
    • G09G2320/066Adjustment of display parameters for control of contrast
    • GPHYSICS
    • G09EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
    • G09GARRANGEMENTS OR CIRCUITS FOR CONTROL OF INDICATING DEVICES USING STATIC MEANS TO PRESENT VARIABLE INFORMATION
    • G09G2360/00Aspects of the architecture of display systems
    • G09G2360/16Calculation or use of calculated indices related to luminance levels in display data

Definitions

  • the present invention relates generally to a system and methods displaying an image on a LCD display.
  • the local transmittance of a liquid crystal display (LCD) panel or a liquid crystal on silicon (LCOS) display can be varied to modulate the intensity of light passing from a backlit source through an area of the panel to produce a pixel that can be displayed at a variable intensity. Whether light from the source passes through the panel to an observer or is blocked, is determined by the orientations of molecules of liquid crystals in a light valve.
  • LCD liquid crystal display
  • LCOS liquid crystal on silicon
  • LCD panels used for computer displays and video screens are typically backlit with fluorescent tubes or arrays of light- emitting diodes (LEDs) that are built into the sides or back of the panel.
  • LEDs light- emitting diodes
  • the transmittance of the light valve is controlled by a layer of liquid crystals interposed between a pair of polarizers.
  • Light from the source impinging on the first polarizer comprises electromagnetic waves vibrating in a plurality of planes. Only that portion of the light vibrating in the plane of the optical axis of a polarizer can pass through the polarizer.
  • the optical axes of the first and second polarizers are arranged at an angle so that light passing through the first polarizer would normally be blocked from passing through the second polarizer in the series.
  • a layer of translucent liquid crystals occupies a cell gap separating the two polarizers.
  • the physical orientation of the molecules of liquid crystal can be controlled and the plane of vibration of light transiting the columns of molecules spanning the layer can be rotated to either align or not align with the optical axes of the polarizers.
  • the surfaces of the first and second polarizers forming the walls of the cell gap are grooved so that the molecules of liquid crystal immediately adjacent to the cell gap walls will align with the grooves and, thereby, be aligned with the optical axis of the respective polarizer.
  • Molecular forces cause adjacent liquid crystal molecules to attempt to align with their neighbors with the result that the orientation of the molecules in the column spanning the cell gap twist over the length of the column.
  • the plane of vibration of light transiting the column of molecules will be "twisted" from the optical axis of the first polarizer to that of the second polarizer. With the liquid crystals in this orientation, light from the source can pass through the series polarizers of the translucent panel assembly to produce a lighted area of the display surface when viewed from the front of the panel.
  • a voltage typically controlled by a thin film transistor, is applied to an electrode in an array of electrodes deposited on one wall of the cell gap.
  • the liquid crystal molecules adjacent to the electrode are attracted by the field created by the voltage and rotate to align with the field.
  • the column of crystals is "untwisted, " and the optical axes of the crystals adjacent the cell wall are rotated out of alignment with the optical axis of the corresponding polarizer progressively reducing the local transmittance of the light valve and the intensity of the corresponding display pixel.
  • Color LCD displays are created by varying the intensity of transmitted light for each of a plurality of primary color elements (typically, red, green, and blue) that make up a display pixel.
  • LCDs can produce bright, high resolution, color images and are thinner, lighter, and draw less power than cathode ray tubes (CRTs) .
  • CRTs cathode ray tubes
  • LCD usage is pervasive for the displays of portable computers, digital clocks and watches, appliances, audio and video equipment, and other electronic devices.
  • the use of LCDs in certain "high end markets, " such as medical imaging and graphic arts, may demand an even greater dynamic range than available with cathode tube backlight based LCDs.
  • Another type of LCD display construction is to include a light emitting diode based backlight array.
  • a light emitting diode based backlight array permits the individual selection of the luminance for individual elements of the backlight array.
  • By selective illumination of the individual elements different regions of the display may be selectively dimmed or otherwise turned off, which increases the dynamic range of the display.
  • Such a display technique may achieve an even greater dynamic range than a high quality CRT or typical cold cathode fluorescent light based LCD displays.
  • the range of intensity values of image pixels may be modified to account for the increased dynamic range of the display.
  • the resulting images displayed tend to exhibit substantial noise and contouring artifacts, especially in the darker regions of the images.
  • What is desired is a display system that reduces the noise and contouring artifacts, especially in high dynamic range displays.
  • the present invention provides a system and methods for displaying an input image on a display.
  • a method for displaying an input image on a display comprises (a) receiving said input image to be displayed on said display; (b) modifying said image with a filtering process to determine a driving signal for a two-dimensional backlight array of independently selectable light emitting elements of said display; (c) modifying said first modified image with a noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display; (d) wherein said two- dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two- dimensional liquid crystal layer defining said pixels of said display.
  • a method for displaying an input image on a display comprises: (a) receiving said input image to be displayed on said display; (b) separating said input image into a first signal suitable for a two-dimensional backlight array of independently selectable light emitting elements of said display and a second signal suitable for a two-dimensional liquid crystal layer defining pixels of said display; (c) wherein said second signal suitable for said two-dimensional liquid crystal layer further includes a noise reduction process after said separation.
  • a system for displaying an input image on a display comprises: (a) a receiver that receives said input image to be displayed on said display; (b) a first filter that modifies said image with a first filtering process to determine a driving signal for a two- dimensional backlight array of independently selectable light emitting elements of said display; (c) a second filter that modifies the first modified image with a second noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display; (d) wherein said two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two-dimensional liquid crystal layer defining said pixels of said display.
  • FIG. 1 illustrates a display
  • FIG. 2 illustrates different luminance ran
  • FIG. 3 illustrates different dynamic range
  • FIG. 4 illustrates a filtering technique
  • FIG. 5 illustrates a filtering technique
  • FIG. 6 illustrates a filtering technique
  • FIG. 7 illustrates a filtering technique
  • FIG. 8 illustrates a gray level curve .
  • FIG. 9 illustrates a denoising technique .
  • FIG. 10 illustrates a denoise block.
  • FIG. 1 1 illustrates a system for use with filtering techniques .
  • a backlit display 20 comprises, generally, a backlight 22 , a diffuser 24 , and a light valve 26 (indicated by a bracket) that controls the transmittance of light from the backlight 22 to a user viewing an image displayed at the front of the panel 28.
  • the light valve typically comprising a liquid crystal apparatus, is arranged to electronically control the transmittance of light for a picture element or pixel. Since liquid crystals do not emit light, an external source of light is necessary to create a visible image .
  • the source of light for small and inexpensive LCDs, such as those used in digital clocks or calculators, may be light that is reflected from the back surface of the panel after passing through the panel.
  • liquid crystal on silicon (LCOS) devices rely on light reflected from a backplane of the light valve to illuminate a display pixel.
  • LCDs absorb a significant portion of the light passing through the assembly and an artificial source of light such as the backlight 22 comprising fluorescent light tubes or an array of light sources 30 (e.g. , light-emitting diodes (LEDs)) , as illustrated in FIG. 1 , is used to produce pixels of sufficient intensity for highly visible images or to illuminate the display in poor lighting conditions.
  • LEDs light-emitting diodes
  • Light radiating from the light sources 30 of the backlight 22 comprises electromagnetic waves vibrating in random planes. Only those light waves vibrating in the plane of a polarizer' s optical axis can pass through the polarizer.
  • the light valve 26 includes a first polarizer 32 and a second polarizer 34 having optical axes arrayed at an angle so that normally light cannot pass through the series of polarizers. Images are displayable with an LCD because local regions of a liquid crystal layer 36 interposed between the first 32 and second 34 polarizer can be electrically controlled to alter the alignment of the plane of vibration of light relative of the optical axis of a polarizer and, thereby, modulate the transmittance of local regions of the panel corresponding to individual pixels 36 in an array of display pixels.
  • the layer of liquid crystal molecules 36 occupies a cell gap having walls formed by surfaces of the first 32 and second 34 polarizers.
  • the walls of the cell gap are rubbed to create microscopic grooves aligned with the optical axis of the corresponding polarizer.
  • the grooves cause the layer of liquid crystal molecules adjacent to the walls of the cell gap to align with the optical axis of the associated polarizer.
  • each succeeding molecule in the column of molecules spanning the cell gap will attempt to align with its neighbors.
  • the result is a layer of liquid crystals comprising innumerable twisted columns of liquid crystal molecules that bridge the cell gap .
  • a voltage is applied to a spatially corresponding electrode of a rectangular array of transparent electrodes deposited on a wall of the cell gap.
  • the resulting electric field causes molecules of the liquid crystal adjacent to the electrode to rotate toward alignment with the field.
  • the effect is to "untwist" the column of molecules so that the plane of vibration of the light is progressively rotated away from the optical axis of the polarizer as the field strength increases and the local transmittance of the light valve 26 is reduced.
  • the pixel 38 progressively darkens until the maximum extinction of light 40 from the light source 42 is obtained.
  • Color LCD displays are created by varying the intensity of transmitted light for each of a plurality of primary color elements (typically, red, green, and blue) elements making up a display pixel.
  • the backlight 22 comprises an array of locally controllable light sources 30.
  • the individual light sources 30 of the backlight may be light-emitting diodes (LEDs) , an arrangement of phosphors and lenslets, or other suitable light-emitting devices.
  • the individual light sources 30 of the backlight array 22 are independently controllable to output light at a luminance level independent of the luminance level of light output by the other light sources so that a light source can be modulated in response to the luminance of the corresponding image pixel.
  • a data processing unit may extract the luminance of the display pixel from the pixel data if the image is a color image.
  • the luminance signal can be obtained by a weighted summing of the red, green, and blue (RGB) components of the pixel data (e . g. , 0.33R+0.57G+0. 1 I B) . If the image is a black and white image , the luminance is directly available from the image data and the extraction step can be omitted.
  • the luminance signal may be low-pass filtered with a filter having parameters determined by the illumination profile of the light source 30 as affected by the diffuser 24 and properties of the human visual system.
  • the signal is subsampled to obtain a light source illumination signal at spatial coordinates corresponding to the light sources 30 of the backlight array 22.
  • the subsampled luminance signal is used to output a power signal to the light source driver to drive the appropriate light source to output a luminance level according a relationship between the luminance of the image pixel and the luminance of the light source.
  • Modulation of the backlight light sources 30 increases the dynamic range of the LCD pixels primarily by attenuating illumination of "darkened" pixels while the luminance of a "fully on” pixel is typically unchanged.
  • the luminance versus image code values is illustrated for both a CRT display and a traditional LCD display with a cold cathode fluorescent light based backlight.
  • the minimum light level of the traditional LCD is greater than that of the minimum light level of the CRT.
  • Modern LCD displays and modern LED based backlight displays can increase the dynamic range of the LCD display to match or even exceed CRT based displays.
  • FIG. 3 Another illustration graphically illustrates the increase in the dynamic range of displays .
  • the traditional dynamic range of the display is shown, where the input data for the image normally had a bit depth of eight.
  • the input data for the image normally retains the input image bit depth of eight, while the contrast indicated by corresponding code values increases somewhat.
  • the image displayed on the standard LCD and improved LCD has a similar appearance.
  • a "high" dynamic range display typically has an array of LEDs (or other selective light emitting elements) arranged to selectively illuminate different portions of the display.
  • the input data for the image normally retains the input image bit depth of eight, while the contrast per code value indicated by the corresponding code values increases significantly. In some cases, the bit depth of the image is internally increased within the display for processing.
  • the resulting image displayed having a more significant increase in the contrast with code values tends to result in more significant image artifacts, such as contour artifacts and noise boosting.
  • the noise boosting tends to be especially strong in the dark region of the tone scale where the quantum noise and dark current noise tends to dominate.
  • an input image 300 is processed to provide a LED driving signal 302 (first signal) to the LED layer and an LCD driving signal 304 (second signal) to the LCD layer of the display.
  • the input image 300 is received and may be non-linear filtered and sub-sampled in process 306 (first filtering process) in accordance with the LED array.
  • a look up table (“LUT") 308 based upon an LED inverse tone response curve (“TRC”) is used on the filtered sub-sampled in process 306 image data to provide the LED driving signal 302.
  • the non-linear sub-sampled in process 306 image is up- sampled and modified in process 310 to simulate an anticipated illumination of the LED layer.
  • the input image 300 is divided in process 3 12 (division operation) by the up- sampled image in process 310.
  • the resulting liquid crystal layer image 314 together with the backlight should accurately simulate the input image 300.
  • a look up table 316 based upon the LCD inverse TRC is used on the resulting image 3 14 image data.
  • the resulting data from the LUT 3 16 is provided as the LCD driving signal 304.
  • visible noise tends to result from high dynamic range displays, especially strong in the dark region of the tone scale where the quantum noise and dark current noise tends to dominate .
  • an input image 400 is processed by a noise reduction process 420.
  • the noise reduction process 420 may include a low pass filter to attenuate the high frequency content, any filter, a coring operation, subsampling, or otherwise.
  • the noise reduced image from the noise reduction process 420 is processed to provide an LED driving signal 402 to the LED layer and an LCD driving signal 404 to the LCD layer of the display.
  • the noise reduced image in process 420 may be nonlinear filtered and sub-sampled in process 406 in accordance with the LED array.
  • a look up table 408 based upon an LED inverse TRC is used on the filtered sub-sampled in process
  • the non-linear sub-sampled 406 image is up-sampled and modified in process 410 to simulate the illumination of the LED layer.
  • the filtered input image from the noise reduction process 420 is divided in process 4 12 by the up-sampled image in process 4 10.
  • the resulting image 4 14 together with the backlight should accurately simulate the input image 400.
  • a look up table 4 16 based upon the LCD inverse TRC is used on the resulting image 4 14 image data.
  • the resulting data from the LUT 4 16 is provided as the LCD driving signal 404.
  • an input image 500 is processed to provide an LED driving signal 502 (first signal) to the LED layer and an LCD driving signal 504 (second signal) to the LCD layer of the display.
  • the input image 500 is received and may be non-linear filtered and sub-sampled 506 (first filtering process) in accordance with the LED array.
  • a look up table (“LUT") 508 based upon an LED inverse TRC is used on the filtered sub-sampled in process 506 image data to provide the LED driving signal 502.
  • the non-linear sub-sampled in process 506 image is up- sampled and modified in process 510 to simulate an anticipated illumination of the LED layer.
  • the input image 500 is divided in process 5 12 (division operation) by the up-sampled image in process 5 10.
  • the resulting image 514 (a liquid crystal layer image) (after LUT 516) together with the backlight should accurately simulate the input image 500.
  • the resulting image 514 will result in readily visible noise that rises above the visual threshold, due in part to the contrast / code value increase.
  • a noise reduction process 520 (second noise reducing process) may receive the resulting image 514.
  • the process 520 may include a low pass filter, any filter, a coring operation, subsampling, or otherwise .
  • a look up table 5 16 based upon the LCD inverse TRC is used on the resulting image 5 14 (image data 5 14) .
  • the resulting data from the LUT 516 is provided as the LCD driving signal 504.
  • the noise reduction process 520 may be a denoising filter or other spatial enhancement filter applied to the resulting image 5 14. That is, the modification is applied to the image after the input image has been divided by the simulated LED light intensity array. This division amplifies the code values. Further, since the division is normally done at a higher contrast per code value, the various code values having noise of amplitudes + / - 1 or 2 have a much larger range, as well as higher amplitude resolution (because the LED simulation is done at a higher amplitude resolution than the input image) . These factors give the denoising technique more leverage in separating signal from noise when performed after the image division step . This denoising step is preferably performed after the division step, but before the LCD TRC calibration step. That is, the denoising step is preferably done in conjunction within the LED-LCD separation technique.
  • an input image 600 is processed to provide an LED driving signal 602 to the LED layer and an LCD driving signal 604 to the LCD layer of the display.
  • the input image 600 may be non-linear filtered and sub-sampled 606 in accordance with the LED array.
  • a look up table 608 based upon an LED inverse TRC is used on the filtered sub- sampled in process 606 image data to provide the LED driving signal 602.
  • the non-linear sub-sampled image in process 606 is up-sampled and modified in process 610 to simulate the illumination of the LED layer.
  • the input image 600 is divided in process 612 by the up-sampled image in process 610.
  • a noise reduction process 620 may receive the resulting image 614.
  • the process 620 may include a low pass filter, any filter, a coring operation, subsampling, or otherwise .
  • a look up table 616 based upon the LCD inverse TRC is used on the resulting image 614 image data.
  • the resulting data from the LUT 616 is provided as the LCD driving signal 604.
  • the noise reduction process 620 may be a denoising filter or other spatial enhancement filter applied to the LCD resulting image 614.
  • the modification is applied to the image after the input image has been divided by the simulated LED light intensity array.
  • This division amplifies the code values. Further, since the division is normally done at a higher contrast per code value, the various code values having noise of amplitudes + / - 1 or 2 have a much larger range, as well as higher amplitude resolution (because the LED simulation is done at a higher amplitude resolution than the input image) . These factors give the denoising technique more leverage in separating signal from noise when performed after the image division step.
  • This denoising step is preferably performed after the division step, but before the LCD TRC calibration step . That is, the denoising step is preferably done in conjunction within the LED-LCD separation technique.
  • the process 620 may further include a gray level dependency in the denoising technique that is determined not from the resulting image 614 upon which the denoising technique is applied (coming out of the division step) , but rather, is determined based upon the LED image. It can be determined from the LED layer after upsampling and other simulation steps (preferred embodiment) , or it can be determined from the subsampled LED image, or it can be determined from the input image 600. Referring to FIG. 8 , a preferred technique for reducing noise based upon gray levels is tailored for the typical noise visibility using a curve.
  • the gray level input from the LED layer may have a 12 bits (0-4096) range.
  • the dark end may be at 0.
  • the noise reduction factor is used on the LCD layer as a denoising parameter.
  • the preferred technique has a strong noise reduction for the dark areas of the final displayed image.
  • Another technique uses edge selective noise reduction where an edge map also controls the noise reduction factor.
  • the typical polarity of that process is to have weak or no noise reduction around edges.
  • FIG. 9 illustrates a noise reduction technique.
  • An input image 900 is received upon which a LED driving signal 902 is determined based upon LED processing 906.
  • the LED process 906 may include non-liner filtering, sub-sampling, and/ or a look up table.
  • a prediction of the backlight is simulated in process 9 10.
  • a division operation 9 12 devices the input image 900 by the backlight prediction 9 10.
  • a resulting LCD image 9 14 is obtained as a result of the division operation 9 12.
  • a noise reduction process 920 is performed based upon the input image 900 and the LCD image 9 14 resulting in a noise reduced image 922.
  • a look up table may be used to adjust the tone curve and provided as a LCD signal 904 to the LCD layer.
  • FIG. 10 illustrates the noise reduction process 920.
  • the input image 900 is passed through an edge detection mapping process 930.
  • the input image 900 is also based through a blurring mapping process 932 which is based upon the LED resolution of the display.
  • a de-noise map is determined and a thresholding operation 934 is done .
  • the LCD image 9 14 and the input image 900 is provided to a two-channel splitting filter 936.
  • a low pass base channel 938 of the image is determined.
  • a residual channel 940 of the image is determined.
  • the output of the threshold operation 934 , the base channel 938 , and the residual channel 940 are combined together 942 to provide the filtered output 922.
  • FIG. 1 1 illustrates a system that can be used with the above methods .
  • a receiver 1000 receives an input image that is to be displayed on the display.
  • a first filter 1006 modifies the image with a first filtering process to determine a driving signal (LED driving signal 1002) for a two-dimensional backlight array of independently selectable light emitting elements of the display.
  • the first filter 1006 may include a non-linear filter and / or a sub- sampler for sub- sampling the input image .
  • a look up table 1008 based upon an LED inverse TRC is used on the filtered sub- sampled image data from the first filter 1006 to provide the LED driving signal 1002.
  • An up-sampler 1010 then up- samples the non-linear sub-sampled image from the first filter 1006, to simulate an anticipated illumination from said backlight array.
  • the input image from receiver 1000 is then divided 10 12 by the up- sampled image from the up-sampler 1010.
  • the resulting liquid crystal layer image 1014 is then received by a second filter 1020 , which modifies this image with a second noise reducing process to determine a driving signal for a two- dimensional liquid crystal layer defining pixels of
  • the second filter 1020 may be a denoising filter or other spatial enhancement filter applied to the resulting liquid crystal layer image 1014.
  • a look up table 1016 based upon the LCD inverse TRC is used on the resulting image 10 14 image data.
  • the resulting data from the LUT 1016 is provided as the LCD driving signal 1004.
  • the two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of the two-dimensional liquid crystal layer defining the pixels of the display.

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Abstract

The present invention relates to an generally to a system and methods displaying an image on a LCD display. The input image is modified with a first filtering process (506) to determine a driving signal (502) for a two-dimensional backlight array of independently selectable light emitting elements of said display. The first modified image is modified with a second noise reducing process (520) to determine a driving signal (504) for a two-dimensional liquid crystal layer defining pixels of said display. The two-dimensional backlight array has a different density of light emitting elements from a density of pixels of the two-dimensional liquid crystal layer.

Description

DESCRIPTION
TITLE OF INVENTION: COMPENSATED LCD DISPLAY SYSTEM
AND METHODS
TECHNICAL FIELD
The present invention relates generally to a system and methods displaying an image on a LCD display.
BACKGROUND ART
The local transmittance of a liquid crystal display (LCD) panel or a liquid crystal on silicon (LCOS) display can be varied to modulate the intensity of light passing from a backlit source through an area of the panel to produce a pixel that can be displayed at a variable intensity. Whether light from the source passes through the panel to an observer or is blocked, is determined by the orientations of molecules of liquid crystals in a light valve.
Since liquid crystals do not emit light, a visible display requires an external light source. Small and inexpensive LCD panels often rely on light that is reflected back toward the viewer after passing through the panel. Since the panel is not completely transparent, a substantial part of the light is absorbed during its transits of the panel and images displayed on this type of panel may be difficult to see except under the best lighting conditions. On the other hand, LCD panels used for computer displays and video screens are typically backlit with fluorescent tubes or arrays of light- emitting diodes (LEDs) that are built into the sides or back of the panel. To provide a display with a more uniform light level, light from these point or line sources is typically dispersed in a diffuser panel before impinging on the light valve that controls transmission to a viewer.
The transmittance of the light valve is controlled by a layer of liquid crystals interposed between a pair of polarizers. Light from the source impinging on the first polarizer comprises electromagnetic waves vibrating in a plurality of planes. Only that portion of the light vibrating in the plane of the optical axis of a polarizer can pass through the polarizer. In a LCD the optical axes of the first and second polarizers are arranged at an angle so that light passing through the first polarizer would normally be blocked from passing through the second polarizer in the series. However, a layer of translucent liquid crystals occupies a cell gap separating the two polarizers. The physical orientation of the molecules of liquid crystal can be controlled and the plane of vibration of light transiting the columns of molecules spanning the layer can be rotated to either align or not align with the optical axes of the polarizers.
The surfaces of the first and second polarizers forming the walls of the cell gap are grooved so that the molecules of liquid crystal immediately adjacent to the cell gap walls will align with the grooves and, thereby, be aligned with the optical axis of the respective polarizer. Molecular forces cause adjacent liquid crystal molecules to attempt to align with their neighbors with the result that the orientation of the molecules in the column spanning the cell gap twist over the length of the column. Likewise, the plane of vibration of light transiting the column of molecules will be "twisted" from the optical axis of the first polarizer to that of the second polarizer. With the liquid crystals in this orientation, light from the source can pass through the series polarizers of the translucent panel assembly to produce a lighted area of the display surface when viewed from the front of the panel.
To darken a pixel and create an image, a voltage, typically controlled by a thin film transistor, is applied to an electrode in an array of electrodes deposited on one wall of the cell gap. The liquid crystal molecules adjacent to the electrode are attracted by the field created by the voltage and rotate to align with the field. As the molecules of liquid crystal are rotated by the electric field, the column of crystals is "untwisted, " and the optical axes of the crystals adjacent the cell wall are rotated out of alignment with the optical axis of the corresponding polarizer progressively reducing the local transmittance of the light valve and the intensity of the corresponding display pixel. Color LCD displays are created by varying the intensity of transmitted light for each of a plurality of primary color elements (typically, red, green, and blue) that make up a display pixel.
LCDs can produce bright, high resolution, color images and are thinner, lighter, and draw less power than cathode ray tubes (CRTs) . As a result, LCD usage is pervasive for the displays of portable computers, digital clocks and watches, appliances, audio and video equipment, and other electronic devices. On the other hand, the use of LCDs in certain "high end markets, " such as medical imaging and graphic arts, may demand an even greater dynamic range than available with cathode tube backlight based LCDs.
The primary efforts to increase the dynamic range of LCDs have been traditionally directed to improving the properties of materials used in LCD construction. As a result of these efforts, the dynamic range of LCDs has increased since their introduction and high quality LCDs can achieve dynamic ranges of 300: 1 or more . This is comparable to the dynamic range of an average quality CRT when operated in a well-lit room but is considerably less than the 1000 : 1 dynamic range that can be obtained with a well-calibrated CRT in a darkened room or dynamic ranges of up to 3000 : 1 that can be achieved with certain plasma displays.
Another type of LCD display construction is to include a light emitting diode based backlight array. Such an array permits the individual selection of the luminance for individual elements of the backlight array. By selective illumination of the individual elements, different regions of the display may be selectively dimmed or otherwise turned off, which increases the dynamic range of the display. Such a display technique may achieve an even greater dynamic range than a high quality CRT or typical cold cathode fluorescent light based LCD displays. The range of intensity values of image pixels may be modified to account for the increased dynamic range of the display. Unfortunately, the resulting images displayed tend to exhibit substantial noise and contouring artifacts, especially in the darker regions of the images.
What is desired is a display system that reduces the noise and contouring artifacts, especially in high dynamic range displays.
SUMMARY OF INVENTION
The present invention provides a system and methods for displaying an input image on a display.
In one aspect of the invention, a method for displaying an input image on a display comprises (a) receiving said input image to be displayed on said display; (b) modifying said image with a filtering process to determine a driving signal for a two-dimensional backlight array of independently selectable light emitting elements of said display; (c) modifying said first modified image with a noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display; (d) wherein said two- dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two- dimensional liquid crystal layer defining said pixels of said display.
In another aspect of the invention, a method for displaying an input image on a display comprises: (a) receiving said input image to be displayed on said display; (b) separating said input image into a first signal suitable for a two-dimensional backlight array of independently selectable light emitting elements of said display and a second signal suitable for a two-dimensional liquid crystal layer defining pixels of said display; (c) wherein said second signal suitable for said two-dimensional liquid crystal layer further includes a noise reduction process after said separation.
In another aspect of the invention, a system for displaying an input image on a display comprises: (a) a receiver that receives said input image to be displayed on said display; (b) a first filter that modifies said image with a first filtering process to determine a driving signal for a two- dimensional backlight array of independently selectable light emitting elements of said display; (c) a second filter that modifies the first modified image with a second noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display; (d) wherein said two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two-dimensional liquid crystal layer defining said pixels of said display.
The foregoing and other objectives, features, and advantages of the invention will be more readily understood upon consideration of the following detailed description of the invention, taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 illustrates a display.
FIG. 2 illustrates different luminance ran
FIG. 3 illustrates different dynamic range
FIG. 4 illustrates a filtering technique.
FIG. 5 illustrates a filtering technique .
FIG. 6 illustrates a filtering technique .
FIG. 7 illustrates a filtering technique .
FIG. 8 illustrates a gray level curve .
FIG. 9 illustrates a denoising technique .
FIG. 10 illustrates a denoise block. FIG. 1 1 illustrates a system for use with filtering techniques .
DESCRIPTION OF EMBODIMENTS
Referring to FIG . 1 , a backlit display 20 comprises, generally, a backlight 22 , a diffuser 24 , and a light valve 26 (indicated by a bracket) that controls the transmittance of light from the backlight 22 to a user viewing an image displayed at the front of the panel 28. The light valve, typically comprising a liquid crystal apparatus, is arranged to electronically control the transmittance of light for a picture element or pixel. Since liquid crystals do not emit light, an external source of light is necessary to create a visible image . The source of light for small and inexpensive LCDs, such as those used in digital clocks or calculators, may be light that is reflected from the back surface of the panel after passing through the panel. Likewise, liquid crystal on silicon (LCOS) devices rely on light reflected from a backplane of the light valve to illuminate a display pixel. However, LCDs absorb a significant portion of the light passing through the assembly and an artificial source of light such as the backlight 22 comprising fluorescent light tubes or an array of light sources 30 (e.g. , light-emitting diodes (LEDs)) , as illustrated in FIG. 1 , is used to produce pixels of sufficient intensity for highly visible images or to illuminate the display in poor lighting conditions. There may not be a light source 30 for each pixel of the display and, therefore, the light from the point or line sources is typically dispersed by a diffuser panel 24 so that the lighting of the front surface of the panel 28 is more uniform. In most cases, the density of light sources is substantially less than that of the individual pixels of the liquid crystal layer.
Light radiating from the light sources 30 of the backlight 22 comprises electromagnetic waves vibrating in random planes. Only those light waves vibrating in the plane of a polarizer' s optical axis can pass through the polarizer. The light valve 26 includes a first polarizer 32 and a second polarizer 34 having optical axes arrayed at an angle so that normally light cannot pass through the series of polarizers. Images are displayable with an LCD because local regions of a liquid crystal layer 36 interposed between the first 32 and second 34 polarizer can be electrically controlled to alter the alignment of the plane of vibration of light relative of the optical axis of a polarizer and, thereby, modulate the transmittance of local regions of the panel corresponding to individual pixels 36 in an array of display pixels.
The layer of liquid crystal molecules 36 occupies a cell gap having walls formed by surfaces of the first 32 and second 34 polarizers. The walls of the cell gap are rubbed to create microscopic grooves aligned with the optical axis of the corresponding polarizer. The grooves cause the layer of liquid crystal molecules adjacent to the walls of the cell gap to align with the optical axis of the associated polarizer. As a result of molecular forces, each succeeding molecule in the column of molecules spanning the cell gap will attempt to align with its neighbors. The result is a layer of liquid crystals comprising innumerable twisted columns of liquid crystal molecules that bridge the cell gap . As light 40 originating at a light source element 42 and passing through the first polarizer 32 passes through each translucent molecule of a column of liquid crystals, its plane of vibration is "twisted" so that when the light reaches the far side of the cell gap its plane of vibration will be aligned with the optical axis of the second polarizer 34. The light 44 vibrating in the plane of the optical axis of the second polarizer 34 can pass through the second polarizer to produce a lighted pixel 38 at the front surface of the display 28.
To darken the pixel 38 , a voltage is applied to a spatially corresponding electrode of a rectangular array of transparent electrodes deposited on a wall of the cell gap. The resulting electric field causes molecules of the liquid crystal adjacent to the electrode to rotate toward alignment with the field. The effect is to "untwist" the column of molecules so that the plane of vibration of the light is progressively rotated away from the optical axis of the polarizer as the field strength increases and the local transmittance of the light valve 26 is reduced. As the transmittance of the light valve 26 is reduced, the pixel 38 progressively darkens until the maximum extinction of light 40 from the light source 42 is obtained. Color LCD displays are created by varying the intensity of transmitted light for each of a plurality of primary color elements (typically, red, green, and blue) elements making up a display pixel.
In the backlit display 20 with extended dynamic range, the backlight 22 comprises an array of locally controllable light sources 30. The individual light sources 30 of the backlight may be light-emitting diodes (LEDs) , an arrangement of phosphors and lenslets, or other suitable light-emitting devices. The individual light sources 30 of the backlight array 22 are independently controllable to output light at a luminance level independent of the luminance level of light output by the other light sources so that a light source can be modulated in response to the luminance of the corresponding image pixel.
A data processing unit may extract the luminance of the display pixel from the pixel data if the image is a color image. For example, the luminance signal can be obtained by a weighted summing of the red, green, and blue (RGB) components of the pixel data (e . g. , 0.33R+0.57G+0. 1 I B) . If the image is a black and white image , the luminance is directly available from the image data and the extraction step can be omitted. The luminance signal may be low-pass filtered with a filter having parameters determined by the illumination profile of the light source 30 as affected by the diffuser 24 and properties of the human visual system. Following filtering, the signal is subsampled to obtain a light source illumination signal at spatial coordinates corresponding to the light sources 30 of the backlight array 22. As the rasterized image pixel data are sequentially used to drive the display pixels of the LCD light valve 26, the subsampled luminance signal is used to output a power signal to the light source driver to drive the appropriate light source to output a luminance level according a relationship between the luminance of the image pixel and the luminance of the light source. Modulation of the backlight light sources 30 increases the dynamic range of the LCD pixels primarily by attenuating illumination of "darkened" pixels while the luminance of a "fully on" pixel is typically unchanged.
Referring to FIG. 2 , the luminance versus image code values is illustrated for both a CRT display and a traditional LCD display with a cold cathode fluorescent light based backlight. As it may be observed, the minimum light level of the traditional LCD is greater than that of the minimum light level of the CRT. Modern LCD displays and modern LED based backlight displays can increase the dynamic range of the LCD display to match or even exceed CRT based displays.
Referring to FIG. 3 , another illustration graphically illustrates the increase in the dynamic range of displays . The traditional dynamic range of the display is shown, where the input data for the image normally had a bit depth of eight.
With improved backlight technology, such as light emitting diodes directed from the periphery of the display, the dynamic range increased somewhat. The input data for the image normally retains the input image bit depth of eight, while the contrast indicated by corresponding code values increases somewhat. The image displayed on the standard LCD and improved LCD has a similar appearance. A "high" dynamic range display typically has an array of LEDs (or other selective light emitting elements) arranged to selectively illuminate different portions of the display. The input data for the image normally retains the input image bit depth of eight, while the contrast per code value indicated by the corresponding code values increases significantly. In some cases, the bit depth of the image is internally increased within the display for processing. The resulting image displayed having a more significant increase in the contrast with code values tends to result in more significant image artifacts, such as contour artifacts and noise boosting. The noise boosting tends to be especially strong in the dark region of the tone scale where the quantum noise and dark current noise tends to dominate.
Referring to FIG. 4, an input image 300 is processed to provide a LED driving signal 302 (first signal) to the LED layer and an LCD driving signal 304 (second signal) to the LCD layer of the display. The input image 300 is received and may be non-linear filtered and sub-sampled in process 306 (first filtering process) in accordance with the LED array. A look up table ("LUT") 308 based upon an LED inverse tone response curve ("TRC") is used on the filtered sub-sampled in process 306 image data to provide the LED driving signal 302. The non-linear sub-sampled in process 306 image is up- sampled and modified in process 310 to simulate an anticipated illumination of the LED layer. The input image 300 is divided in process 3 12 (division operation) by the up- sampled image in process 310. The resulting liquid crystal layer image 314 together with the backlight should accurately simulate the input image 300. A look up table 316 based upon the LCD inverse TRC is used on the resulting image 3 14 image data. The resulting data from the LUT 3 16 is provided as the LCD driving signal 304. Unfortunately, visible noise tends to result from high dynamic range displays, especially strong in the dark region of the tone scale where the quantum noise and dark current noise tends to dominate .
Referring to FIG. 5 , one potential way to reduce visible noise, an input image 400 is processed by a noise reduction process 420. The noise reduction process 420 may include a low pass filter to attenuate the high frequency content, any filter, a coring operation, subsampling, or otherwise. The noise reduced image from the noise reduction process 420 is processed to provide an LED driving signal 402 to the LED layer and an LCD driving signal 404 to the LCD layer of the display. The noise reduced image in process 420 may be nonlinear filtered and sub-sampled in process 406 in accordance with the LED array. A look up table 408 based upon an LED inverse TRC is used on the filtered sub-sampled in process
406 image data to provide the LED driving signal 402. The non-linear sub-sampled 406 image is up-sampled and modified in process 410 to simulate the illumination of the LED layer. The filtered input image from the noise reduction process 420 is divided in process 4 12 by the up-sampled image in process 4 10. The resulting image 4 14 together with the backlight should accurately simulate the input image 400. A look up table 4 16 based upon the LCD inverse TRC is used on the resulting image 4 14 image data. The resulting data from the LUT 4 16 is provided as the LCD driving signal 404.
Unfortunately, visible noise tends to result from high dynamic range displays, even with the noise reduction process 420, being especially strong in the dark region of the tone scale where the quantum noise and dark current noise tends to dominate. The problem with this technique of pre-filtering the image is that the noise signal in the problematic areas are very low, such as 1 or 2 code values, and signals of importance are in this range as well. Normally such code value differences are difficult to see (especially in the dark end of the tone scale) , particularly for noise which has significant high frequency content (and thus below threshold due to high spatial frequency) . However, once the contrast/ code value is increased by a higher dynamic range display, these values get amplified in the luminance domain, and rise above the visual threshold.
Referring to FIG. 6, an input image 500 is processed to provide an LED driving signal 502 (first signal) to the LED layer and an LCD driving signal 504 (second signal) to the LCD layer of the display. The input image 500 is received and may be non-linear filtered and sub-sampled 506 (first filtering process) in accordance with the LED array. A look up table ("LUT") 508 based upon an LED inverse TRC is used on the filtered sub-sampled in process 506 image data to provide the LED driving signal 502. The non-linear sub-sampled in process 506 image is up- sampled and modified in process 510 to simulate an anticipated illumination of the LED layer. The input image 500 is divided in process 5 12 (division operation) by the up-sampled image in process 5 10. The resulting image 514 (a liquid crystal layer image) (after LUT 516) together with the backlight should accurately simulate the input image 500. Unfortunately, the resulting image 514 will result in readily visible noise that rises above the visual threshold, due in part to the contrast / code value increase. A noise reduction process 520 (second noise reducing process) may receive the resulting image 514. The process 520 may include a low pass filter, any filter, a coring operation, subsampling, or otherwise . A look up table 5 16 based upon the LCD inverse TRC is used on the resulting image 5 14 (image data 5 14) . The resulting data from the LUT 516 is provided as the LCD driving signal 504.
The noise reduction process 520 may be a denoising filter or other spatial enhancement filter applied to the resulting image 5 14. That is, the modification is applied to the image after the input image has been divided by the simulated LED light intensity array. This division amplifies the code values. Further, since the division is normally done at a higher contrast per code value, the various code values having noise of amplitudes + / - 1 or 2 have a much larger range, as well as higher amplitude resolution (because the LED simulation is done at a higher amplitude resolution than the input image) . These factors give the denoising technique more leverage in separating signal from noise when performed after the image division step . This denoising step is preferably performed after the division step, but before the LCD TRC calibration step. That is, the denoising step is preferably done in conjunction within the LED-LCD separation technique.
Referring to FIG. 7 , an input image 600 is processed to provide an LED driving signal 602 to the LED layer and an LCD driving signal 604 to the LCD layer of the display. The input image 600 may be non-linear filtered and sub-sampled 606 in accordance with the LED array. A look up table 608 based upon an LED inverse TRC is used on the filtered sub- sampled in process 606 image data to provide the LED driving signal 602. The non-linear sub-sampled image in process 606 is up-sampled and modified in process 610 to simulate the illumination of the LED layer. The input image 600 is divided in process 612 by the up-sampled image in process 610. The resulting image 6 14 (after LUT 616) together with the backlight should accurately simulate the input image 600. Unfortunately, the resulting image 614 will result in readily visible noise that rises above the visual threshold, due in part to the contrast / code value increase. A noise reduction process 620 may receive the resulting image 614. The process 620 may include a low pass filter, any filter, a coring operation, subsampling, or otherwise . A look up table 616 based upon the LCD inverse TRC is used on the resulting image 614 image data. The resulting data from the LUT 616 is provided as the LCD driving signal 604. The noise reduction process 620 may be a denoising filter or other spatial enhancement filter applied to the LCD resulting image 614. That is, the modification is applied to the image after the input image has been divided by the simulated LED light intensity array. This division amplifies the code values. Further, since the division is normally done at a higher contrast per code value, the various code values having noise of amplitudes + / - 1 or 2 have a much larger range, as well as higher amplitude resolution (because the LED simulation is done at a higher amplitude resolution than the input image) . These factors give the denoising technique more leverage in separating signal from noise when performed after the image division step. This denoising step is preferably performed after the division step, but before the LCD TRC calibration step . That is, the denoising step is preferably done in conjunction within the LED-LCD separation technique. The process 620 may further include a gray level dependency in the denoising technique that is determined not from the resulting image 614 upon which the denoising technique is applied (coming out of the division step) , but rather, is determined based upon the LED image. It can be determined from the LED layer after upsampling and other simulation steps (preferred embodiment) , or it can be determined from the subsampled LED image, or it can be determined from the input image 600. Referring to FIG. 8 , a preferred technique for reducing noise based upon gray levels is tailored for the typical noise visibility using a curve. The gray level input from the LED layer may have a 12 bits (0-4096) range. The dark end may be at 0. The noise reduction factor is used on the LCD layer as a denoising parameter. The preferred technique has a strong noise reduction for the dark areas of the final displayed image.
Another technique uses edge selective noise reduction where an edge map also controls the noise reduction factor. The typical polarity of that process is to have weak or no noise reduction around edges.
FIG. 9 illustrates a noise reduction technique. An input image 900 is received upon which a LED driving signal 902 is determined based upon LED processing 906. The LED process 906 may include non-liner filtering, sub-sampling, and/ or a look up table. Based upon the LED process 906 a prediction of the backlight is simulated in process 9 10. A division operation 9 12 devices the input image 900 by the backlight prediction 9 10. A resulting LCD image 9 14 is obtained as a result of the division operation 9 12. A noise reduction process 920 is performed based upon the input image 900 and the LCD image 9 14 resulting in a noise reduced image 922. A look up table may be used to adjust the tone curve and provided as a LCD signal 904 to the LCD layer.
FIG. 10 illustrates the noise reduction process 920. The input image 900 is passed through an edge detection mapping process 930. The input image 900 is also based through a blurring mapping process 932 which is based upon the LED resolution of the display. A de-noise map is determined and a thresholding operation 934 is done . The LCD image 9 14 and the input image 900 is provided to a two-channel splitting filter 936. A low pass base channel 938 of the image is determined. A residual channel 940 of the image is determined. The output of the threshold operation 934 , the base channel 938 , and the residual channel 940 are combined together 942 to provide the filtered output 922.
FIG. 1 1 illustrates a system that can be used with the above methods . In this system a receiver 1000 receives an input image that is to be displayed on the display.
A first filter 1006 modifies the image with a first filtering process to determine a driving signal (LED driving signal 1002) for a two-dimensional backlight array of independently selectable light emitting elements of the display. The first filter 1006 may include a non-linear filter and / or a sub- sampler for sub- sampling the input image . A look up table 1008 based upon an LED inverse TRC is used on the filtered sub- sampled image data from the first filter 1006 to provide the LED driving signal 1002. An up-sampler 1010 then up- samples the non-linear sub-sampled image from the first filter 1006, to simulate an anticipated illumination from said backlight array. The input image from receiver 1000 is then divided 10 12 by the up- sampled image from the up-sampler 1010. The resulting liquid crystal layer image 1014 is then received by a second filter 1020 , which modifies this image with a second noise reducing process to determine a driving signal for a two- dimensional liquid crystal layer defining pixels of the display.
The second filter 1020 may be a denoising filter or other spatial enhancement filter applied to the resulting liquid crystal layer image 1014. A look up table 1016 based upon the LCD inverse TRC is used on the resulting image 10 14 image data. The resulting data from the LUT 1016 is provided as the LCD driving signal 1004.
In this system, the two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of the two-dimensional liquid crystal layer defining the pixels of the display.
The terms and expressions which have been employed in the foregoing specification are used therein as terms of description and not of limitation, and there is no intention, in the use of such terms and expressions, of excluding equivalents of the features shown and described or portions thereof, it being recognized that the scope of the invention is defined and limited only by the claims which follow.

Claims

1. A method for displaying an input image on a display comprising:
(a) receiving said input image to be displayed on said display;
(b) modifying said image with a first filtering process to determine a driving signal for a two-dimensional backlight array of independently selectable light emitting elements of said display;
(c) modifying said first modified image with a second noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display;
(d) wherein said two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two-dimensional liquid crystal layer defining said pixels of said display.
2. The method of claim 1 wherein said first filtering process non-linear filters said input image.
3. The method of claim 1 wherein said first filtering process sub-samples said input image .
4. The method of claim 1 wherein said first filtering process non-linear filters and sub-samples said input image .
5. The method of claim 4 further including up- sampling said first modified input image to simulate an anticipated illumination from said backlight array.
6. The method of claim 5 further including creating a liquid crystal layer image based upon said up- sampled first modified input image and said input image .
7. The method of claim 6 wherein said liquid crystal layer image is filtered by said second noise reducing process.
8. The method of claim 7 wherein said creating said liquid crystal layer image is based upon a division operation.
9. A method for displaying an input image on a display comprising:
(a) receiving said input image to be displayed on said display;
(b) separating said input image into a first signal suitable for a two-dimensional backlight array of independently selectable light emitting elements of said display and a second signal suitable for a two-dimensional liquid crystal layer defining pixels of said display;
(c) wherein said second signal suitable for said two- dimensional liquid crystal layer further includes a noise reduction process after said separation.
10. A system for displaying an input image on a display comprising:
(a) a receiver that receives said input image to be displayed on said display;
(b) a first filter that modifies said image with a first filtering process to determine a driving signal for a two- dimensional backlight array of independently selectable light emitting elements of said display;
(c) a second filter that modifies the first modified image with a second noise reducing process to determine a driving signal for a two-dimensional liquid crystal layer defining pixels of said display;
(d) wherein said two-dimensional backlight array has a density of light emitting elements that is different from a density of pixels of said two-dimensional liquid crystal layer defining said pixels of said display.
1 1 . The system of claim 10 wherein said first filter eludes a non-linear filter.
12. The system of claim 10 wherein said first filter includes a sub-sampler for sub-sampling said input image .
13. The system of claim 10 wherein said first filter includes a non-linear filter and a sub- sampler for sub- sampling said input image.
14. The system of claim 13 further including an up- sampler that up- samples said first modified input image to simulate an anticipated illumination from said backlight array.
15. The system of claim 10 wherein the second filter is a denoising filter.
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EP2504734A4 (en) 2013-03-20
JP5502209B2 (en) 2014-05-28
CN102713734A (en) 2012-10-03
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