Source code for colour.temperature.cct

#!/usr/bin/env python
# -*- coding: utf-8 -*-

"""
Correlated Colour Temperature :math:`T_{cp}`
============================================

Defines correlated colour temperature :math:`T_{cp}` computations objects:

-   :func:`uv_to_CCT_Ohno2013`: Correlated colour temperature :math:`T_{cp}`
    and :math:`\Delta_{uv}` computation of given *CIE UCS* colourspace *uv*
    chromaticity coordinates using Ohno (2013) method.
-   :func:`CCT_to_uv_Ohno2013`: *CIE UCS* colourspace *uv* chromaticity
    coordinates computation of given correlated colour temperature
    :math:`T_{cp}`, :math:`\Delta_{uv}` using Ohno (2013) method.
-   :func:`uv_to_CCT_Robertson1968`: Correlated colour temperature
    :math:`T_{cp}` and :math:`\Delta_{uv}` computation of given *CIE UCS*
    colourspace *uv* chromaticity coordinates using Robertson (1968) method.
-   :func:`CCT_to_uv_Robertson1968`: *CIE UCS* colourspace *uv* chromaticity
    coordinates computation of given correlated colour temperature
    :math:`T_{cp}` and :math:`\Delta_{uv}` using Robertson (1968) method.
-   :func:`xy_to_CCT_McCamy1992`: Correlated colour temperature :math:`T_{cp}`
    computation of given *CIE XYZ* colourspace *xy* chromaticity coordinates
    using McCamy (1992) method.
-   :func:`xy_to_CCT_Hernandez1999`: Correlated colour temperature
    :math:`T_{cp}` computation of given *CIE XYZ* colourspace *xy* chromaticity
    coordinates using Hernandez-Andres, Lee and Romero (1999) method.
-   :func:`CCT_to_xy_Kang2002`: *CIE XYZ* colourspace *xy* chromaticity
    coordinates computation of given correlated colour temperature
    :math:`T_{cp}` using Kang et al. (2002) method.
-   :func:`CCT_to_xy_CIE_D`: *CIE XYZ* colourspace *xy* chromaticity
    coordinates computation of *CIE Illuminant D Series* from given correlated
    colour temperature :math:`T_{cp}` of that *CIE Illuminant D Series*.

See Also
--------
`Colour Temperature & Correlated Colour Temperature IPython Notebook
<http://nbviewer.ipython.org/github/colour-science/colour-ipython/blob/master/notebooks/temperature/cct.ipynb>`_  # noqa

References
----------
.. [1]  Wikipedia. (n.d.). Color temperature. Retrieved June 28, 2014, from
        http://en.wikipedia.org/wiki/Color_temperature
"""

from __future__ import division, unicode_literals

import numpy as np
from collections import namedtuple

from colour.colorimetry import (
    STANDARD_OBSERVERS_CMFS,
    blackbody_spd,
    spectral_to_XYZ)
from colour.models import UCS_to_uv, XYZ_to_UCS
from colour.utilities import CaseInsensitiveMapping, warning

__author__ = 'Colour Developers'
__copyright__ = 'Copyright (C) 2013 - 2015 - Colour Developers'
__license__ = 'New BSD License - http://opensource.org/licenses/BSD-3-Clause'
__maintainer__ = 'Colour Developers'
__email__ = 'colour-science@googlegroups.com'
__status__ = 'Production'

__all__ = ['PLANCKIAN_TABLE_TUVD',
           'CCT_MINIMAL',
           'CCT_MAXIMAL',
           'CCT_SAMPLES',
           'CCT_CALCULATION_ITERATIONS',
           'ROBERTSON_ISOTEMPERATURE_LINES_DATA',
           'ROBERTSON_ISOTEMPERATURE_LINES_RUVT',
           'ROBERTSON_ISOTEMPERATURE_LINES',
           'planckian_table',
           'planckian_table_minimal_distance_index',
           'uv_to_CCT_Ohno2013',
           'CCT_to_uv_Ohno2013',
           'uv_to_CCT_Robertson1968',
           'CCT_to_uv_Robertson1968',
           'UV_TO_CCT_METHODS',
           'uv_to_CCT',
           'CCT_TO_UV_METHODS',
           'CCT_to_uv',
           'xy_to_CCT_McCamy1992',
           'xy_to_CCT_Hernandez1999',
           'CCT_to_xy_Kang2002',
           'CCT_to_xy_CIE_D',
           'XY_TO_CCT_METHODS',
           'xy_to_CCT',
           'CCT_TO_XY_METHODS',
           'CCT_to_xy']

PLANCKIAN_TABLE_TUVD = namedtuple('PlanckianTable_Tuvdi',
                                  ('Ti', 'ui', 'vi', 'di'))

CCT_MINIMAL = 1000
CCT_MAXIMAL = 100000
CCT_SAMPLES = 10
CCT_CALCULATION_ITERATIONS = 6

ROBERTSON_ISOTEMPERATURE_LINES_DATA = (
    (0, 0.18006, 0.26352, -0.24341),
    (10, 0.18066, 0.26589, -0.25479),
    (20, 0.18133, 0.26846, -0.26876),
    (30, 0.18208, 0.27119, -0.28539),
    (40, 0.18293, 0.27407, -0.30470),
    (50, 0.18388, 0.27709, -0.32675),
    (60, 0.18494, 0.28021, -0.35156),
    (70, 0.18611, 0.28342, -0.37915),
    (80, 0.18740, 0.28668, -0.40955),
    (90, 0.18880, 0.28997, -0.44278),
    (100, 0.19032, 0.29326, -0.47888),
    (125, 0.19462, 0.30141, -0.58204),
    (150, 0.19962, 0.30921, -0.70471),
    (175, 0.20525, 0.31647, -0.84901),
    (200, 0.21142, 0.32312, -1.0182),
    (225, 0.21807, 0.32909, -1.2168),
    (250, 0.22511, 0.33439, -1.4512),
    (275, 0.23247, 0.33904, -1.7298),
    (300, 0.24010, 0.34308, -2.0637),
    (325, 0.24792, 0.34655, -2.4681),  # 0.24702 ---> 0.24792 Bruce Lindbloom
    (350, 0.25591, 0.34951, -2.9641),
    (375, 0.26400, 0.35200, -3.5814),
    (400, 0.27218, 0.35407, -4.3633),
    (425, 0.28039, 0.35577, -5.3762),
    (450, 0.28863, 0.35714, -6.7262),
    (475, 0.29685, 0.35823, -8.5955),
    (500, 0.30505, 0.35907, -11.324),
    (525, 0.31320, 0.35968, -15.628),
    (550, 0.32129, 0.36011, -23.325),
    (575, 0.32931, 0.36038, -40.770),
    (600, 0.33724, 0.36051, -116.45))
"""
Robertson (1968) iso-temperature lines.

ROBERTSON_ISOTEMPERATURE_LINES_DATA : tuple
    (Reciprocal Megakelvin,
    CIE 1960 Chromaticity Coordinate *u*,
    CIE 1960 Chromaticity Coordinate *v*,
    Slope)

Notes
-----
-   A correction has been done by Lindbloom for *325* Megakelvin
    temperature: 0.24702 ---> 0.24792

References
----------
.. [2]  Wyszecki, G., & Stiles, W. S. (2000). Table 1(3.11) Isotemperature
        Lines. In Color Science: Concepts and Methods, Quantitative Data and
        Formulae (p. 228). Wiley. ISBN:978-0471399186
"""

ROBERTSON_ISOTEMPERATURE_LINES_RUVT = namedtuple(
    'WyszeckiRobertson_ruvt', ('r', 'u', 'v', 't'))

ROBERTSON_ISOTEMPERATURE_LINES = [
    ROBERTSON_ISOTEMPERATURE_LINES_RUVT(*x)
    for x in ROBERTSON_ISOTEMPERATURE_LINES_DATA]


[docs]def planckian_table(uv, cmfs, start, end, count): """ Returns a planckian table from given *CIE UCS* colourspace *uv* chromaticity coordinates, colour matching functions and temperature range using Ohno (2013) method. Parameters ---------- uv : array_like *uv* chromaticity coordinates. cmfs : XYZ_ColourMatchingFunctions Standard observer colour matching functions. start : numeric Temperature range start in kelvins. end : numeric Temperature range end in kelvins. count : int Temperatures count in the planckian table. Returns ------- list Planckian table. Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> from pprint import pprint >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> pprint(planckian_table((0.1978, 0.3122), cmfs, 1000, 1010, 10)) # noqa # doctest: +ELLIPSIS [PlanckianTable_Tuvdi(Ti=1000.0, ui=0.4480108..., vi=0.3546249..., di=0.2537821...), PlanckianTable_Tuvdi(Ti=1001.1111111..., ui=0.4477508..., vi=0.3546475..., di=0.2535294...), PlanckianTable_Tuvdi(Ti=1002.2222222..., ui=0.4474910..., vi=0.3546700..., di=0.2532771...), PlanckianTable_Tuvdi(Ti=1003.3333333..., ui=0.4472316..., vi=0.3546924..., di=0.2530251...), PlanckianTable_Tuvdi(Ti=1004.4444444..., ui=0.4469724..., vi=0.3547148..., di=0.2527734...), PlanckianTable_Tuvdi(Ti=1005.5555555..., ui=0.4467136..., vi=0.3547372..., di=0.2525220...), PlanckianTable_Tuvdi(Ti=1006.6666666..., ui=0.4464550..., vi=0.3547595..., di=0.2522710...), PlanckianTable_Tuvdi(Ti=1007.7777777..., ui=0.4461968..., vi=0.3547817..., di=0.2520202...), PlanckianTable_Tuvdi(Ti=1008.8888888..., ui=0.4459389..., vi=0.3548040..., di=0.2517697...), PlanckianTable_Tuvdi(Ti=1010.0, ui=0.4456812..., vi=0.3548261..., di=0.2515196...)] """ ux, vx = uv shape = cmfs.shape table = [] for Ti in np.linspace(start, end, count): spd = blackbody_spd(Ti, shape) XYZ = spectral_to_XYZ(spd, cmfs) XYZ *= 1 / np.max(XYZ) UVW = XYZ_to_UCS(XYZ) ui, vi = UCS_to_uv(UVW) di = np.sqrt((ux - ui) ** 2 + (vx - vi) ** 2) table.append(PLANCKIAN_TABLE_TUVD(Ti, ui, vi, di)) return table
[docs]def planckian_table_minimal_distance_index(planckian_table): """ Returns the shortest distance index in given planckian table using Ohno (2013) method. Parameters ---------- planckian_table : list Planckian table. Returns ------- int Shortest distance index. Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> table = planckian_table((0.1978, 0.3122), cmfs, 1000, 1010, 10) >>> planckian_table_minimal_distance_index(table) 9 """ distances = [x.di for x in planckian_table] return distances.index(min(distances))
[docs]def uv_to_CCT_Ohno2013(uv, cmfs=STANDARD_OBSERVERS_CMFS.get( 'CIE 1931 2 Degree Standard Observer'), start=CCT_MINIMAL, end=CCT_MAXIMAL, count=CCT_SAMPLES, iterations=CCT_CALCULATION_ITERATIONS): """ Returns the correlated colour temperature :math:`T_{cp}` and :math:`\Delta_{uv}` from given *CIE UCS* colourspace *uv* chromaticity coordinates, colour matching functions and temperature range using Ohno (2013) method. The iterations parameter defines the calculations precision: The higher its value, the more planckian tables will be generated through cascade expansion in order to converge to the exact solution. Parameters ---------- uv : array_like *CIE UCS* colourspace *uv* chromaticity coordinates. cmfs : XYZ_ColourMatchingFunctions, optional Standard observer colour matching functions. start : numeric, optional Temperature range start in kelvins. end : numeric, optional Temperature range end in kelvins. count : int, optional Temperatures count in the planckian tables. iterations : int, optional Number of planckian tables to generate. Returns ------- tuple Correlated colour temperature :math:`T_{cp}`, :math:`\Delta_{uv}`. References ---------- .. [3] Ohno, Y. (2014). Practical Use and Calculation of CCT and Duv. LEUKOS, 10(1), 47–55. doi:10.1080/15502724.2014.839020 Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> uv_to_CCT_Ohno2013((0.1978, 0.3122), cmfs) # doctest: +ELLIPSIS (6507.5470349..., 0.0032236...) """ # Ensuring we do at least one iteration to initialise variables. if iterations <= 0: iterations = 1 # Planckian table creation through cascade expansion. for i in range(iterations): table = planckian_table(uv, cmfs, start, end, count) index = planckian_table_minimal_distance_index(table) if index == 0: warning( ('Minimal distance index is on lowest planckian table bound, ' 'unpredictable results may occur!')) index += 1 elif index == len(table) - 1: warning( ('Minimal distance index is on highest planckian table bound, ' 'unpredictable results may occur!')) index -= 1 start = table[index - 1].Ti end = table[index + 1].Ti ux, vx = uv Tuvdip, Tuvdi, Tuvdin = (table[index - 1], table[index], table[index + 1]) Tip, uip, vip, dip = Tuvdip.Ti, Tuvdip.ui, Tuvdip.vi, Tuvdip.di Ti, di = Tuvdi.Ti, Tuvdi.di Tin, uin, vin, din = Tuvdin.Ti, Tuvdin.ui, Tuvdin.vi, Tuvdin.di # Triangular solution. l = np.sqrt((uin - uip) ** 2 + (vin - vip) ** 2) x = (dip ** 2 - din ** 2 + l ** 2) / (2 * l) T = Tip + (Tin - Tip) * (x / l) vtx = vip + (vin - vip) * (x / l) sign = 1 if vx - vtx >= 0 else -1 D_uv = (dip ** 2 - x ** 2) ** (1 / 2) * sign # Parabolic solution. if D_uv < 0.002: X = (Tin - Ti) * (Tip - Tin) * (Ti - Tip) a = (Tip * (din - di) + Ti * (dip - din) + Tin * (di - dip)) * X ** -1 b = (-(Tip ** 2 * (din - di) + Ti ** 2 * (dip - din) + Tin ** 2 * (di - dip)) * X ** -1) c = (-(dip * (Tin - Ti) * Ti * Tin + di * (Tip - Tin) * Tip * Tin + din * (Ti - Tip) * Tip * Ti) * X ** -1) T = -b / (2 * a) D_uv = sign * (a * T ** 2 + b * T + c) return T, D_uv
[docs]def CCT_to_uv_Ohno2013(CCT, D_uv=0, cmfs=STANDARD_OBSERVERS_CMFS.get( 'CIE 1931 2 Degree Standard Observer')): """ Returns the *CIE UCS* colourspace *uv* chromaticity coordinates from given correlated colour temperature :math:`T_{cp}`, :math:`\Delta_{uv}` and colour matching functions using Ohno (2013) method. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. D_uv : numeric, optional :math:`\Delta_{uv}`. cmfs : XYZ_ColourMatchingFunctions, optional Standard observer colour matching functions. Returns ------- tuple *CIE UCS* colourspace *uv* chromaticity coordinates. References ---------- .. [4] Ohno, Y. (2014). Practical Use and Calculation of CCT and Duv. LEUKOS, 10(1), 47–55. doi:10.1080/15502724.2014.839020 Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> CCT = 6507.4342201047066 >>> D_uv = 0.003223690901512735 >>> CCT_to_uv_Ohno2013(CCT, D_uv, cmfs) # doctest: +ELLIPSIS (0.1978003..., 0.3122005...) """ shape = cmfs.shape delta = 0.01 spd = blackbody_spd(CCT, shape) XYZ = spectral_to_XYZ(spd, cmfs) XYZ *= 1 / np.max(XYZ) UVW = XYZ_to_UCS(XYZ) u0, v0 = UCS_to_uv(UVW) if D_uv == 0: return u0, v0 else: spd = blackbody_spd(CCT + delta, shape) XYZ = spectral_to_XYZ(spd, cmfs) XYZ *= 1 / np.max(XYZ) UVW = XYZ_to_UCS(XYZ) u1, v1 = UCS_to_uv(UVW) du = u0 - u1 dv = v0 - v1 u = u0 - D_uv * (dv / np.sqrt(du ** 2 + dv ** 2)) v = v0 + D_uv * (du / np.sqrt(du ** 2 + dv ** 2)) return u, v
[docs]def uv_to_CCT_Robertson1968(uv): """ Returns the correlated colour temperature :math:`T_{cp}` and :math:`\Delta_{uv}` from given *CIE UCS* colourspace *uv* chromaticity coordinates using *Roberston (1968)* method. Parameters ---------- uv : array_like *CIE UCS* colourspace *uv* chromaticity coordinates. Returns ------- tuple Correlated colour temperature :math:`T_{cp}`, :math:`\Delta_{uv}`. References ---------- .. [5] Wyszecki, G., & Stiles, W. S. (2000). DISTRIBUTION TEMPERATURE, COLOR TEMPERATURE, AND CORRELATED COLOR TEMPERATURE. In Color Science: Concepts and Methods, Quantitative Data and Formulae (pp. 224–229). Wiley. ISBN:978-0471399186 .. [6] Adobe Systems. (2013). Adobe DNG Software Development Kit (SDK) - 1.3.0.0 - dng_sdk_1_3/dng_sdk/source/dng_temperature.cpp:: dng_temperature::Set_xy_coord. Retrieved from https://www.adobe.com/support/downloads/dng/dng_sdk.html Examples -------- >>> uv = (0.19374137599822966, 0.31522104394059397) >>> uv_to_CCT_Robertson1968(uv) # doctest: +ELLIPSIS (6500.0162879..., 0.0083333...) """ u, v = uv last_dt = last_dv = last_du = 0.0 for i in range(1, 31): wr_ruvt = ROBERTSON_ISOTEMPERATURE_LINES[i] wr_ruvt_previous = ROBERTSON_ISOTEMPERATURE_LINES[i - 1] du = 1.0 dv = wr_ruvt.t length = np.sqrt(1 + dv * dv) du /= length dv /= length uu = u - wr_ruvt.u vv = v - wr_ruvt.v dt = -uu * dv + vv * du if dt <= 0 or i == 30: if dt > 0.0: dt = 0.0 dt = -dt if i == 1: f = 0.0 else: f = dt / (last_dt + dt) T = 1.0e6 / (wr_ruvt_previous.r * f + wr_ruvt.r * (1 - f)) uu = u - (wr_ruvt_previous.u * f + wr_ruvt.u * (1 - f)) vv = v - (wr_ruvt_previous.v * f + wr_ruvt.v * (1 - f)) du = du * (1 - f) + last_du * f dv = dv * (1 - f) + last_dv * f length = np.sqrt(du * du + dv * dv) du /= length dv /= length D_uv = uu * du + vv * dv break last_dt = dt last_du = du last_dv = dv return T, -D_uv
[docs]def CCT_to_uv_Robertson1968(CCT, D_uv=0): """ Returns the *CIE UCS* colourspace *uv* chromaticity coordinates from given correlated colour temperature :math:`T_{cp}` and :math:`\Delta_{uv}` using *Roberston (1968)* method. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. D_uv : numeric :math:`\Delta_{uv}`. Returns ------- tuple *CIE UCS* colourspace *uv* chromaticity coordinates. References ---------- .. [7] Wyszecki, G., & Stiles, W. S. (2000). DISTRIBUTION TEMPERATURE, COLOR TEMPERATURE, AND CORRELATED COLOR TEMPERATURE. In Color Science: Concepts and Methods, Quantitative Data and Formulae (pp. 224–229). Wiley. ISBN:978-0471399186 .. [8] Adobe Systems. (2013). Adobe DNG Software Development Kit (SDK) - 1.3.0.0 - dng_sdk_1_3/dng_sdk/source/dng_temperature.cpp:: dng_temperature::xy_coord. Retrieved from https://www.adobe.com/support/downloads/dng/dng_sdk.html Examples -------- >>> CCT = 6500.0081378199056 >>> D_uv = 0.0083333312442250979 >>> CCT_to_uv_Robertson1968(CCT, D_uv) # doctest: +ELLIPSIS (0.1937413..., 0.3152210...) """ r = 1.0e6 / CCT for i in range(30): wr_ruvt = ROBERTSON_ISOTEMPERATURE_LINES[i] wr_ruvt_next = ROBERTSON_ISOTEMPERATURE_LINES[i + 1] if r < wr_ruvt_next.r or i == 29: f = (wr_ruvt_next.r - r) / (wr_ruvt_next.r - wr_ruvt.r) u = wr_ruvt.u * f + wr_ruvt_next.u * (1 - f) v = wr_ruvt.v * f + wr_ruvt_next.v * (1 - f) uu1 = uu2 = 1.0 vv1, vv2 = wr_ruvt.t, wr_ruvt_next.t length1 = np.sqrt(1 + vv1 * vv1) length2 = np.sqrt(1 + vv2 * vv2) uu1 /= length1 vv1 /= length1 uu2 /= length2 vv2 /= length2 uu3 = uu1 * f + uu2 * (1 - f) vv3 = vv1 * f + vv2 * (1 - f) len3 = np.sqrt(uu3 * uu3 + vv3 * vv3) uu3 /= len3 vv3 /= len3 u += uu3 * -D_uv v += vv3 * -D_uv return u, v
UV_TO_CCT_METHODS = CaseInsensitiveMapping( {'Ohno 2013': uv_to_CCT_Ohno2013, 'Robertson 1968': uv_to_CCT_Robertson1968}) """ Supported *CIE UCS* colourspace *uv* chromaticity coordinates to correlated colour temperature :math:`T_{cp}` computation methods. UV_TO_CCT_METHODS : CaseInsensitiveMapping {'Ohno 2013', 'Robertson 1968'} Aliases: - 'ohno2013': 'Ohno 2013' - 'robertson1968': 'Robertson 1968' """ UV_TO_CCT_METHODS['ohno2013'] = UV_TO_CCT_METHODS['Ohno 2013'] UV_TO_CCT_METHODS['robertson1968'] = UV_TO_CCT_METHODS['Robertson 1968']
[docs]def uv_to_CCT(uv, method='Ohno 2013', **kwargs): """ Returns the correlated colour temperature :math:`T_{cp}` and :math:`\Delta_{uv}` from given *CIE UCS* colourspace *uv* chromaticity coordinates using given method. Parameters ---------- uv : array_like *CIE UCS* colourspace *uv* chromaticity coordinates. method : unicode, optional {'Ohno 2013', 'Robertson 1968'} Computation method. \*\*kwargs : \*\* Keywords arguments. Returns ------- tuple Correlated colour temperature :math:`T_{cp}`, :math:`\Delta_{uv}`. Raises ------ ValueError If the computation method is not defined. Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> uv_to_CCT((0.1978, 0.3122), cmfs=cmfs) # doctest: +ELLIPSIS (6507.5470349..., 0.0032236...) """ if method == 'Ohno 2013': return UV_TO_CCT_METHODS.get(method)(uv, **kwargs) else: if 'cmfs' in kwargs: if kwargs.get('cmfs').name != ( 'CIE 1931 2 Degree Standard Observer'): raise ValueError( ('Robertson (1968) method is only valid for ' '"CIE 1931 2 Degree Standard Observer"!')) return UV_TO_CCT_METHODS.get(method)(uv)
CCT_TO_UV_METHODS = CaseInsensitiveMapping( {'Ohno 2013': CCT_to_uv_Ohno2013, 'Robertson 1968': CCT_to_uv_Robertson1968}) """ Supported correlated colour temperature :math:`T_{cp}` to *CIE UCS* colourspace *uv* chromaticity coordinates computation methods. CCT_TO_UV_METHODS : CaseInsensitiveMapping {'Ohno 2013', 'Robertson 1968'} Aliases: - 'ohno2013': 'Ohno 2013' - 'robertson1968': 'Robertson 1968' """ CCT_TO_UV_METHODS['ohno2013'] = CCT_TO_UV_METHODS['Ohno 2013'] CCT_TO_UV_METHODS['robertson1968'] = CCT_TO_UV_METHODS['Robertson 1968']
[docs]def CCT_to_uv(CCT, D_uv=0, method='Ohno 2013', **kwargs): """ Returns the *CIE UCS* colourspace *uv* chromaticity coordinates from given correlated colour temperature :math:`T_{cp}` and :math:`\Delta_{uv}` using given method. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. D_uv : numeric :math:`\Delta_{uv}`. method : unicode, optional {'Ohno 2013', 'Robertson 1968'} Computation method. \*\*kwargs : \*\* Keywords arguments. Returns ------- tuple *CIE UCS* colourspace *uv* chromaticity coordinates. Raises ------ ValueError If the computation method is not defined. Examples -------- >>> from colour import STANDARD_OBSERVERS_CMFS >>> cmfs = 'CIE 1931 2 Degree Standard Observer' >>> cmfs = STANDARD_OBSERVERS_CMFS.get(cmfs) >>> CCT = 6507.4342201047066 >>> D_uv = 0.003223690901512735 >>> CCT_to_uv(CCT, D_uv, cmfs=cmfs) # doctest: +ELLIPSIS (0.1978003..., 0.3122005...) """ if method == 'Ohno 2013': return CCT_TO_UV_METHODS.get(method)(CCT, D_uv, **kwargs) else: if 'cmfs' in kwargs: if kwargs.get('cmfs').name != ( 'CIE 1931 2 Degree Standard Observer'): raise ValueError( ('Robertson (1968) method is only valid for ' '"CIE 1931 2 Degree Standard Observer"!')) return CCT_TO_UV_METHODS.get(method)(CCT, D_uv)
[docs]def xy_to_CCT_McCamy1992(xy): """ Returns the correlated colour temperature :math:`T_{cp}` from given *CIE XYZ* colourspace *xy* chromaticity coordinates using McCamy (1992) method. Parameters ---------- xy : array_like *xy* chromaticity coordinates. Returns ------- numeric Correlated colour temperature :math:`T_{cp}`. References ---------- .. [9] Wikipedia. (n.d.). Approximation. Retrieved June 28, 2014, from http://en.wikipedia.org/wiki/Color_temperature#Approximation Examples -------- >>> xy_to_CCT_McCamy1992((0.31271, 0.32902)) # doctest: +ELLIPSIS 6504.3893830... """ x, y = xy n = (x - 0.3320) / (y - 0.1858) CCT = -449 * n ** 3 + 3525 * n ** 2 - 6823.3 * n + 5520.33 return CCT
[docs]def xy_to_CCT_Hernandez1999(xy): """ Returns the correlated colour temperature :math:`T_{cp}` from given *CIE XYZ* colourspace *xy* chromaticity coordinates using Hernandez-Andres, Lee and Romero (1999) method. Parameters ---------- xy : array_like *xy* chromaticity coordinates. Returns ------- numeric Correlated colour temperature :math:`T_{cp}`. References ---------- .. [10] Hernández-Andrés, J., Lee, R. L., & Romero, J. (1999). Calculating correlated color temperatures across the entire gamut of daylight and skylight chromaticities. Applied Optics, 38(27), 5703–5709. doi:10.1364/AO.38.005703 Examples -------- >>> xy_to_CCT_Hernandez1999((0.31271, 0.32902)) # doctest: +ELLIPSIS 6500.0421533... """ x, y = xy n = (x - 0.3366) / (y - 0.1735) CCT = (-949.86315 + 6253.80338 * np.exp(-n / 0.92159) + 28.70599 * np.exp(-n / 0.20039) + 0.00004 * np.exp(-n / 0.07125)) if CCT > 50000: n = (x - 0.3356) / (y - 0.1691) CCT = (36284.48953 + 0.00228 * np.exp(-n / 0.07861) + 5.4535e-36 * np.exp(-n / 0.01543)) return CCT
[docs]def CCT_to_xy_Kang2002(CCT): """ Returns the *CIE XYZ* colourspace *xy* chromaticity coordinates from given correlated colour temperature :math:`T_{cp}` using Kang et al. (2002) method. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. Returns ------- tuple *xy* chromaticity coordinates. Raises ------ ValueError If the correlated colour temperature is not in appropriate domain. References ---------- .. [11] Kang, B., Moon, O., Hong, C., Lee, H., Cho, B., & Kim, Y. (2002). Design of advanced color: Temperature control system for HDTV applications. Journal of the Korean …, 41(6), 865–871. Retrieved from http://cat.inist.fr/?aModele=afficheN&cpsidt=14448733 Examples -------- >>> CCT_to_xy_Kang2002(6504.38938305) # doctest: +ELLIPSIS (0.3134259..., 0.3235959...) """ if 1667 <= CCT <= 4000: x = (-0.2661239 * 10 ** 9 / CCT ** 3 - 0.2343589 * 10 ** 6 / CCT ** 2 + 0.8776956 * 10 ** 3 / CCT + 0.179910) elif 4000 <= CCT <= 25000: x = (-3.0258469 * 10 ** 9 / CCT ** 3 + 2.1070379 * 10 ** 6 / CCT ** 2 + 0.2226347 * 10 ** 3 / CCT + 0.24039) else: raise ValueError( 'Correlated colour temperature must be in domain [1667, 25000]!') if 1667 <= CCT <= 2222: y = (-1.1063814 * x ** 3 - 1.34811020 * x ** 2 + 2.18555832 * x - 0.20219683) elif 2222 <= CCT <= 4000: y = (-0.9549476 * x ** 3 - 1.37418593 * x ** 2 + 2.09137015 * x - 0.16748867) elif 4000 <= CCT <= 25000: y = (3.0817580 * x ** 3 - 5.8733867 * x ** 2 + 3.75112997 * x - 0.37001483) return x, y
[docs]def CCT_to_xy_CIE_D(CCT): """ Converts from the correlated colour temperature :math:`T_{cp}` of a *CIE Illuminant D Series* to the chromaticity of that *CIE Illuminant D Series* illuminant. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. Returns ------- tuple *xy* chromaticity coordinates. Raises ------ ValueError If the correlated colour temperature is not in appropriate domain. References ---------- .. [12] Wyszecki, G., & Stiles, W. S. (2000). CIE Method of Calculating D-Illuminants. In Color Science: Concepts and Methods, Quantitative Data and Formulae (pp. 145–146). Wiley. ISBN:978-0471399186 Examples -------- >>> CCT_to_xy_CIE_D(6504.38938305) # doctest: +ELLIPSIS (0.3127077..., 0.3291128...) """ if 4000 <= CCT <= 7000: x = (-4.607 * 10 ** 9 / CCT ** 3 + 2.9678 * 10 ** 6 / CCT ** 2 + 0.09911 * 10 ** 3 / CCT + 0.244063) elif 7000 < CCT <= 25000: x = (-2.0064 * 10 ** 9 / CCT ** 3 + 1.9018 * 10 ** 6 / CCT ** 2 + 0.24748 * 10 ** 3 / CCT + 0.23704) else: raise ValueError( 'Correlated colour temperature must be in domain [4000, 25000]!') y = -3 * x ** 2 + 2.87 * x - 0.275 return x, y
XY_TO_CCT_METHODS = CaseInsensitiveMapping( {'McCamy 1992': xy_to_CCT_McCamy1992, 'Hernandez 1999': xy_to_CCT_Hernandez1999}) """ Supported *CIE XYZ* colourspace *xy* chromaticity coordinates to correlated colour temperature :math:`T_{cp}` computation methods. XY_TO_CCT_METHODS : CaseInsensitiveMapping {'McCamy 1992', 'Hernandez 1999'} Aliases: - 'mccamy1992': 'McCamy 1992' - 'hernandez1999': 'Hernandez 1999' """ XY_TO_CCT_METHODS['mccamy1992'] = XY_TO_CCT_METHODS['McCamy 1992'] XY_TO_CCT_METHODS['hernandez1999'] = XY_TO_CCT_METHODS['Hernandez 1999']
[docs]def xy_to_CCT(xy, method='McCamy 1992', **kwargs): """ Returns the correlated colour temperature :math:`T_{cp}` from given *CIE XYZ* colourspace *xy* chromaticity coordinates using given method. Parameters ---------- xy : array_like *xy* chromaticity coordinates. method : unicode, optional {'McCamy 1992', 'Hernandez 1999'} Computation method. \*\*kwargs : \*\* Keywords arguments. Returns ------- numeric Correlated colour temperature :math:`T_{cp}`. """ return XY_TO_CCT_METHODS.get(method)(xy)
CCT_TO_XY_METHODS = CaseInsensitiveMapping( {'Kang 2002': CCT_to_xy_Kang2002, 'CIE Illuminant D Series': CCT_to_xy_CIE_D}) """ Supported correlated colour temperature :math:`T_{cp}` to *CIE XYZ* colourspace *xy* chromaticity coordinates computation methods. CCT_TO_XY_METHODS : CaseInsensitiveMapping {'Kang 2002', 'CIE Illuminant D Series'} Aliases: - 'kang2002': 'Kang 2002' - 'cie_d': 'Hernandez 1999' """ CCT_TO_XY_METHODS['kang2002'] = CCT_TO_XY_METHODS['Kang 2002'] CCT_TO_XY_METHODS['cie_d'] = CCT_TO_XY_METHODS['CIE Illuminant D Series']
[docs]def CCT_to_xy(CCT, method='Kang 2002'): """ Returns the *CIE XYZ* colourspace *xy* chromaticity coordinates from given correlated colour temperature :math:`T_{cp}` using given method. Parameters ---------- CCT : numeric Correlated colour temperature :math:`T_{cp}`. method : unicode, optional {'Kang 2002', 'CIE Illuminant D Series'} Computation method. Returns ------- tuple *xy* chromaticity coordinates. """ return CCT_TO_XY_METHODS.get(method)(CCT)