2) the magnitude of the differential transmittance may be dependent on the backlight drive levels, such that the envelope shape remains relatively constant across this range.

3) For a type 1 LCD panel, the magnitude of the envelope increases monotonically with increasing backlight drive; for a type 2 LCD panel, the magnitude of this envelope decreases monotonically with increasing backlight drive. [00057] Based on these observations, a separable model for the LCD response as a function of LCD code c_i and backlight power vector ? may be constructed:

where

[00058] In the above expression, p_i is a strength coefficient for channel i, positive for a type 1 LCD panel, negative for type 2 LCD panel; ∈[0,1] is a nonlinear“power”

function, common across channels, describing the change in transmittance vs. backlight power;

∈[0,1] is the envelope function for channel i, such that

[00059] FIG.9 is the differential LCD response versus the relative code values for different LED drive levels for a type 1 LCD panel.

[00060] Figure 9 for type 1 monitors, WLED at 127 input for red is 920, green is 932 and blue is 944, WLED at 255 input for red is 918, green is 930 and blue is 942, WLED at 511 input for red is 916, green is 928 and blue is 940, WLED at 1023 input for red is 914, green is 926 and blue is 938, WLED at 2047 input for red is 912, green is 924 and blue is 936 and WLED at 4095 input for red is 910, green is 922 and blue is 934.

[00061] FIG.10 is the differential LCD response versus the relative code values for different LED drive levels for a type 2 LCD panel.

[00062] Figure 10 for type 2 monitors, WLED at 127 input for red is 1020, green is 1032 and blue is 1044, WLED at 255 input for red is 1018, green is 1030 and blue is 1042, WLED at 511 input for red is 1016, green is 1028 and blue is 1040, WLED at 1023 input for red is 1014, green is 1026 and blue is 1038, WLED at 2047 input for red is 1012, green is 1024 and blue is 1036 and WLED at 4095 input for red is 1010, green is 1022 and blue is 1034.

[00063] For examples of the type 1 LCD panel FIG.11 and type 2 LCD panels FIG.12, the model parameters are summarized in the table below. Using these model components, the fit to the measured data from Figure 8-9 is shown in FIG.11 for type 1 LCD panels and FIG. 12 for type 2 LCD panels. This indicates that one model may be used to adequately describe the response of two LCD panel designs that have very different characteristics. This model may describe other LCD panels as well, provided a characterization is performed to determine the envelope and power functions, as well as the strength and backlight energy coefficients. This characterization may not be required per panel but instead may apply across a fleet as it describes the deviation of the gamma response relative to the low intensity measurement with respect to different backlight intensity levels.

[00064] Figure 11 depicts type 1 envelope functions for red 1112, green 1114 and blue 1110 and on the right the energy function data is 1116 and the curve fit is 1118.

[00065] Figure 12 depicts type 2 envelope functions for red 1212, green 1214 and blue 1210 and on the right the energy function data is 1216 and the curve fit is 1218. [00066] Table 1: LCD Model Parameters

Type 1 LCD Type 2 LCD p_R = 0.1653 p_R = -0.1085

Strength coefs, p: p_G = 0.1411 p_G = -0.1196

p_B = 0.1243 p_B = -0.0933

b^acklight

e_nergy: s = 0.33R + 0.33G + 0.33B s = 0.42R + 0.33G + 0.25B [00067] For the type 1 LCD panels FIG.13 and type 2 LCD panels FIG.14, the model parameters are summarized in the table above. Using these model components, the fit is to the measured data from the type 1 LCD panels FIG 9 and type 2 LCD panels FIG 10.

[00068] Figure 13 for type 1 monitors, WLED at 127 input for red is 1320, green is 1332 and blue is 1344, WLED at 255 input for red is 1318, green is 1330 and blue is 1342, WLED at 511 input for red is 1316, green is 1328 and blue is 1340, WLED at 1023 input for red is 1314, green is 1326 and blue is 1338, WLED at 2047 input for red is 1312, green is 1324 and blue is 1336 and WLED at 4095 input for red is 1310, green is 1322 and blue is 1334.

[00069] Figure 14 for type 2 monitors, WLED at 127 input for red is 1420, green is 1432 and blue is 1444, WLED at 255 input for red is 1418, green is 1430 and blue is 1442, WLED at 511 input for red is 1416, green is 1428 and blue is 1440, WLED at 1023 input for red is 1414, green is 1426 and blue is 1438, WLED at 2047 input for red is 1412, green is 1424 and blue is 1436 and WLED at 4095 input for red is 1410, green is 1422 and blue is 1434.

[00070] Equipped with a basic configurable model it is then possible to construct a correction algorithm. In this case, it is sought to achieve an LCD response mimicking that measured at low back light intensity levels, In other words, at a particular backlight

drive intensity, the LCD code words may be perturbed to compensate for the effects of the backlight power levels such that the target transmittance is achieved. Given the previously derived transmittance model,

[00071] Equation (3) may be inverted to find the change in LCD code value Δc_i that may produce a transmittance equal to

. A first-order Taylor expansion may be used estimate the perturbation

Equation (4) may be further approximated with the realization that is generally

much smaller than unity,

where:

[00072] L⁰ and L¹ are denoted first and second order correction functions, and may be represented as polynomial functions, or preferably as one dimensional look up tables (ID LUT). These correction functions are dependent on one variable, the LCD relative code value Ci.

[00073] Figures 15 and 16 show examples of the correction functions for the type 1 LCD panels and type 2 LCD panels respectively. The first order correction functions show opposite polarity for the type 1 and type 2 LCD panels. The second order correction functions are generally much smaller in magnitude relative to L⁰ , the relative strength becomes greater near relative code = 0.9.

[00074] FIG. 15 depicts correction functions L⁰ 1510 and L¹ 1512 for type 1 LCD panels. Red is designated by 1514 and 1520, green is designated by 1512 and 1518 and blue is designated by 1510 and 1516.

[00075] FIG. 16 depicts correction function Ls⁰ 1610 and L¹ 1612 for type 2 LCD panels. Red is designated by 1612 and 1618, green is designated by 1610 and 1620 and blue is designated by 1614 and 1616. [00076] Equipped the model and its subsequent inversion, it is now possible to construct the steps for LCD compensation for LCD pixel sites:

1) Estimate the R, G, and B backlight optical power levels based on the light field

simulation (LFS) associated with the individual backlight drives, such as a tristimulus XYZ value corresponding to the LCD channel. Summing these three produces one tristimulus se

t XYZ_LFS which may be used to estimate the relative R,G,B backlight p^{ower levels,}

where N is a 3x3 matrix.

2) Determine the backlight power_?

correspond to the backlight energy coefficients

3) Determine the value of the power function q(s), usually a low order polynomial or a (real-valued) Laurent series.

4) Determine the initial LCD code value by inverting

– note that this step

may already be performed in a dual-modulation pipeline without the LCD compensation, it has been included here for completeness.

5) Determine the L0 and L1 values from This may be performed via a polynomial,

or preferably using an m-bit 1D lookup table, where m may be 16.

6) Determine the corrected LCD code value:

Note that for some LCD panels, utilizing only a first order correction term (L0) may be sufficient and thus would reduce the overall computation. LCD Emulation

[00077] In certain cases, it may be desirable to emulate the behavior of a particular LCD model’s response. For example, if content has been mastered on monitors using type 1 LCD panels without LCD compensation, it may be required to have the content appear visually equivalent on monitors constructed using type 2 LCD panels. Colorists and other creatives may not wish to apply a trim based on which LCD panel is used. The same algorithm described in equation (7) may be used to cause one LCD panel to emulate the lightfield- dependent behavior of another, for example, emulating the differential response of the type 1 LCD panel on a type 2 LCD panel.

[00078] In this case, the target transmittance may be that of the destination device. The c^{ode value correction may become:}

where:

[00079] In equations (8) and (9), the“d” superscript refers to the destination LCD panel. The first and second order emulation functions for type 1 LCD panel emulation of type 2 LCD panels and vice-versa are shown in Figures 17-18 respectively. In this example, the magnitude of these functions is greater than those shown in Figures 15-16, as the emulation will cause the panel, type 2 LCD panel, to a response beyond correction to approximate the behavior of the target LCD, type 1 LCD panel. Thus it may be possible to emulate the properties of a target LCD panel using the same algorithm as described for correction, except for the use of different L0 and L1 functions.

[00080] With these algorithms in place, it may be possible to achieve a visual match when using two monitors with different LCD panel models, type 1 and type 2. The algorithm itself is efficient, and imposes a 1-2% increase in processing time for the pipeline. It is expected this algorithm may be applied to a variety of other LCD panels with similar results.

[00081] FIG.17 Emulation functions L⁰1710 and L¹1712 for type 1 LCD panels emulating type 2 LCD panels. Red is designated by 1714 and 1720, green is designated by 1712 and 1718 and blue is designated by 1710 and 1716.

[00082] FIG.18 Emulation functions L⁰1810 and L¹1812 for type 2 LCD panels emulating type 1 LCD panels. Red is designated by 1810 and 1820, green is designated by 1812 and 1818 and blue is designated by 1814 and 1816. [00083] FIG.19 depicts a method for compensation of liquid crystal display response variations in high brightness fields, comprising receiving 1910 an image signal having a set of initial liquid crystal display code values for a region, estimating 1912 individual backlight power levels for the region of the image signal, determining 1914 a combined backlight power level based on the individual backlight power levels of the region, determining 1916 at least one change in transmittance based on the combined backlight power level of the region, and correcting 1918 the set of initial liquid crystal display code values based in the determined at least one change in transmittance.

[00084] FIG.20 depicts a method for compensation of liquid crystal display response variations in high brightness fields, comprising receiving 2010 an image signal having a set of initial liquid crystal display code values for a region, estimating 2012 individual backlight power levels for the region, determining 2014 a combined backlight power level based on the individual backlight power levels of the region, determining 2016 at least one delta change in transmittance based on the combined backlight power level of the region and a reference power level, correcting 2018 the set of initial liquid crystal display code values based in the determined at least one delta change in transmittance.

[00085] FIG.21 depicts a method for compensation of liquid crystal display response variations in high brightness fields, comprising receiving 2110 an image signal, estimating 2112 a plurality of colors for a region of the image signal, estimating 2114 a plurality of backlight power levels for the region, measuring 2116 the transmittance for the plurality of colors and the plurality of backlight power levels, modelling 2118 the measured

transmittance.

[00086] FIG.22 depicts an apparatus that compensates for liquid crystal display response variations in high brightness fields, comprising a power measurement device 2216 coupled to a local backlight array 2210 of the liquid crystal display, a compensation module 2218 coupled to the power measurement device and the liquid crystal display, wherein the compensation module, modulates a set of initial liquid crystal display code values based on a measured power.

[00087] FIG.23 depicts an apparatus that compensates for liquid crystal display response variations in high brightness fields, comprising a reflected optical power measurement device 2316 coupled to a local backlight array 2310 of the liquid crystal display, a compensation module 2318 coupled to the reflected optical power measurement device and the liquid crystal display, wherein the compensation module, modulates a set of initial liquid crystal display code values based on a reflected optical power.

[00088] The method described in the present disclosure may be implemented in hardware, software, firmware or any combination thereof. Features described as blocks, modules or components may be implemented together (e.g., in a logic device such as an integrated logic device) or separately (e.g., as separate connected logic devices). The software portion of the methods of the present disclosure may comprise a computer-readable medium which comprises instructions that, when executed, perform, at least in part, the described methods. The computer-readable medium may comprise, for example, a random access memory (RAM) and/or a read-only memory (ROM). The instructions may be executed by a processor (e.g., a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable logic array (FPGA), a graphic processing unit (GPU) or a general purpose GPU). EQUIVALENTS, EXTENSIONS, ALTERNATIVES AND MISCELLANEOUS [00089] Example embodiments that relate to LCD gamma compensation based on brightness are thus described. In the foregoing specification, embodiments of the present disclosure have been described with reference to numerous specific details that may vary from implementation to implementation. Thus, the sole and exclusive indicator of what is the invention, and is intended by the applicants to be the invention, is the set of claims that issue from this application, in the specific form in which such claims issue, including any subsequent correction. Any definitions expressly set forth herein for terms contained in such claims shall govern the meaning of such terms as used in the claims. Hence, no limitation, element, property, feature, advantage or attribute that is not expressly recited in a claim should limit the scope of such claim in any way. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.

[00090] Various aspects of the present invention may be appreciated from the following enumerated example embodiments (EEEs).

EEE 1. A method for compensation of liquid crystal display response variations in high brightness fields with a processor, the method comprising:

receiving an image signal having a set of initial liquid crystal display code values for a region; estimating individual backlight power levels for the region of the image signal;

determining a combined backlight power level based on the individual backlight power levels of the region;

determining at least one change in transmittance based on the combined backlight power level of the region; and

correcting the set of initial liquid crystal display code values based in the determined at least one change in transmittance.

EEE 2. The method of EEE 1 wherein the estimating individual backlight power levels of the region is based on a light field simulation.

EEE 3. The method of EEE 1 or EEE2 wherein the estimating individual backlight power levels of the region is a three by three matrix for red, blue and green.

EEE 4. The method of any preceding EEE wherein the combined backlight power level is for red, blue and green.

EEE 5. The method of any preceding EEE wherein the at least one change in transmittance is an inversion of a measured transmittance at a reference power setting.

EEE 6. The method of any preceding EEE wherein the set of initial liquid crystal display code values is based on a look up table.

EEE 7. The method of any preceding EEE further comprising quantizing the corrected set of initial liquid crystal display codes.

EEE 8. The method of any preceding EEE wherein the determining at least one change in transmittance is based on a polynomial.

EEE 9. A method for compensation of liquid crystal display response variations in high brightness fields with a processor, the method comprising:

receiving an image signal having a set of initial liquid crystal display code values for a region;

estimating individual backlight power levels for the region;

determining at least one delta change in transmittance based on the combined

backlight power level of the region and a reference; and

correcting the set of initial liquid crystal display code values based in the determined at least one delta change in transmittance. EEE 10. The method of EEE 9 wherein the estimating individual backlight power levels of the region is based on a light field simulation.

EEE 11. The method of EEE 9 or EEE 10 wherein the estimating individual backlight power levels of the region is a three by three matrix for red, blue and green.

EEE 12. The method of any one of EEEs 9 to 11 wherein the combined backlight power level is for red, blue and green.

EEE 13. The method of any one of EEEs 9 to 12 wherein the at least one change in

transmittance is an inversion of a measured transmittance at a reference power setting.

EEE 14. The method of any one of EEEs 9 to 13 wherein the set of initial liquid crystal display code values is based on a look up table.

EEE 15. The method of any one of EEEs 9 to 14 further comprising quantizing the corrected set of initial liquid crystal display codes.

EEE 16. The method of any one of EEEs 9 to 15wherein the determining at least one change in transmittance is based on a polynomial.

EEE 17. A method for compensation of liquid crystal display response variations in high brightness fields with a processor, the method comprising:

receiving an image signal;

estimating a plurality of colors for a region of the image signal;

estimating a plurality of backlight power levels for the region;

measuring a transmittance for the plurality of colors and the plurality of backlight power levels; and

modelling the measured transmittance.

EEE 18. The method of EEE 17 further comprising creating a look up table based on the modelled transmittance.

EEE 19. The method of EEE 17 or EEE 18 further comprising creating an inverse look up table based on the modelled transmittance.

EEE 20. An apparatus that compensates for liquid crystal display response variations in high brightness fields, comprising:

a power measurement device coupled to a local backlight array of the liquid crystal display;

a compensation module coupled to said power measurement device and said liquid crystal display; and wherein said compensation module, modulates a set of initial liquid crystal display code values based on a measured power.

EEE 21. The apparatus of EEE 20 wherein the compensation module estimates at least one change in transmittance based on the measured power.

EEE 22. An apparatus that compensates for liquid crystal display response variations in high brightness fields, comprising:

a reflected optical power measurement device coupled to a local backlight array of the liquid crystal display;

a compensation module coupled to said reflected optical power measurement device and said liquid crystal display; and

wherein said compensation module, modulates a set of initial liquid crystal display code values based on a reflected optical power.

EEE 23. The apparatus of EEE 22 wherein the compensation module estimates at least one change in transmittance based on the measured reflected optical power.

Claims

CLAIMS 1. In a display comprising an LCD modulator and a backlight, a method of controlling the LCD modulator, the method comprising:

receiving an image signal comprising an LCD code value for setting a transmittance level of at least a part of the LCD modulator, wherein the received LCD code value corresponds to a target transmittance level on a first response curve of said at least a part of the LCD modulator, the first response curve giving transmittance levels as a of function LCD code values for said at least a part of the LCD modulator when illuminated by at least a part of the backlight at a reference output level thereof;

obtaining an output level value of said at least a part of the backlight;

determining an adapted LCD code value as a function of the received LCD code value and the obtained output level value, such that the adapted LCD code value corresponds to the target transmittance level on a second response curve of said at least a part of the LCD modulator, the second response curve giving transmittance levels as a function of LCD code values for said at least a part of the LCD modulator when illuminated by said at least a part of the backlight at the obtained output level; and

setting the transmittance level of said at least a part of the LCD modulator according to the adapted LCD code value.

2. The method of claim 1, wherein the adapted LCD code value is determined as a monotonically decreasing function of the obtained output level of said at least a part of the backlight.

3. The method of claim 1, wherein the adapted LCD code value is determined as a monotonically increasing function of the obtained output level of said at least a part of the backlight.

4. The method of any preceding method claim, wherein the obtained output level value of said at least a part of the backlight represents an estimated power level of said at least a part of the backlight.

5. The method of any preceding method claim, wherein determining the adapted LCD code value is based at least in part on a polynomial.

6. The method of any preceding method claim, wherein determining the adapted LCD code value is based at least in part on a look up table.

7. A computer program product having instructions which, when executed by a computing device or system, cause said computing device or system to perform the method of any preceding claim.

8. Control hardware for a display, the display comprising an LCD modulator and a backlight, the control hardware being configured to:

receive an image signal comprising an LCD code value for setting a transmittance level of at least a part of the LCD modulator, wherein the received LCD code value corresponds to a target transmittance level on a first response curve of said at least a part of the LCD modulator, the first response curve giving transmittance levels as a of function LCD code values for said at least a part of the LCD modulator when illuminated by at least a part of the backlight at a reference output level thereof;

obtain an output level value of said at least a part of the backlight;

determine an adapted LCD code value as a function of the received LCD code value and the obtained output level value, such that the adapted LCD code value corresponds to the target transmittance level on a second response curve of said at least a part of the LCD modulator, the second response curve giving transmittance levels as a function of LCD code values for said at least a part of the LCD modulator when illuminated by said at least a part of the backlight at the obtained output level; and

set the transmittance level of said at least a part of the LCD modulator according to the adapted LCD code value.

9. The control hardware of claim 8, wherein the adapted LCD code value is determined as a monotonically decreasing function of the obtained output level of said at least a part of the backlight.

10. The control hardware of claim 8, wherein the adapted LCD code value is determined as a monotonically increasing function of the obtained output level of said at least a part of the backlight.

11. The control hardware of any one of claims 8 to 10, wherein the obtained output level value of said at least a part of the backlight represents an estimated power level of said at least a part of the backlight.

12. The control hardware of any one of claims 8 to 11, wherein determining the adapted LCD code value is based at least in part on a polynomial.

13. The control hardware of any one of claims 8 to 12, wherein determining the adapted LCD code value is based at least in part on a look up table.

14. A display comprising an LCD modulator, a backlight and the control hardware of any one of claims 8 to 13.