.. image:: https://raw.githubusercontent.com/colour-science/colour-branding/master/images/Colour_Logo_001.png | `Colour `__ is an open-source `Python `__ package providing a comprehensive number of algorithms and datasets for colour science. It is freely available under the `New BSD License `__ terms. **Colour** is an affiliated project of `NumFOCUS `__, a 501(c)(3) nonprofit in the United States. .. sectnum:: Draft Release Notes ------------------- The draft release notes from the `develop `__ branch are available at this `url `__. Sponsors -------- We are grateful for the support of our `sponsors `__. If you'd like to join them, please consider `becoming a sponsor on OpenCollective `__. Features -------- Most of the objects are available from the ``colour`` namespace: .. code-block:: python >>> import colour Automatic Colour Conversion Graph - ``colour.graph`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Starting with version *0.3.14*, **Colour** implements an automatic colour conversion graph enabling easier colour conversions. .. image:: https://colour.readthedocs.io/en/develop/_static/Examples_Colour_Automatic_Conversion_Graph.png .. code-block:: python >>> sd = colour.SDS_COLOURCHECKERS["ColorChecker N Ohta"]["dark skin"] >>> colour.convert( ... sd, "Spectral Distribution", "sRGB", verbose={"mode": "Short"} ... ) :: =============================================================================== * * * [ Conversion Path ] * * * * "sd_to_XYZ" --> "XYZ_to_sRGB" * * * =============================================================================== array([ 0.45675795, 0.30986982, 0.24861924]) .. code-block:: python >>> illuminant = colour.SDS_ILLUMINANTS["FL2"] >>> colour.convert( ... sd, ... "Spectral Distribution", ... "sRGB", ... sd_to_XYZ={"illuminant": illuminant}, ... ) array([ 0.47924575, 0.31676968, 0.17362725]) Chromatic Adaptation - ``colour.adaptation`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> XYZ = [0.20654008, 0.12197225, 0.05136952] >>> D65 = colour.CCS_ILLUMINANTS["CIE 1931 2 Degree Standard Observer"][ ... "D65" ... ] >>> A = colour.CCS_ILLUMINANTS["CIE 1931 2 Degree Standard Observer"]["A"] >>> colour.chromatic_adaptation( ... XYZ, colour.xy_to_XYZ(D65), colour.xy_to_XYZ(A) ... ) array([ 0.2533053 , 0.13765138, 0.01543307]) >>> sorted(colour.CHROMATIC_ADAPTATION_METHODS) ['CIE 1994', 'CMCCAT2000', 'Fairchild 1990', 'Von Kries', 'Zhai 2018'] Algebra - ``colour.algebra`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Kernel Interpolation ******************** .. code-block:: python >>> y = [5.9200, 9.3700, 10.8135, 4.5100, 69.5900, 27.8007, 86.0500] >>> x = range(len(y)) >>> colour.KernelInterpolator(x, y)([0.25, 0.75, 5.50]) array([ 6.18062083, 8.08238488, 57.85783403]) Sprague (1880) Interpolation **************************** .. code-block:: python >>> y = [5.9200, 9.3700, 10.8135, 4.5100, 69.5900, 27.8007, 86.0500] >>> x = range(len(y)) >>> colour.SpragueInterpolator(x, y)([0.25, 0.75, 5.50]) array([ 6.72951612, 7.81406251, 43.77379185]) Colour Appearance Models - ``colour.appearance`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> XYZ_w = [95.05, 100.00, 108.88] >>> L_A = 318.31 >>> Y_b = 20.0 >>> colour.XYZ_to_CIECAM02(XYZ, XYZ_w, L_A, Y_b) CAM_Specification_CIECAM02(J=34.434525727858997, C=67.365010921125943, h=22.279164147957065, s=62.81485585332716, Q=177.47124941102123, M=70.024939419291414, H=2.6896085344238898, HC=None) >>> colour.XYZ_to_CIECAM16(XYZ, XYZ_w, L_A, Y_b) CAM_Specification_CIECAM16(J=34.434525727858997, C=67.365010921125943, h=22.279164147957065, s=62.81485585332716, Q=177.47124941102123, M=70.024939419291414, H=2.6896085344238898, HC=None) >>> colour.XYZ_to_CAM16(XYZ, XYZ_w, L_A, Y_b) CAM_Specification_CAM16(J=33.880368498111686, C=69.444353357408033, h=19.510887327451748, s=64.03612114840314, Q=176.03752758512178, M=72.18638534116765, H=399.52975599115319, HC=None) >>> colour.XYZ_to_Hellwig2022(XYZ, XYZ_w, L_A) CAM_Specification_Hellwig2022(J=33.880368498111686, C=40.347043294550311, h=19.510887327451748, s=117.38555017188679, Q=45.34489577734751, M=53.228355383108031, H=399.52975599115319, HC=None) >>> colour.XYZ_to_Kim2009(XYZ, XYZ_w, L_A) CAM_Specification_Kim2009(J=19.879918542450902, C=55.839055250876946, h=22.013388165090046, s=112.97979354939129, Q=36.309026130161449, M=46.346415858227864, H=2.3543198369639931, HC=None) >>> colour.XYZ_to_ZCAM(XYZ, XYZ_w, L_A, Y_b) CAM_Specification_ZCAM(J=38.347186278956357, C=21.12138989208518, h=33.711578931095197, s=81.444585609489536, Q=76.986725284523772, M=42.403805833900506, H=0.45779200212219573, HC=None, V=43.623590687423544, K=43.20894953152817, W=34.829588380192149) Colour Blindness - ``colour.blindness`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> import numpy as np >>> cmfs = colour.LMS_CMFS["Stockman & Sharpe 2 Degree Cone Fundamentals"] >>> colour.msds_cmfs_anomalous_trichromacy_Machado2009( ... cmfs, np.array([15, 0, 0]) ... )[450] array([ 0.08912884, 0.0870524 , 0.955393 ]) >>> primaries = colour.MSDS_DISPLAY_PRIMARIES["Apple Studio Display"] >>> d_LMS = (15, 0, 0) >>> colour.matrix_anomalous_trichromacy_Machado2009(cmfs, primaries, d_LMS) array([[-0.27774652, 2.65150084, -1.37375432], [ 0.27189369, 0.20047862, 0.52762768], [ 0.00644047, 0.25921579, 0.73434374]]) Colour Correction - ``colour characterisation`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> import numpy as np >>> RGB = [0.17224810, 0.09170660, 0.06416938] >>> M_T = np.random.random((24, 3)) >>> M_R = M_T + (np.random.random((24, 3)) - 0.5) * 0.5 >>> colour.colour_correction(RGB, M_T, M_R) array([ 0.1806237 , 0.07234791, 0.07848845]) >>> sorted(colour.COLOUR_CORRECTION_METHODS) ['Cheung 2004', 'Finlayson 2015', 'Vandermonde'] ACES Input Transform - ``colour characterisation`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> sensitivities = colour.MSDS_CAMERA_SENSITIVITIES["Nikon 5100 (NPL)"] >>> illuminant = colour.SDS_ILLUMINANTS["D55"] >>> colour.matrix_idt(sensitivities, illuminant) (array([[ 0.46579986, 0.13409221, 0.01935163], [ 0.01786092, 0.77557268, -0.16775531], [ 0.03458647, -0.16152923, 0.74270363]]), array([ 1.58214188, 1. , 1.28910346])) Colorimetry - ``colour.colorimetry`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Spectral Computations ********************* .. code-block:: python >>> colour.sd_to_XYZ(colour.SDS_LIGHT_SOURCES["Neodimium Incandescent"]) array([ 36.94726204, 32.62076174, 13.0143849 ]) >>> sorted(colour.SPECTRAL_TO_XYZ_METHODS) ['ASTM E308', 'Integration', 'astm2015'] Multi-Spectral Computations *************************** .. code-block:: python >>> msds = np.array( ... [ ... [ ... [ ... 0.01367208, ... 0.09127947, ... 0.01524376, ... 0.02810712, ... 0.19176012, ... 0.04299992, ... ], ... [ ... 0.00959792, ... 0.25822842, ... 0.41388571, ... 0.22275120, ... 0.00407416, ... 0.37439537, ... ], ... [ ... 0.01791409, ... 0.29707789, ... 0.56295109, ... 0.23752193, ... 0.00236515, ... 0.58190280, ... ], ... ], ... [ ... [ ... 0.01492332, ... 0.10421912, ... 0.02240025, ... 0.03735409, ... 0.57663846, ... 0.32416266, ... ], ... [ ... 0.04180972, ... 0.26402685, ... 0.03572137, ... 0.00413520, ... 0.41808194, ... 0.24696727, ... ], ... [ ... 0.00628672, ... 0.11454948, ... 0.02198825, ... 0.39906919, ... 0.63640803, ... 0.01139849, ... ], ... ], ... [ ... [ ... 0.04325933, ... 0.26825359, ... 0.23732357, ... 0.05175860, ... 0.01181048, ... 0.08233768, ... ], ... [ ... 0.02484169, ... 0.12027161, ... 0.00541695, ... 0.00654612, ... 0.18603799, ... 0.36247808, ... ], ... [ ... 0.03102159, ... 0.16815442, ... 0.37186235, ... 0.08610666, ... 0.00413520, ... 0.78492409, ... ], ... ], ... [ ... [ ... 0.11682307, ... 0.78883040, ... 0.74468607, ... 0.83375293, ... 0.90571451, ... 0.70054168, ... ], ... [ ... 0.06321812, ... 0.41898224, ... 0.15190357, ... 0.24591440, ... 0.55301750, ... 0.00657664, ... ], ... [ ... 0.00305180, ... 0.11288624, ... 0.11357290, ... 0.12924391, ... 0.00195315, ... 0.21771573, ... ], ... ], ... ] ... ) >>> colour.msds_to_XYZ( ... msds, ... method="Integration", ... shape=colour.SpectralShape(400, 700, 60), ... ) array([[[ 7.68544647, 4.09414317, 8.49324254], [ 17.12567298, 27.77681821, 25.52573685], [ 19.10280411, 34.45851476, 29.76319628]], [[ 18.03375827, 8.62340812, 9.71702574], [ 15.03110867, 6.54001068, 24.53208465], [ 37.68269495, 26.4411103 , 10.66361816]], [[ 8.09532373, 12.75333339, 25.79613956], [ 7.09620297, 2.79257389, 11.15039854], [ 8.933163 , 19.39985815, 17.14915636]], [[ 80.00969553, 80.39810464, 76.08184429], [ 33.27611427, 24.38947838, 39.34919287], [ 8.89425686, 11.05185138, 10.86767594]]]) >>> sorted(colour.MSDS_TO_XYZ_METHODS) ['ASTM E308', 'Integration', 'astm2015'] Blackbody Spectral Radiance Computation *************************************** .. code-block:: python >>> colour.sd_blackbody(5000) SpectralDistribution([[ 3.60000000e+02, 6.65427827e+12], [ 3.61000000e+02, 6.70960528e+12], [ 3.62000000e+02, 6.76482512e+12], ... [ 7.78000000e+02, 1.06068004e+13], [ 7.79000000e+02, 1.05903327e+13], [ 7.80000000e+02, 1.05738520e+13]], interpolator=SpragueInterpolator, interpolator_args={}, extrapolator=Extrapolator, extrapolator_args={'right': None, 'method': 'Constant', 'left': None}) Dominant, Complementary Wavelength & Colour Purity Computation ************************************************************** .. code-block:: python >>> xy = [0.54369557, 0.32107944] >>> xy_n = [0.31270000, 0.32900000] >>> colour.dominant_wavelength(xy, xy_n) (array(616.0), array([ 0.68354746, 0.31628409]), array([ 0.68354746, 0.31628409])) Lightness Computation ********************* .. code-block:: python >>> colour.lightness(12.19722535) 41.527875844653451 >>> sorted(colour.LIGHTNESS_METHODS) ['Abebe 2017', 'CIE 1976', 'Fairchild 2010', 'Fairchild 2011', 'Glasser 1958', 'Lstar1976', 'Wyszecki 1963'] Luminance Computation ********************* .. code-block:: python >>> colour.luminance(41.52787585) 12.197225353400775 >>> sorted(colour.LUMINANCE_METHODS) ['ASTM D1535', 'CIE 1976', 'Fairchild 2010', 'Fairchild 2011', 'Newhall 1943', 'astm2008', 'cie1976'] Whiteness Computation ********************* .. code-block:: python >>> XYZ = [95.00000000, 100.00000000, 105.00000000] >>> XYZ_0 = [94.80966767, 100.00000000, 107.30513595] >>> colour.whiteness(XYZ, XYZ_0) array([ 93.756 , -1.33000001]) >>> sorted(colour.WHITENESS_METHODS) ['ASTM E313', 'Berger 1959', 'CIE 2004', 'Ganz 1979', 'Stensby 1968', 'Taube 1960', 'cie2004'] Yellowness Computation ********************** .. code-block:: python >>> XYZ = [95.00000000, 100.00000000, 105.00000000] >>> colour.yellowness(XYZ) 4.3400000000000034 >>> sorted(colour.YELLOWNESS_METHODS) ['ASTM D1925', 'ASTM E313', 'ASTM E313 Alternative'] Luminous Flux, Efficiency & Efficacy Computation ************************************************ .. code-block:: python >>> sd = colour.SDS_LIGHT_SOURCES["Neodimium Incandescent"] >>> colour.luminous_flux(sd) 23807.655527367202 >>> sd = colour.SDS_LIGHT_SOURCES["Neodimium Incandescent"] >>> colour.luminous_efficiency(sd) 0.19943935624521045 >>> sd = colour.SDS_LIGHT_SOURCES["Neodimium Incandescent"] >>> colour.luminous_efficacy(sd) 136.21708031547874 Contrast Sensitivity Function - ``colour.contrast`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> colour.contrast_sensitivity_function(u=4, X_0=60, E=65) 358.51180789884984 >>> sorted(colour.CONTRAST_SENSITIVITY_METHODS) ['Barten 1999'] Colour Difference - ``colour.difference`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> Lab_1 = [100.00000000, 21.57210357, 272.22819350] >>> Lab_2 = [100.00000000, 426.67945353, 72.39590835] >>> colour.delta_E(Lab_1, Lab_2) 94.035649026659485 >>> sorted(colour.DELTA_E_METHODS) ['CAM02-LCD', 'CAM02-SCD', 'CAM02-UCS', 'CAM16-LCD', 'CAM16-SCD', 'CAM16-UCS', 'CIE 1976', 'CIE 1994', 'CIE 2000', 'CMC', 'DIN99', 'ITP', 'cie1976', 'cie1994', 'cie2000'] IO - ``colour.io`` ~~~~~~~~~~~~~~~~~~ Images ****** .. code-block:: python >>> RGB = colour.read_image("Ishihara_Colour_Blindness_Test_Plate_3.png") >>> RGB.shape (276, 281, 3) Look Up Table (LUT) Data ************************ .. code-block:: python >>> LUT = colour.read_LUT("ACES_Proxy_10_to_ACES.cube") >>> print(LUT) :: LUT3x1D - ACES Proxy 10 to ACES ------------------------------- Dimensions : 2 Domain : [[0 0 0] [1 1 1]] Size : (32, 3) .. code-block:: python >>> RGB = [0.17224810, 0.09170660, 0.06416938] >>> LUT.apply(RGB) array([ 0.00575674, 0.00181493, 0.00121419]) Colour Models - ``colour.models`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ CIE xyY Colourspace ******************* .. code-block:: python >>> colour.XYZ_to_xyY([0.20654008, 0.12197225, 0.05136952]) array([ 0.54369557, 0.32107944, 0.12197225]) CIE L*a*b* Colourspace ********************** .. code-block:: python >>> colour.XYZ_to_Lab([0.20654008, 0.12197225, 0.05136952]) array([ 41.52787529, 52.63858304, 26.92317922]) CIE L*u*v* Colourspace ********************** .. code-block:: python >>> colour.XYZ_to_Luv([0.20654008, 0.12197225, 0.05136952]) array([ 41.52787529, 96.83626054, 17.75210149]) CIE 1960 UCS Colourspace ************************ .. code-block:: python >>> colour.XYZ_to_UCS([0.20654008, 0.12197225, 0.05136952]) array([ 0.13769339, 0.12197225, 0.1053731 ]) CIE 1964 U*V*W* Colourspace *************************** .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> colour.XYZ_to_UVW(XYZ) array([ 94.55035725, 11.55536523, 40.54757405]) Hunter L,a,b Colour Scale ************************* .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> colour.XYZ_to_Hunter_Lab(XYZ) array([ 34.92452577, 47.06189858, 14.38615107]) Hunter Rd,a,b Colour Scale ************************** .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> colour.XYZ_to_Hunter_Rdab(XYZ) array([ 12.197225 , 57.12537874, 17.46241341]) CAM02-LCD, CAM02-SCD, and CAM02-UCS Colourspaces - Luo, Cui and Li (2006) ************************************************************************* .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> XYZ_w = [95.05, 100.00, 108.88] >>> L_A = 318.31 >>> Y_b = 20.0 >>> surround = colour.VIEWING_CONDITIONS_CIECAM02["Average"] >>> specification = colour.XYZ_to_CIECAM02(XYZ, XYZ_w, L_A, Y_b, surround) >>> JMh = (specification.J, specification.M, specification.h) >>> colour.JMh_CIECAM02_to_CAM02UCS(JMh) array([ 47.16899898, 38.72623785, 15.8663383 ]) >>> XYZ = [0.20654008, 0.12197225, 0.05136952] >>> XYZ_w = [95.05 / 100, 100.00 / 100, 108.88 / 100] >>> colour.XYZ_to_CAM02UCS(XYZ, XYZ_w=XYZ_w, L_A=L_A, Y_b=Y_b) array([ 47.16899898, 38.72623785, 15.8663383 ]) CAM16-LCD, CAM16-SCD, and CAM16-UCS Colourspaces - Li et al. (2017) ******************************************************************* .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> XYZ_w = [95.05, 100.00, 108.88] >>> L_A = 318.31 >>> Y_b = 20.0 >>> surround = colour.VIEWING_CONDITIONS_CAM16["Average"] >>> specification = colour.XYZ_to_CAM16(XYZ, XYZ_w, L_A, Y_b, surround) >>> JMh = (specification.J, specification.M, specification.h) >>> colour.JMh_CAM16_to_CAM16UCS(JMh) array([ 46.55542238, 40.22460974, 14.25288392] >>> XYZ = [0.20654008, 0.12197225, 0.05136952] >>> XYZ_w = [95.05 / 100, 100.00 / 100, 108.88 / 100] >>> colour.XYZ_to_CAM16UCS(XYZ, XYZ_w=XYZ_w, L_A=L_A, Y_b=Y_b) array([ 46.55542238, 40.22460974, 14.25288392]) ICaCb Colourspace ****************** .. code-block:: python >>> XYZ_to_ICaCb(np.array([0.20654008, 0.12197225, 0.05136952])) array([ 0.06875297, 0.05753352, 0.02081548]) IgPgTg Colourspace ****************** .. code-block:: python >>> colour.XYZ_to_IgPgTg([0.20654008, 0.12197225, 0.05136952]) array([ 0.42421258, 0.18632491, 0.10689223]) IPT Colourspace *************** .. code-block:: python >>> colour.XYZ_to_IPT([0.20654008, 0.12197225, 0.05136952]) array([ 0.38426191, 0.38487306, 0.18886838]) Munish Ragoo and Farup (2021) Optimised IPT Colourspace ******************************************************* .. code-block:: python >>> colour.XYZ_to_IPT_Munish2021([0.20654008, 0.12197225, 0.05136952]) array([ 0.42248243, 0.2910514 , 0.20410663]) DIN99 Colourspace ***************** .. code-block:: python >>> Lab = [41.52787529, 52.63858304, 26.92317922] >>> colour.Lab_to_DIN99(Lab) array([ 53.22821988, 28.41634656, 3.89839552]) hdr-CIELAB Colourspace ********************** .. code-block:: python >>> colour.XYZ_to_hdr_CIELab([0.20654008, 0.12197225, 0.05136952]) array([ 51.87002062, 60.4763385 , 32.14551912]) hdr-IPT Colourspace ******************* .. code-block:: python >>> colour.XYZ_to_hdr_IPT([0.20654008, 0.12197225, 0.05136952]) array([ 25.18261761, -22.62111297, 3.18511729]) Oklab Colourspace ***************** .. code-block:: python >>> colour.XYZ_to_Oklab([0.20654008, 0.12197225, 0.05136952]) array([ 0.51634019, 0.154695 , 0.06289579]) OSA UCS Colourspace ******************* .. code-block:: python >>> XYZ = [0.20654008 * 100, 0.12197225 * 100, 0.05136952 * 100] >>> colour.XYZ_to_OSA_UCS(XYZ) array([-3.0049979 , 2.99713697, -9.66784231]) ProLab Colourspace ****************** .. code-block:: python >>> colour.XYZ_to_ProLab([0.51634019, 0.15469500, 0.06289579]) array([1.24610688, 2.39525236, 0.41902126]) Jzazbz Colourspace ****************** .. code-block:: python >>> colour.XYZ_to_Jzazbz([0.20654008, 0.12197225, 0.05136952]) array([ 0.00535048, 0.00924302, 0.00526007]) Y'CbCr Colour Encoding ********************** .. code-block:: python >>> colour.RGB_to_YCbCr([1.0, 1.0, 1.0]) array([ 0.92156863, 0.50196078, 0.50196078]) YCoCg Colour Encoding ********************* .. code-block:: python >>> colour.RGB_to_YCoCg([0.75, 0.75, 0.0]) array([ 0.5625, 0.375 , 0.1875]) ICtCp Colour Encoding ********************* .. code-block:: python >>> colour.RGB_to_ICtCp([0.45620519, 0.03081071, 0.04091952]) array([ 0.07351364, 0.00475253, 0.09351596]) HSV Colourspace *************** .. code-block:: python >>> colour.RGB_to_HSV([0.45620519, 0.03081071, 0.04091952]) array([ 0.99603944, 0.93246304, 0.45620519]) IHLS Colourspace **************** .. code-block:: python >>> colour.RGB_to_IHLS([0.45620519, 0.03081071, 0.04091952]) array([ 6.26236117, 0.12197943, 0.42539448]) Prismatic Colourspace ********************* .. code-block:: python >>> colour.RGB_to_Prismatic([0.25, 0.50, 0.75]) array([ 0.75 , 0.16666667, 0.33333333, 0.5 ]) RGB Colourspace and Transformations *********************************** .. code-block:: python >>> XYZ = [0.21638819, 0.12570000, 0.03847493] >>> illuminant_XYZ = [0.34570, 0.35850] >>> illuminant_RGB = [0.31270, 0.32900] >>> chromatic_adaptation_transform = "Bradford" >>> matrix_XYZ_to_RGB = [ ... [3.24062548, -1.53720797, -0.49862860], ... [-0.96893071, 1.87575606, 0.04151752], ... [0.05571012, -0.20402105, 1.05699594], ... ] >>> colour.XYZ_to_RGB( ... XYZ, ... illuminant_XYZ, ... illuminant_RGB, ... matrix_XYZ_to_RGB, ... chromatic_adaptation_transform, ... ) array([ 0.45595571, 0.03039702, 0.04087245]) RGB Colourspace Derivation ************************** .. code-block:: python >>> p = [0.73470, 0.26530, 0.00000, 1.00000, 0.00010, -0.07700] >>> w = [0.32168, 0.33767] >>> colour.normalised_primary_matrix(p, w) array([[ 9.52552396e-01, 0.00000000e+00, 9.36786317e-05], [ 3.43966450e-01, 7.28166097e-01, -7.21325464e-02], [ 0.00000000e+00, 0.00000000e+00, 1.00882518e+00]]) RGB Colourspaces **************** .. code-block:: python >>> sorted(colour.RGB_COLOURSPACES) ['ACES2065-1', 'ACEScc', 'ACEScct', 'ACEScg', 'ACESproxy', 'ARRI Wide Gamut 3', 'ARRI Wide Gamut 4', 'Adobe RGB (1998)', 'Adobe Wide Gamut RGB', 'Apple RGB', 'Best RGB', 'Beta RGB', 'Blackmagic Wide Gamut', 'CIE RGB', 'Cinema Gamut', 'ColorMatch RGB', 'DCDM XYZ', 'DCI-P3', 'DCI-P3-P', 'DJI D-Gamut', 'DRAGONcolor', 'DRAGONcolor2', 'DaVinci Wide Gamut', 'Display P3', 'Don RGB 4', 'EBU Tech. 3213-E', 'ECI RGB v2', 'ERIMM RGB', 'Ekta Space PS 5', 'F-Gamut', 'FilmLight E-Gamut', 'ITU-R BT.2020', 'ITU-R BT.470 - 525', 'ITU-R BT.470 - 625', 'ITU-R BT.709', 'ITU-T H.273 - 22 Unspecified', 'ITU-T H.273 - Generic Film', 'Max RGB', 'N-Gamut', 'NTSC (1953)', 'NTSC (1987)', 'P3-D65', 'Pal/Secam', 'ProPhoto RGB', 'Protune Native', 'REDWideGamutRGB', 'REDcolor', 'REDcolor2', 'REDcolor3', 'REDcolor4', 'RIMM RGB', 'ROMM RGB', 'Russell RGB', 'S-Gamut', 'S-Gamut3', 'S-Gamut3.Cine', 'SMPTE 240M', 'SMPTE C', 'Sharp RGB', 'V-Gamut', 'Venice S-Gamut3', 'Venice S-Gamut3.Cine', 'Xtreme RGB', 'aces', 'adobe1998', 'prophoto', 'sRGB'] OETFs ***** .. code-block:: python >>> sorted(colour.OETFS) ['ARIB STD-B67', 'Blackmagic Film Generation 5', 'DaVinci Intermediate', 'ITU-R BT.2020', 'ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ', 'ITU-R BT.601', 'ITU-R BT.709', 'ITU-T H.273 IEC 61966-2', 'ITU-T H.273 Log', 'ITU-T H.273 Log Sqrt', 'SMPTE 240M'] EOTFs ***** .. code-block:: python >>> sorted(colour.EOTFS) ['DCDM', 'DICOM GSDF', 'ITU-R BT.1886', 'ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ', 'ITU-T H.273 ST.428-1', 'SMPTE 240M', 'ST 2084', 'sRGB'] OOTFs ***** .. code-block:: python >>> sorted(colour.OOTFS) ['ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ'] Log Encoding / Decoding *********************** .. code-block:: python >>> sorted(colour.LOG_ENCODINGS) ['ACEScc', 'ACEScct', 'ACESproxy', 'ARRI LogC3', 'ARRI LogC4', 'Canon Log', 'Canon Log 2', 'Canon Log 3', 'Cineon', 'D-Log', 'ERIMM RGB', 'F-Log', 'Filmic Pro 6', 'L-Log', 'Log2', 'Log3G10', 'Log3G12', 'N-Log', 'PLog', 'Panalog', 'Protune', 'REDLog', 'REDLogFilm', 'S-Log', 'S-Log2', 'S-Log3', 'T-Log', 'V-Log', 'ViperLog'] CCTFs Encoding / Decoding ************************* .. code-block:: python >>> sorted(colour.CCTF_ENCODINGS) ['ACEScc', 'ACEScct', 'ACESproxy', 'ARRI LogC3', 'ARRI LogC4', 'ARIB STD-B67', 'Canon Log', 'Canon Log 2', 'Canon Log 3', 'Cineon', 'D-Log', 'DCDM', 'DICOM GSDF', 'ERIMM RGB', 'F-Log', 'Filmic Pro 6', 'Gamma 2.2', 'Gamma 2.4', 'Gamma 2.6', 'ITU-R BT.1886', 'ITU-R BT.2020', 'ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ', 'ITU-R BT.601', 'ITU-R BT.709', 'Log2', 'Log3G10', 'Log3G12', 'PLog', 'Panalog', 'ProPhoto RGB', 'Protune', 'REDLog', 'REDLogFilm', 'RIMM RGB', 'ROMM RGB', 'S-Log', 'S-Log2', 'S-Log3', 'SMPTE 240M', 'ST 2084', 'T-Log', 'V-Log', 'ViperLog', 'sRGB'] Recommendation ITU-T H.273 Code points for Video Signal Type Identification *************************************************************************** .. code-block:: python >>> colour.COLOUR_PRIMARIES_ITUTH273.keys() dict_keys([0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 22, 23]) >>> colour.COLOUR_PRIMARIES_ITUTH273.keys() >>> description = colour.models.describe_video_signal_colour_primaries(1) =============================================================================== * * * Colour Primaries: 1 * * ------------------- * * * * Primaries : [[ 0.64 0.33] * * [ 0.3 0.6 ] * * [ 0.15 0.06]] * * Whitepoint : [ 0.3127 0.329 ] * * Whitepoint Name : D65 * * NPM : [[ 0.4123908 0.35758434 0.18048079] * * [ 0.21263901 0.71516868 0.07219232] * * [ 0.01933082 0.11919478 0.95053215]] * * NPM -1 : [[ 3.24096994 -1.53738318 -0.49861076] * * [-0.96924364 1.8759675 0.04155506] * * [ 0.05563008 -0.20397696 1.05697151]] * * FFmpeg Constants : ['AVCOL_PRI_BT709', 'BT709'] * * * =============================================================================== >>> colour.TRANSFER_CHARACTERISTICS_ITUTH273.keys() dict_keys([0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19]) >>> description = ( ... colour.models.describe_video_signal_transfer_characteristics(1) ... ) =============================================================================== * * * Transfer Characteristics: 1 * * --------------------------- * * * * Function : * * FFmpeg Constants : ['AVCOL_TRC_BT709', 'BT709'] * * * =============================================================================== >>> colour.MATRIX_COEFFICIENTS_ITUTH273.keys() dict_keys([0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15]) >>> description = colour.models.describe_video_signal_matrix_coefficients( ... 1 ... ) =============================================================================== * * * Matrix Coefficients: 1 * * ---------------------- * * * * Matrix Coefficients : [ 0.2126 0.0722] * * FFmpeg Constants : ['AVCOL_SPC_BT709', 'BT709'] * * * =============================================================================== Colour Notation Systems - ``colour.notation`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Munsell Value ************* .. code-block:: python >>> colour.munsell_value(12.23634268) 4.0824437076525664 >>> sorted(colour.MUNSELL_VALUE_METHODS) ['ASTM D1535', 'Ladd 1955', 'McCamy 1987', 'Moon 1943', 'Munsell 1933', 'Priest 1920', 'Saunderson 1944', 'astm2008'] Munsell Colour ************** .. code-block:: python >>> colour.xyY_to_munsell_colour([0.38736945, 0.35751656, 0.59362000]) '4.2YR 8.1/5.3' >>> colour.munsell_colour_to_xyY("4.2YR 8.1/5.3") array([ 0.38736945, 0.35751656, 0.59362 ]) Optical Phenomena - ``colour.phenomena`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> colour.rayleigh_scattering_sd() SpectralDistribution([[ 3.60000000e+02, 5.99101337e-01], [ 3.61000000e+02, 5.92170690e-01], [ 3.62000000e+02, 5.85341006e-01], ... [ 7.78000000e+02, 2.55208377e-02], [ 7.79000000e+02, 2.53887969e-02], [ 7.80000000e+02, 2.52576106e-02]], interpolator=SpragueInterpolator, interpolator_args={}, extrapolator=Extrapolator, extrapolator_args={'right': None, 'method': 'Constant', 'left': None}) Light Quality - ``colour.quality`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Colour Fidelity Index ********************* .. code-block:: python >>> colour.colour_fidelity_index(colour.SDS_ILLUMINANTS["FL2"]) 70.120825477833037 >>> sorted(colour.COLOUR_FIDELITY_INDEX_METHODS) ['ANSI/IES TM-30-18', 'CIE 2017'] Colour Rendering Index ********************** .. code-block:: python >>> colour.colour_quality_scale(colour.SDS_ILLUMINANTS["FL2"]) 64.111703163816699 >>> sorted(colour.COLOUR_QUALITY_SCALE_METHODS) ['NIST CQS 7.4', 'NIST CQS 9.0'] Colour Quality Scale ******************** .. code-block:: python >>> colour.colour_rendering_index(colour.SDS_ILLUMINANTS["FL2"]) 64.233724121664807 Academy Spectral Similarity Index (SSI) *************************************** .. code-block:: python >>> colour.spectral_similarity_index( ... colour.SDS_ILLUMINANTS["C"], colour.SDS_ILLUMINANTS["D65"] ... ) 94.0 Spectral Up-Sampling & Recovery - ``colour.recovery`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Reflectance Recovery ******************** .. code-block:: python >>> colour.XYZ_to_sd([0.20654008, 0.12197225, 0.05136952]) SpectralDistribution([[ 3.60000000e+02, 8.40144095e-02], [ 3.65000000e+02, 8.41264236e-02], [ 3.70000000e+02, 8.40057597e-02], ... [ 7.70000000e+02, 4.46743012e-01], [ 7.75000000e+02, 4.46817187e-01], [ 7.80000000e+02, 4.46857696e-01]], SpragueInterpolator, {}, Extrapolator, {'method': 'Constant', 'left': None, 'right': None}) >>> sorted(colour.REFLECTANCE_RECOVERY_METHODS) ['Jakob 2019', 'Mallett 2019', 'Meng 2015', 'Otsu 2018', 'Smits 1999'] Camera RGB Sensitivities Recovery ********************************* >>> illuminant = colour.colorimetry.SDS_ILLUMINANTS["D65"] >>> sensitivities = colour.characterisation.MSDS_CAMERA_SENSITIVITIES[ ... "Nikon 5100 (NPL)" ... ] >>> reflectances = [ ... sd.copy().align( ... colour.recovery.SPECTRAL_SHAPE_BASIS_FUNCTIONS_DYER2017 ... ) ... for sd in colour.characterisation.SDS_COLOURCHECKERS[ ... "BabelColor Average" ... ].values() ... ] >>> reflectances = colour.colorimetry.sds_and_msds_to_msds(reflectances) >>> RGB = colour.colorimetry.msds_to_XYZ( ... reflectances, ... method="Integration", ... cmfs=sensitivities, ... illuminant=illuminant, ... k=0.01, ... shape=colour.recovery.SPECTRAL_SHAPE_BASIS_FUNCTIONS_DYER2017, ... ) >>> colour.recovery.RGB_to_msds_camera_sensitivities_Jiang2013( ... RGB, ... illuminant, ... reflectances, ... colour.recovery.BASIS_FUNCTIONS_DYER2017, ... colour.recovery.SPECTRAL_SHAPE_BASIS_FUNCTIONS_DYER2017, ... ) RGB_CameraSensitivities([[ 4.00000000e+02, 7.22815777e-03, 9.22506480e-03, -9.88368972e-03], [ 4.10000000e+02, -8.50457609e-03, 1.12777480e-02, 3.86248655e-03], [ 4.20000000e+02, 4.58191132e-02, 7.15520948e-02, 4.04068293e-01], ... [ 6.80000000e+02, 4.08276173e-02, 5.55290476e-03, 1.39907862e-03], [ 6.90000000e+02, -3.71437574e-03, 2.50935640e-03, 3.97652622e-04], [ 7.00000000e+02, -5.62256563e-03, 1.56433970e-03, 5.84726936e-04]], ['red', 'green', 'blue'], SpragueInterpolator, {}, Extrapolator, {'method': 'Constant', 'left': None, 'right': None}) Correlated Colour Temperature Computation Methods - ``colour.temperature`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> colour.uv_to_CCT([0.1978, 0.3122]) array([ 6.50751282e+03, 3.22335875e-03]) >>> sorted(colour.UV_TO_CCT_METHODS) ['Krystek 1985', 'Ohno 2013', 'Planck 1900', 'Robertson 1968', 'ohno2013', 'robertson1968'] >>> sorted(colour.XY_TO_CCT_METHODS) ['CIE Illuminant D Series', 'Hernandez 1999', 'Kang 2002', 'McCamy 1992', 'daylight', 'hernandez1999', 'kang2002', 'mccamy1992'] Colour Volume - ``colour.volume`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> colour.RGB_colourspace_volume_MonteCarlo( ... colour.RGB_COLOURSPACE_RGB["sRGB"] ... ) 821958.30000000005 Geometry Primitives Generation - ``colour.geometry`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. code-block:: python >>> colour.primitive("Grid") (array([ ([-0.5, 0.5, 0. ], [ 0., 1.], [ 0., 0., 1.], [ 0., 1., 0., 1.]), ([ 0.5, 0.5, 0. ], [ 1., 1.], [ 0., 0., 1.], [ 1., 1., 0., 1.]), ([-0.5, -0.5, 0. ], [ 0., 0.], [ 0., 0., 1.], [ 0., 0., 0., 1.]), ([ 0.5, -0.5, 0. ], [ 1., 0.], [ 0., 0., 1.], [ 1., 0., 0., 1.])], dtype=[('position', '>> sorted(colour.PRIMITIVE_METHODS) ['Cube', 'Grid'] >>> colour.primitive_vertices("Quad MPL") array([[ 0., 0., 0.], [ 1., 0., 0.], [ 1., 1., 0.], [ 0., 1., 0.]]) >>> sorted(colour.PRIMITIVE_VERTICES_METHODS) ['Cube MPL', 'Grid MPL', 'Quad MPL', 'Sphere'] Plotting - ``colour.plotting`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Most of the objects are available from the ``colour.plotting`` namespace: .. code-block:: python >>> from colour.plotting import * >>> colour_style() Visible Spectrum **************** .. code-block:: python >>> plot_visible_spectrum("CIE 1931 2 Degree Standard Observer") .. image:: _static/Examples_Plotting_Visible_Spectrum.png Spectral Distribution ********************* .. code-block:: python >>> plot_single_illuminant_sd("FL1") .. image:: _static/Examples_Plotting_Illuminant_F1_SD.png Blackbody ********* .. code-block:: python >>> blackbody_sds = [ ... colour.sd_blackbody(i, colour.SpectralShape(0, 10000, 10)) ... for i in range(1000, 15000, 1000) ... ] >>> plot_multi_sds( ... blackbody_sds, ... y_label="W / (sr m$^2$) / m", ... plot_kwargs={"use_sd_colours": True, "normalise_sd_colours": True}, ... legend_location="upper right", ... bounding_box=(0, 1250, 0, 2.5e6), ... ) .. image:: _static/Examples_Plotting_Blackbodies.png Colour Matching Functions ************************* .. code-block:: python >>> plot_single_cmfs( ... "Stockman & Sharpe 2 Degree Cone Fundamentals", ... y_label="Sensitivity", ... bounding_box=(390, 870, 0, 1.1), ... ) .. image:: _static/Examples_Plotting_Cone_Fundamentals.png Luminous Efficiency ******************* .. code-block:: python >>> sd_mesopic_luminous_efficiency_function = ( ... colour.sd_mesopic_luminous_efficiency_function(0.2) ... ) >>> plot_multi_sds( ... ( ... sd_mesopic_luminous_efficiency_function, ... colour.PHOTOPIC_LEFS["CIE 1924 Photopic Standard Observer"], ... colour.SCOTOPIC_LEFS["CIE 1951 Scotopic Standard Observer"], ... ), ... y_label="Luminous Efficiency", ... legend_location="upper right", ... y_tighten=True, ... margins=(0, 0, 0, 0.1), ... ) .. image:: _static/Examples_Plotting_Luminous_Efficiency.png Colour Checker ************** .. code-block:: python >>> from colour.characterisation.dataset.colour_checkers.sds import ( ... COLOURCHECKER_INDEXES_TO_NAMES_MAPPING, ... ) >>> plot_multi_sds( ... [ ... colour.SDS_COLOURCHECKERS["BabelColor Average"][value] ... for key, value in sorted( ... COLOURCHECKER_INDEXES_TO_NAMES_MAPPING.items() ... ) ... ], ... plot_kwargs={ ... "use_sd_colours": True, ... }, ... title=("BabelColor Average - " "Spectral Distributions"), ... ) .. image:: _static/Examples_Plotting_BabelColor_Average.png .. code-block:: python >>> plot_single_colour_checker( ... "ColorChecker 2005", text_kwargs={"visible": False} ... ) .. image:: _static/Examples_Plotting_ColorChecker_2005.png Chromaticities Prediction ************************* .. code-block:: python >>> plot_corresponding_chromaticities_prediction( ... 2, "Von Kries", "Bianco 2010" ... ) .. image:: _static/Examples_Plotting_Chromaticities_Prediction.png Chromaticities ************** .. code-block:: python >>> import numpy as np >>> RGB = np.random.random((32, 32, 3)) >>> plot_RGB_chromaticities_in_chromaticity_diagram_CIE1931( ... RGB, ... "ITU-R BT.709", ... colourspaces=["ACEScg", "S-Gamut"], ... show_pointer_gamut=True, ... ) .. image:: _static/Examples_Plotting_Chromaticities_CIE_1931_Chromaticity_Diagram.png Colour Rendering Index ********************** .. code-block:: python >>> plot_single_sd_colour_rendering_index_bars( ... colour.SDS_ILLUMINANTS["FL2"] ... ) .. image:: _static/Examples_Plotting_CRI.png ANSI/IES TM-30-18 Colour Rendition Report ***************************************** .. code-block:: python >>> plot_single_sd_colour_rendition_report(colour.SDS_ILLUMINANTS["FL2"]) .. image:: _static/Examples_Plotting_Colour_Rendition_Report.png Gamut Section ************* .. code-block:: python >>> plot_visible_spectrum_section( ... section_colours="RGB", section_opacity=0.15 ... ) .. image:: _static/Examples_Plotting_Plot_Visible_Spectrum_Section.png .. code-block:: python >>> plot_RGB_colourspace_section( ... "sRGB", section_colours="RGB", section_opacity=0.15 ... ) .. image:: _static/Examples_Plotting_Plot_RGB_Colourspace_Section.png Colour Temperature ****************** .. code-block:: python >>> plot_planckian_locus_in_chromaticity_diagram_CIE1960UCS( ... ["A", "B", "C"] ... ) .. image:: _static/Examples_Plotting_CCT_CIE_1960_UCS_Chromaticity_Diagram.png User Guide ---------- .. toctree:: :maxdepth: 2 user-guide API Reference ------------- .. toctree:: :maxdepth: 2 reference See Also -------- Software ~~~~~~~~ **Python** - `Colorio `__ by Schlömer, N. - `ColorPy `__ by Kness, M. - `Colorspacious `__ by Smith, N. J., et al. - `python-colormath `__ by Taylor, G., et al. **Go** - `go-colorful `__ by Beyer, L., et al. **.NET** - `Colourful `__ by Pažourek, T., et al. **Julia** - `Colors.jl `__ by Holy, T., et al. **Matlab & Octave** - `COLORLAB `__ by Malo, J., et al. - `Psychtoolbox `__ by Brainard, D., et al. - `The Munsell and Kubelka-Munk Toolbox `__ by Centore, P. Code of Conduct --------------- The *Code of Conduct*, adapted from the `Contributor Covenant 1.4 `__, is available on the `Code of Conduct `__ page. Contact & Social ---------------- The *Colour Developers* can be reached via different means: - `Email `__ - `Facebook `__ - `Github Discussions `__ - `Gitter `__ - `Twitter `__ About ----- | **Colour** by Colour Developers | Copyright 2013 Colour Developers – `colour-developers@colour-science.org `__ | This software is released under terms of New BSD License: https://opensource.org/licenses/BSD-3-Clause | `https://github.com/colour-science/colour `__