Exemplo n.º 1
0
def oetf_reverse_ARIBSTDB67(E_p, r=0.5, constants=ARIBSTDB67_CONSTANTS):
    """
    Defines *ARIB STD-B67 (Hybrid Log-Gamma)* reverse opto-electrical transfer
    function (OETF / OECF).

    Parameters
    ----------
    E_p : numeric or array_like
        Non-linear signal :math:`E'`.
    r : numeric, optional
        Video level corresponding to reference white level.
    constants : Structure, optional
        *ARIB STD-B67 (Hybrid Log-Gamma)* constants.

    Returns
    -------
    numeric or ndarray
        Voltage :math:`E` normalised by the reference white level and
        proportional to the implicit light intensity that would be detected
        with a reference camera color channel R, G, B.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E_p``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`AssociationofRadioIndustriesandBusinesses2015a`

    Examples
    --------
    >>> oetf_reverse_ARIBSTDB67(0.212132034355964)  # doctest: +ELLIPSIS
    0.1799999...
    """

    E_p = to_domain_1(E_p)

    a = constants.a
    b = constants.b
    c = constants.c

    with domain_range_scale('ignore'):
        E = np.where(
            E_p <= oetf_ARIBSTDB67(1),
            (E_p / r) ** 2,
            np.exp((E_p - c) / a) + b,
        )

    return as_float(from_range_1(E))
Exemplo n.º 2
0
def uv_to_Luv(
        uv,
        illuminant=ILLUMINANTS['CIE 1931 2 Degree Standard Observer']['D65'],
        Y=1):
    """
    Returns the *CIE L\\*u\\*v\\** colourspace array from given :math:`uv^p`
    chromaticity coordinates by extending the array last dimension with given
    :math:`L` *Lightness*.

    Parameters
    ----------
    uv : array_like
        :math:`uv^p` chromaticity coordinates.
    illuminant : array_like, optional
        Reference *illuminant* *xy* chromaticity coordinates or *CIE xyY*
        colourspace array.
    Y : numeric, optional
        Optional :math:`Y` *luminance* value used to construct the intermediate
        *CIE XYZ* colourspace array, the default :math:`Y` *luminance* value is
        1.

    Returns
    -------
    ndarray
        *CIE L\\*u\\*v\\** colourspace array.

    Notes
    -----

    +----------------+-----------------------+-----------------+
    | **Range**      | **Scale - Reference** | **Scale - 1**   |
    +================+=======================+=================+
    | ``Luv``        | ``L`` : [0, 100]      | ``L`` : [0, 1]  |
    |                |                       |                 |
    |                | ``u`` : [-100, 100]   | ``u`` : [-1, 1] |
    |                |                       |                 |
    |                | ``v`` : [-100, 100]   | ``v`` : [-1, 1] |
    +----------------+-----------------------+-----------------+
    | ``illuminant`` | [0, 1]                | [0, 1]          |
    +----------------+-----------------------+-----------------+

    References
    ----------
    :cite:`CIETC1-482004j`

    Examples
    --------
    >>> uv = np.array([0.37720213, 0.50120264])
    >>> uv_to_Luv(uv)  # doctest: +ELLIPSIS
    array([ 100.        ,  233.1837603...,   42.7474385...])
    """

    u, v = tsplit(uv)
    Y = to_domain_1(Y)

    X = 9 * u / (4 * v)
    Z = (-5 * Y * v - 3 * u / 4 + 3) / v
    Y = np.full(u.shape, Y, DEFAULT_FLOAT_DTYPE)

    return XYZ_to_Luv(from_range_1(tstack([X, Y, Z])), illuminant)
Exemplo n.º 3
0
def XYZ_to_xyY(
        XYZ,
        illuminant=ILLUMINANTS['CIE 1931 2 Degree Standard Observer']['D65']):
    """
    Converts from *CIE XYZ* tristimulus values to *CIE xyY* colourspace and
    reference *illuminant*.

    Parameters
    ----------
    XYZ : array_like
        *CIE XYZ* tristimulus values.
    illuminant : array_like, optional
        Reference *illuminant* chromaticity coordinates.

    Returns
    -------
    ndarray
        *CIE xyY* colourspace array.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``XYZ``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``xyY``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Lindbloom2003e`, :cite:`Wikipedia2005`

    Examples
    --------
    >>> XYZ = np.array([0.20654008, 0.12197225, 0.05136952])
    >>> XYZ_to_xyY(XYZ)  # doctest: +ELLIPSIS
    array([ 0.5436955...,  0.3210794...,  0.1219722...])
    """

    XYZ = to_domain_1(XYZ)
    X, Y, Z = tsplit(XYZ)
    xy_w = as_float_array(illuminant)

    XYZ_n = np.zeros(XYZ.shape)
    XYZ_n[..., 0:2] = xy_w

    xyY = np.where(
        np.all(XYZ == 0, axis=-1)[..., np.newaxis],
        XYZ_n,
        tstack([X / (X + Y + Z), Y / (X + Y + Z),
                from_range_1(Y)]),
    )

    return xyY
Exemplo n.º 4
0
def lightness_Fairchild2011(Y, epsilon=0.474, method='hdr-CIELAB'):
    """
    Computes *Lightness* :math:`L_{hdr}` of given *luminance* :math:`Y` using
    *Fairchild and Chen (2011)* method according to *Michealis-Menten*
    kinetics.

    Parameters
    ----------
    Y : array_like
        *luminance* :math:`Y`.
    epsilon : numeric or array_like, optional
        :math:`\\epsilon` exponent.
    method : unicode, optional
        **{'hdr-CIELAB', 'hdr-IPT'}**,
        *Lightness* :math:`L_{hdr}` computation method.

    Returns
    -------
    array_like
        *Lightness* :math:`L_{hdr}`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``Y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_hdr``  | [0, 100]              | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Fairchild2011`

    Examples
    --------
    >>> lightness_Fairchild2011(12.19722535 / 100)  # doctest: +ELLIPSIS
    51.8529584...
    >>> lightness_Fairchild2011(12.19722535 / 100, method='hdr-IPT')
    ... # doctest: +ELLIPSIS
    51.6431084...
    """

    Y = to_domain_1(Y)

    if method.lower() == 'hdr-cielab':
        maximum_perception = 247
    else:
        maximum_perception = 246

    L_hdr = reaction_rate_MichealisMenten(
        spow(Y, epsilon), maximum_perception, 2 ** epsilon) + 0.02

    return from_range_100(L_hdr)
Exemplo n.º 5
0
def eotf_BT1886(V, L_B=0, L_W=1):
    """
    Defines *Recommendation ITU-R BT.1886* electro-optical transfer function
    (EOTF / EOCF).

    Parameters
    ----------
    V : numeric or array_like
        Input video signal level (normalised, black at :math:`V = 0`, to white
        at :math:`V = 1`. For content mastered per
        *Recommendation ITU-R BT.709*, 10-bit digital code values :math:`D` map
        into values of :math:`V` per the following equation:
        :math:`V = (D-64)/876`
    L_B : numeric, optional
        Screen luminance for black.
    L_W : numeric, optional
        Screen luminance for white.

    Returns
    -------
    numeric or ndarray
        Screen luminance in :math:`cd/m^2`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2011h`

    Examples
    --------
    >>> eotf_BT1886(0.409007728864150)  # doctest: +ELLIPSIS
    0.1169918...
    """

    V = to_domain_1(V)

    gamma = 2.40
    gamma_d = 1 / gamma

    n = L_W ** gamma_d - L_B ** gamma_d
    a = n ** gamma
    b = L_B ** gamma_d / n
    L = a * np.maximum(V + b, 0) ** gamma

    return from_range_1(L)
Exemplo n.º 6
0
def log_encoding_ALEXALogC(x,
                           firmware='SUP 3.x',
                           method='Linear Scene Exposure Factor',
                           EI=800):
    """
    Defines the *ALEXA Log C* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    firmware : unicode, optional
        **{'SUP 3.x', 'SUP 2.x'}**,
        Alexa firmware version.
    method : unicode, optional
        **{'Linear Scene Exposure Factor', 'Normalised Sensor Signal'}**,
        Conversion method.
    EI : int,  optional
        Ei.

    Returns
    -------
    numeric or ndarray
        *ALEXA Log C* encoded data :math:`t`.

    References
    ----------
    :cite:`ARRI2012a`

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``t``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    Examples
    --------
    >>> log_encoding_ALEXALogC(0.18)  # doctest: +ELLIPSIS
    0.3910068...
    """

    x = to_domain_1(x)

    cut, a, b, c, d, e, f, _e_cut_f = (
        ALEXA_LOG_C_CURVE_CONVERSION_DATA[firmware][method][EI])

    t = np.where(x > cut, c * np.log10(a * x + b) + d, e * x + f)

    return as_float(from_range_1(t))
Exemplo n.º 7
0
def log_decoding_ALEXALogC(t,
                           firmware='SUP 3.x',
                           method='Linear Scene Exposure Factor',
                           EI=800):
    """
    Defines the *ALEXA Log C* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    t : numeric or array_like
        *ALEXA Log C* encoded data :math:`t`.
    firmware : unicode, optional
        **{'SUP 3.x', 'SUP 2.x'}**,
        Alexa firmware version.
    method : unicode,  optional
        **{'Linear Scene Exposure Factor', 'Normalised Sensor Signal'}**,
        Conversion method.
    EI : int,  optional
        Ei.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``t``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`ARRI2012a`

    Examples
    --------
    >>> log_decoding_ALEXALogC(0.391006832034084)  # doctest: +ELLIPSIS
    0.18...
    """

    t = to_domain_1(t)

    cut, a, b, c, d, e, f, _e_cut_f = (
        ALEXA_LOG_C_CURVE_CONVERSION_DATA[firmware][method][EI])

    x = np.where(t > e * cut + f, (10 ** ((t - d) / c) - b) / a, (t - f) / e)

    return as_float(from_range_1(x))
Exemplo n.º 8
0
def log_encoding_PivotedLog(x,
                            log_reference=445,
                            linear_reference=0.18,
                            negative_gamma=0.6,
                            density_per_code_value=0.002):
    """
    Defines the *Josh Pines* style *Pivoted Log* log encoding curve /
    opto-electronic transfer function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    log_reference : numeric or array_like
        Log reference.
    linear_reference : numeric or array_like
        Linear reference.
    negative_gamma : numeric or array_like
        Negative gamma.
    density_per_code_value : numeric or array_like
        Density per code value.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`y`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SonyImageworks2012a`

    Examples
    --------
    >>> log_encoding_PivotedLog(0.18)  # doctest: +ELLIPSIS
    0.4349951...
    """

    x = to_domain_1(x)

    y = ((log_reference + np.log10(x / linear_reference) /
          (density_per_code_value / negative_gamma)) / 1023)

    return from_range_1(y)
Exemplo n.º 9
0
def CMY_to_CMYK(CMY):
    """
    Converts from *CMY* colourspace to *CMYK* colourspace.

    Parameters
    ----------
    CMY : array_like
        *CMY* colourspace array.

    Returns
    -------
    ndarray
        *CMYK* array.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``CMY``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``CMYK``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`EasyRGBo`

    Examples
    --------
    >>> CMY = np.array([0.54379481, 0.96918929, 0.95908048])
    >>> CMY_to_CMYK(CMY)  # doctest: +ELLIPSIS
    array([ 0.        ,  0.9324630...,  0.9103045...,  0.5437948...])
    """

    C, M, Y = tsplit(to_domain_1(CMY))

    K = np.ones(C.shape)
    K = np.where(C < K, C, K)
    K = np.where(M < K, M, K)
    K = np.where(Y < K, Y, K)

    C = as_float_array((C - K) / (1 - K))
    M = as_float_array((M - K) / (1 - K))
    Y = as_float_array((Y - K) / (1 - K))

    C[np.asarray(K == 1)] = 0
    M[np.asarray(K == 1)] = 0
    Y[np.asarray(K == 1)] = 0

    CMYK = tstack([C, M, Y, K])

    return from_range_1(CMYK)
Exemplo n.º 10
0
def log_decoding_PivotedLog(y,
                            log_reference=445,
                            linear_reference=0.18,
                            negative_gamma=0.6,
                            density_per_code_value=0.002):
    """
    Defines the *Josh Pines* style *Pivoted Log* log decoding curve /
    electro-optical transfer function.

    Parameters
    ----------
    y : numeric or array_like
        Non-linear data :math:`y`.
    log_reference : numeric or array_like
        Log reference.
    linear_reference : numeric or array_like
        Linear reference.
    negative_gamma : numeric or array_like
        Negative gamma.
    density_per_code_value : numeric or array_like
        Density per code value.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SonyImageworks2012a`

    Examples
    --------
    >>> log_decoding_PivotedLog(0.434995112414467)  # doctest: +ELLIPSIS
    0.1...
    """

    y = to_domain_1(y)

    x = (10 ** ((y * 1023 - log_reference) *
                (density_per_code_value / negative_gamma)) * linear_reference)

    return from_range_1(x)
Exemplo n.º 11
0
def eotf_reverse_BT1886(L, L_B=0, L_W=1):
    """
    Defines *Recommendation ITU-R BT.1886* reverse electro-optical transfer
    function (EOTF / EOCF).

    Parameters
    ----------
    L : numeric or array_like
        Screen luminance in :math:`cd/m^2`.
    L_B : numeric, optional
        Screen luminance for black.
    L_W : numeric, optional
        Screen luminance for white.

    Returns
    -------
    numeric or ndarray
        Input video signal level (normalised, black at :math:`V = 0`, to white
        at :math:`V = 1`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2011h`

    Examples
    --------
    >>> eotf_reverse_BT1886(0.11699185725296059)  # doctest: +ELLIPSIS
    0.4090077...
    """

    L = to_domain_1(L)

    gamma = 2.40
    gamma_d = 1 / gamma

    n = L_W ** gamma_d - L_B ** gamma_d
    a = n ** gamma
    b = L_B ** gamma_d / n

    V = (L / a) ** gamma_d - b

    return from_range_1(V)
Exemplo n.º 12
0
def oetf_ARIBSTDB67(E, r=0.5, constants=ARIBSTDB67_CONSTANTS):
    """
    Defines *ARIB STD-B67 (Hybrid Log-Gamma)* opto-electrical transfer
    function (OETF / OECF).

    Parameters
    ----------
    E : numeric or array_like
        Voltage normalised by the reference white level and proportional to
        the implicit light intensity that would be detected with a reference
        camera color channel R, G, B.
    r : numeric, optional
        Video level corresponding to reference white level.
    constants : Structure, optional
        *ARIB STD-B67 (Hybrid Log-Gamma)* constants.

    Returns
    -------
    numeric or ndarray
        Resulting non-linear signal :math:`E'`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E_p``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`AssociationofRadioIndustriesandBusinesses2015a`

    Examples
    --------
    >>> oetf_ARIBSTDB67(0.18)  # doctest: +ELLIPSIS
    0.2121320...
    """

    E = to_domain_1(E)

    a = constants.a
    b = constants.b
    c = constants.c

    E_p = np.where(E <= 1, r * np.sqrt(E), a * np.log(E - b) + c)

    return as_float(from_range_1(E_p))
Exemplo n.º 13
0
def lightness_Fairchild2010(Y, epsilon=1.836):
    """
    Computes *Lightness* :math:`L_{hdr}` of given *luminance* :math:`Y` using
    *Fairchild and Wyble (2010)* method according to *Michealis-Menten*
    kinetics.

    Parameters
    ----------
    Y : array_like
        *luminance* :math:`Y`.
    epsilon : numeric or array_like, optional
        :math:`\\epsilon` exponent.

    Returns
    -------
    array_like
        *Lightness* :math:`L_{hdr}`.

    Warning
    -------
    The input domain of that definition is non standard!

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``Y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_hdr``  | [0, 100]              | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Fairchild2010`

    Examples
    --------
    >>> lightness_Fairchild2010(12.19722535 / 100)  # doctest: +ELLIPSIS
    31.9963902...
    """

    Y = to_domain_1(Y)

    maximum_perception = 100

    L_hdr = reaction_rate_MichealisMenten(
        spow(Y, epsilon), maximum_perception, 0.184 ** epsilon) + 0.02

    return from_range_100(L_hdr)
Exemplo n.º 14
0
def log_encoding_FilmicPro6(t):
    """
    Defines the *FiLMiC Pro 6* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    t : numeric or array_like
        Linear data :math:`t`.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`y`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``t``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    -   The *FiLMiC Pro 6* log encoding curve / opto-electronic transfer
        function is only defined for domain (0, 1].

    References
    ----------
    :cite:`FiLMiCInc2017`

    Warnings
    --------
    The *FiLMiC Pro 6* log encoding curve / opto-electronic transfer function
    was fitted with poor precision and has :math:`Y=1.000000819999999` value
    for :math:`t=1`. It also has no linear segment near zero and will thus be
    undefined for :math:`t=0` when computing its logarithm.

    Examples
    --------
    >>> log_encoding_FilmicPro6(0.18)  # doctest: +ELLIPSIS
    0.6066345...
    """

    t = to_domain_1(t)

    y = 0.371 * (np.sqrt(t) + 0.28257 * np.log(t) + 1.69542)

    return from_range_1(y)
Exemplo n.º 15
0
def eotf_reverse_DCDM(XYZ, out_int=False):
    """
    Defines the *DCDM* reverse electro-optical transfer function (EOTF / EOCF).

    Parameters
    ----------
    XYZ : numeric or array_like
        *CIE XYZ* tristimulus values.
    out_int : bool, optional
        Whether to return value as integer code value or float equivalent of a
        code value at a given bit depth.

    Returns
    -------
    numeric or ndarray
        Non-linear *CIE XYZ'* tristimulus values.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``XYZ``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``XYZ_p``      | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has an output integer switch, thus the domain-range
        scale information is only given for the floating point mode.

    References
    ----------
    :cite:`DigitalCinemaInitiatives2007b`

    Examples
    --------
    >>> eotf_reverse_DCDM(0.18)  # doctest: +ELLIPSIS
    0.1128186...
    >>> eotf_reverse_DCDM(0.18, out_int=True)
    462
    """

    XYZ = to_domain_1(XYZ)

    XYZ_p = spow(XYZ / 52.37, 1 / 2.6)

    if out_int:
        return np.round(4095 * XYZ_p).astype(DEFAULT_INT_DTYPE)
    else:
        return from_range_1(XYZ_p)
Exemplo n.º 16
0
def eotf_DCDM(XYZ_p, in_int=False):
    """
    Defines the *DCDM* electro-optical transfer function (EOTF / EOCF).

    Parameters
    ----------
    XYZ_p : numeric or array_like
        Non-linear *CIE XYZ'* tristimulus values.
    in_int : bool, optional
        Whether to treat the input value as integer code value or float
        equivalent of a code value at a given bit depth.

    Returns
    -------
    numeric or ndarray
        *CIE XYZ* tristimulus values.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``XYZ_p``      | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``XYZ``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has an input integer switch, thus the domain-range
        scale information is only given for the floating point mode.

    References
    ----------
    :cite:`DigitalCinemaInitiatives2007b`

    Examples
    --------
    >>> eotf_DCDM(0.11281860951766724)  # doctest: +ELLIPSIS
    0.18...
    >>> eotf_DCDM(462, in_int=True)  # doctest: +ELLIPSIS
    0.18...
    """

    XYZ_p = to_domain_1(XYZ_p)

    if in_int:
        XYZ_p = XYZ_p / 4095

    XYZ = 52.37 * spow(XYZ_p, 2.6)

    return from_range_1(XYZ)
Exemplo n.º 17
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def XYZ_to_IPT(XYZ):
    """
    Converts from *CIE XYZ* tristimulus values to *IPT* colourspace.

    Parameters
    ----------
    XYZ : array_like
        *CIE XYZ* tristimulus values.

    Returns
    -------
    ndarray
        *IPT* colourspace array.

    Notes
    -----

    +------------+-----------------------+-----------------+
    | **Domain** | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``XYZ``    | [0, 1]                | [0, 1]          |
    +------------+-----------------------+-----------------+

    +------------+-----------------------+-----------------+
    | **Range**  | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``IPT``    | ``I`` : [0, 1]        | ``I`` : [0, 1]  |
    |            |                       |                 |
    |            | ``P`` : [-1, 1]       | ``P`` : [-1, 1] |
    |            |                       |                 |
    |            | ``T`` : [-1, 1]       | ``T`` : [-1, 1] |
    +------------+-----------------------+-----------------+

    -   Input *CIE XYZ* tristimulus values needs to be adapted for
        *CIE Standard Illuminant D Series* *D65*.

    References
    ----------
    :cite:`Fairchild2013y`

    Examples
    --------
    >>> XYZ = np.array([0.20654008, 0.12197225, 0.05136952])
    >>> XYZ_to_IPT(XYZ)  # doctest: +ELLIPSIS
    array([ 0.3842619...,  0.3848730...,  0.1888683...])
    """

    XYZ = to_domain_1(XYZ)

    LMS = dot_vector(IPT_XYZ_TO_LMS_MATRIX, XYZ)
    LMS_prime = spow(LMS, 0.43)
    IPT = dot_vector(IPT_LMS_TO_IPT_MATRIX, LMS_prime)

    return from_range_1(IPT)
Exemplo n.º 18
0
    def test_to_domain_1(self):
        """
        Tests :func:`colour.utilities.common.to_domain_1` definition.
        """

        with domain_range_scale('Reference'):
            self.assertEqual(to_domain_1(1), 1)

        with domain_range_scale('1'):
            self.assertEqual(to_domain_1(1), 1)

        with domain_range_scale('100'):
            self.assertEqual(to_domain_1(1), 0.01)

        with domain_range_scale('100'):
            self.assertEqual(to_domain_1(1, np.pi), 1 / np.pi)

        with domain_range_scale('100'):
            self.assertEqual(
                to_domain_1(1, dtype=np.float16).dtype, np.float16)
Exemplo n.º 19
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def log_decoding_FilmicPro6(y):
    """
    Defines the *FiLMiC Pro 6* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    y : numeric or array_like
        Non-linear data :math:`y`.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`t`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``t``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    -   The *FiLMiC Pro 6* log decoding curve / electro-optical transfer
        function is only defined for domain (0, 1].

    References
    ----------
    :cite:`FiLMiCInc2017`

    Warnings
    --------
    The *FiLMiC Pro 6* log encoding curve / opto-electronic transfer function
    has no inverse in :math:`R`, we thus use a *LUT* based inversion.

    Examples
    --------
    >>> log_decoding_FilmicPro6(0.6066345199247033)  # doctest: +ELLIPSIS
    0.1800000...
    """

    y = to_domain_1(y)

    t = _log_decoding_FilmicPro6_interpolator()(y)

    return from_range_1(t)
Exemplo n.º 20
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def log_decoding_Log3G10(y, legacy_curve=False):
    """
    Defines the *Log3G10* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    y : numeric or array_like
        Non-linear data :math:`y`.
    legacy_curve : bool, optional
        Whether to use the v1 *Log3G10* log encoding curve. Default is *False*.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Nattress2016a`

    Examples
    --------
    >>> log_decoding_Log3G10(1.0 / 3, legacy_curve=True)  # doctest: +ELLIPSIS
    0.1799994...
    >>> log_decoding_Log3G10(1.0)  # doctest: +ELLIPSIS
    184.3223476...
    """

    y = to_domain_1(y)

    if legacy_curve:
        x = (np.sign(y) * (10.0 ** (np.abs(y) / 0.222497) - 1) / 169.379333)
    else:
        x = (np.sign(y) * (10.0 **
                           (np.abs(y) / 0.224282) - 1) / 155.975327) - 0.01

    return from_range_1(x)
Exemplo n.º 21
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def oetf_reverse_sRGB(V):
    """
    Defines the *sRGB* colourspace reverse opto-electronic transfer function
    (OETF / OECF).

    Parameters
    ----------
    V : numeric or array_like
        Electrical signal :math:`V`.

    Returns
    -------
    numeric or ndarray
        Corresponding *luminance* :math:`L` of the image.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`InternationalElectrotechnicalCommission1999a`,
    :cite:`InternationalTelecommunicationUnion2015i`

    Examples
    --------
    >>> oetf_reverse_sRGB(0.461356129500442)  # doctest: +ELLIPSIS
    0.1...
    """

    V = to_domain_1(V)

    with domain_range_scale('ignore'):
        L = np.where(
            V <= oetf_sRGB(0.0031308),
            V / 12.92,
            spow((V + 0.055) / 1.055, 2.4),
        )

    return as_float(from_range_1(L))
Exemplo n.º 22
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def IPT_to_XYZ(IPT):
    """
    Converts from *IPT* colourspace to *CIE XYZ* tristimulus values.

    Parameters
    ----------
    IPT : array_like
        *IPT* colourspace array.

    Returns
    -------
    ndarray
        *CIE XYZ* tristimulus values.

    Notes
    -----

    +------------+-----------------------+-----------------+
    | **Domain** | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``IPT``    | ``I`` : [0, 1]        | ``I`` : [0, 1]  |
    |            |                       |                 |
    |            | ``P`` : [-1, 1]       | ``P`` : [-1, 1] |
    |            |                       |                 |
    |            | ``T`` : [-1, 1]       | ``T`` : [-1, 1] |
    +------------+-----------------------+-----------------+

    +------------+-----------------------+-----------------+
    | **Range**  | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``XYZ``    | [0, 1]                | [0, 1]          |
    +------------+-----------------------+-----------------+

    References
    ----------
    :cite:`Fairchild2013y`

    Examples
    --------
    >>> IPT = np.array([0.38426191, 0.38487306, 0.18886838])
    >>> IPT_to_XYZ(IPT)  # doctest: +ELLIPSIS
    array([ 0.2065400...,  0.1219722...,  0.0513695...])
    """

    IPT = to_domain_1(IPT)

    LMS = dot_vector(IPT_IPT_TO_LMS_MATRIX, IPT)
    LMS_prime = spow(LMS, 1 / 0.43)
    XYZ = dot_vector(IPT_LMS_TO_XYZ_MATRIX, LMS_prime)

    return from_range_1(XYZ)
Exemplo n.º 23
0
def eotf_SMPTE240M(V_r):
    """
    Defines *SMPTE 240M* electro-optical transfer function (EOTF / EOCF).

    Parameters
    ----------
    V_r : numeric or array_like
        Video signal level :math:`V_r` driving the reference reproducer
        normalised to the system reference white.

    Returns
    -------
    numeric or ndarray
         Light output :math:`L_r` from the reference reproducer normalised to
         the system reference white.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_c``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_c``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SocietyofMotionPictureandTelevisionEngineers1999b`

    Examples
    --------
    >>> eotf_SMPTE240M(0.402285796753870)  # doctest: +ELLIPSIS
    0.1...
    """

    V_r = to_domain_1(V_r)

    with domain_range_scale('ignore'):
        L_r = np.where(
            V_r < oetf_SMPTE240M(0.0228),
            V_r / 4,
            spow((V_r + 0.1115) / 1.1115, 1 / 0.45),
        )

    return as_float(from_range_1(L_r))
Exemplo n.º 24
0
def xyY_to_XYZ(xyY):
    """
    Converts from *CIE xyY* colourspace to *CIE XYZ* tristimulus values.

    Parameters
    ----------
    xyY : array_like
        *CIE xyY* colourspace array.

    Returns
    -------
    ndarray
        *CIE XYZ* tristimulus values.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``xyY``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``XYZ``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Lindbloom2009d`, :cite:`Wikipedia2005`

    Examples
    --------
    >>> xyY = np.array([0.54369557, 0.32107944, 0.12197225])
    >>> xyY_to_XYZ(xyY)  # doctest: +ELLIPSIS
    array([ 0.2065400...,  0.1219722...,  0.0513695...])
    """

    x, y, Y = tsplit(xyY)
    Y = to_domain_1(Y)

    XYZ = np.where(
        (y == 0)[..., np.newaxis],
        tstack([y, y, y]),
        tstack([x * Y / y, Y, (1 - x - y) * Y / y]),
    )

    return from_range_1(XYZ)
Exemplo n.º 25
0
def IPT_hue_angle(IPT):
    """
    Computes the hue angle in degrees from *IPT* colourspace.

    Parameters
    ----------
    IPT : array_like
        *IPT* colourspace array.

    Returns
    -------
    numeric or ndarray
        Hue angle in degrees.

    Notes
    -----

    +------------+-----------------------+-----------------+
    | **Domain** | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``IPT``    | ``I`` : [0, 1]        | ``I`` : [0, 1]  |
    |            |                       |                 |
    |            | ``P`` : [-1, 1]       | ``P`` : [-1, 1] |
    |            |                       |                 |
    |            | ``T`` : [-1, 1]       | ``T`` : [-1, 1] |
    +------------+-----------------------+-----------------+

    +------------+-----------------------+-----------------+
    | **Range**  | **Scale - Reference** | **Scale - 1**   |
    +============+=======================+=================+
    | ``hue``    | [0, 360]              | [0, 1]          |
    +------------+-----------------------+-----------------+

    References
    ----------
    :cite:`Fairchild2013y`

    Examples
    --------
    >>> IPT = np.array([0.96907232, 1, 1.12179215])
    >>> IPT_hue_angle(IPT)  # doctest: +ELLIPSIS
    48.2852074...
    """

    _I, P, T = tsplit(to_domain_1(IPT))

    hue = np.degrees(np.arctan2(T, P)) % 360

    return from_range_degrees(hue)
Exemplo n.º 26
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def log_encoding_REDLog(x, black_offset=10 ** ((0 - 1023) / 511)):
    """
    Defines the *REDLog* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    black_offset : numeric or array_like
        Black offset.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`y`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SonyImageworks2012a`

    Examples
    --------
    >>> log_encoding_REDLog(0.18)  # doctest: +ELLIPSIS
    0.6376218...
    """

    x = to_domain_1(x)

    y = (1023 + 511 * np.log10(x * (1 - black_offset) + black_offset)) / 1023

    return from_range_1(y)
Exemplo n.º 27
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def log_decoding_Cineon(y, black_offset=10 ** ((95 - 685) / 300)):
    """
    Defines the *Cineon* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    y : numeric or array_like
        Non-linear data :math:`y`.
    black_offset : numeric or array_like
        Black offset.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SonyImageworks2012a`

    Examples
    --------
    >>> log_decoding_Cineon(0.457319613085418)  # doctest: +ELLIPSIS
    0.1799999...
    """

    y = to_domain_1(y)

    x = ((10 ** ((1023 * y - 685) / 300) - black_offset) / (1 - black_offset))

    return from_range_1(x)
Exemplo n.º 28
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def log_decoding_REDLog(y, black_offset=10 ** ((0 - 1023) / 511)):
    """
    Defines the *REDLog* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    y : numeric or array_like
        Non-linear data :math:`y`.
    black_offset : numeric or array_like
        Black offset.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SonyImageworks2012a`

    Examples
    --------
    >>> log_decoding_REDLog(0.637621845988175)  # doctest: +ELLIPSIS
    0.1...
    """

    y = to_domain_1(y)

    x = ((10 ** ((1023 * y - 1023) / 511)) - black_offset) / (1 - black_offset)

    return from_range_1(x)
Exemplo n.º 29
0
def oetf_sRGB(L):
    """
    Defines the *sRGB* colourspace opto-electronic transfer function
    (OETF / OECF).

    Parameters
    ----------
    L : numeric or array_like
        *Luminance* :math:`L` of the image.

    Returns
    -------
    numeric or ndarray
        Corresponding electrical signal :math:`V`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`InternationalElectrotechnicalCommission1999a`,
    :cite:`InternationalTelecommunicationUnion2015i`

    Examples
    --------
    >>> oetf_sRGB(0.18)  # doctest: +ELLIPSIS
    0.4613561...
    """

    L = to_domain_1(L)

    V = np.where(L <= 0.0031308, L * 12.92, 1.055 * spow(L, 1 / 2.4) - 0.055)

    return as_float(from_range_1(V))
Exemplo n.º 30
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def oetf_SMPTE240M(L_c):
    """
    Defines *SMPTE 240M* opto-electrical transfer function (OETF / OECF).

    Parameters
    ----------
    L_c : numeric or array_like
        Light input :math:`L_c` to the reference camera normalised to the
        system reference white.

    Returns
    -------
    numeric or ndarray
        Video signal output :math:`V_c` of the reference camera normalised to
        the system reference white.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_c``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_c``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`SocietyofMotionPictureandTelevisionEngineers1999b`

    Examples
    --------
    >>> oetf_SMPTE240M(0.18)  # doctest: +ELLIPSIS
    0.4022857...
    """

    L_c = to_domain_1(L_c)

    V_c = np.where(L_c < 0.0228, 4 * L_c, 1.1115 * spow(L_c, 0.45) - 0.1115)

    return as_float(from_range_1(V_c))
Exemplo n.º 31
0
def log_encoding_ERIMMRGB(X,
                          bit_depth=8,
                          out_int=False,
                          E_min=0.001,
                          E_clip=316.2):
    """
    Defines the *ERIMM RGB* log encoding curve / opto-electronic transfer
    function (OETF / OECF).

    Parameters
    ----------
    X : numeric or array_like
        Linear data :math:`X_{ERIMM}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_int : bool, optional
        Whether to return value as integer code value or float equivalent of a
        code value at a given bit depth.
    E_min : numeric, optional
        Minimum exposure limit.
    E_clip : numeric, optional
        Maximum exposure limit.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`X'_{ERIMM}`.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X``          | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X_p``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    \\* This definition has an output integer switch, thus the domain-range
    scale information is only given for the floating point mode.

    References
    ----------
    :cite:`Spaulding2000b`

    Examples
    --------
    >>> log_encoding_ERIMMRGB(0.18)  # doctest: +ELLIPSIS
    0.4100523...
    >>> log_encoding_ERIMMRGB(0.18, out_int=True)
    105
    """

    X = to_domain_1(X)

    I_max = 2**bit_depth - 1

    E_t = np.exp(1) * E_min

    X_p = np.select([
        X < 0.0,
        X <= E_t,
        X > E_t,
        X > E_clip,
    ], [
        0,
        I_max * ((np.log(E_t) - np.log(E_min)) /
                 (np.log(E_clip) - np.log(E_min))) * (X / E_t),
        I_max * ((np.log(X) - np.log(E_min)) /
                 (np.log(E_clip) - np.log(E_min))),
        I_max,
    ])

    if out_int:
        return as_int(np.round(X_p))
    else:
        return as_float(from_range_1(X_p / I_max))
Exemplo n.º 32
0
def exponent_hdr_CIELab(Y_s, Y_abs, method='Fairchild 2011'):
    """
    Computes *hdr-CIELAB* colourspace *Lightness* :math:`\\epsilon` exponent
    using *Fairchild and Wyble (2010)* or *Fairchild and Chen (2011)* method.

    Parameters
    ----------
    Y_s : numeric or array_like
        Relative luminance :math:`Y_s` of the surround.
    Y_abs : numeric or array_like
        Absolute luminance :math:`Y_{abs}` of the scene diffuse white in
        :math:`cd/m^2`.
    method : unicode, optional
        **{'Fairchild 2011', 'Fairchild 2010'}**,
        Computation method.

    Returns
    -------
    array_like
        *hdr-CIELAB* colourspace *Lightness* :math:`\\epsilon` exponent.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``Y_s``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    Examples
    --------
    >>> exponent_hdr_CIELab(0.2, 100)  # doctest: +ELLIPSIS
    0.4738510...
    >>> exponent_hdr_CIELab(0.2, 100, method='Fairchild 2010')
    ... # doctest: +ELLIPSIS
    1.8360198...
    """

    Y_s = to_domain_1(Y_s)
    Y_abs = as_float_array(Y_abs)

    method_l = method.lower()
    assert method.lower() in [
        m.lower() for m in HDR_CIELAB_METHODS
    ], ('"{0}" method is invalid, must be one of {1}!'.format(
        method, HDR_CIELAB_METHODS))

    if method_l == 'fairchild 2010':
        epsilon = 1.50
    else:
        epsilon = 0.58

    sf = 1.25 - 0.25 * (Y_s / 0.184)
    lf = np.log(318) / np.log(Y_abs)
    if method_l == 'fairchild 2010':
        epsilon *= sf * lf
    else:
        epsilon /= sf * lf

    return epsilon
Exemplo n.º 33
0
def log_encoding_VLog(L_in,
                      bit_depth=10,
                      out_normalised_code_value=True,
                      in_reflection=True,
                      constants=VLOG_CONSTANTS,
                      **kwargs):
    """
    Defines the *Panasonic V-Log* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    L_in : numeric or array_like
        Linear reflection data :math`L_{in}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_normalised_code_value : bool, optional
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded as normalised code values.
    in_reflection : bool, optional
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants : Structure, optional
        *Panasonic V-Log* constants.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`V_{out}`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_encoding_VLog(0.18)  # doctest: +ELLIPSIS
    0.4233114...

    The values of *Fig.2.2 V-Log Code Value* table in :cite:`Panasonic2014a`
    are obtained as follows:

    >>> L_in = np.array([0, 18, 90]) / 100
    >>> np.around(log_encoding_VLog(L_in, 10, False) * 100).astype(np.int)
    array([ 7, 42, 61])
    >>> np.around(log_encoding_VLog(L_in) * (2 ** 10 - 1)).astype(np.int)
    array([128, 433, 602])
    >>> np.around(log_encoding_VLog(L_in) * (2 ** 12 - 1)).astype(np.int)
    array([ 512, 1733, 2409])

    Note that some values in the last column values of
    *Fig.2.2 V-Log Code Value* table in :cite:`Panasonic2014a` are different
    by a code: [512, 1732, 2408].
    """

    out_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['out_legal', 'out_normalised_code_value']],
        }, **kwargs).get('out_normalised_code_value',
                         out_normalised_code_value)

    L_in = to_domain_1(L_in)

    if not in_reflection:
        L_in = L_in * 0.9

    cut1 = constants.cut1
    b = constants.b
    c = constants.c
    d = constants.d

    V_out = np.where(
        L_in < cut1,
        5.6 * L_in + 0.125,
        c * np.log10(L_in + b) + d,
    )

    V_out = (V_out if out_normalised_code_value else legal_to_full(
        V_out, bit_depth))

    return as_float(from_range_1(V_out))
Exemplo n.º 34
0
def log_encoding_FLog(in_r,
                      bit_depth=10,
                      out_normalised_code_value=True,
                      in_reflection=True,
                      constants=FLOG_CONSTANTS):
    """
    Defines the *Fujifilm F-Log* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    in_r : numeric or array_like
        Linear reflection data :math`in`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_normalised_code_value : bool, optional
        Whether the non-linear *Fujifilm F-Log* data :math:`out` is encoded as
        normalised code values.
    in_reflection : bool, optional
        Whether the light level :math`in` to a camera is reflection.
    constants : Structure, optional
        *Fujifilm F-Log* constants.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`out`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``in_r``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``out_r``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Fujifilm2016`

    Examples
    --------
    >>> log_encoding_FLog(0.18)  # doctest: +ELLIPSIS
    0.4593184...

    The values of *2-2. F-Log Code Value* table in :cite:`Fujifilm2016` are
    obtained as follows:

    >>> x = np.array([0, 18, 90]) / 100
    >>> np.around(log_encoding_FLog(x, 10, False) * 100, 1)
    array([  3.5,  46.3,  73.2])
    >>> np.around(log_encoding_FLog(x) * (2 ** 10 - 1)).astype(np.int)
    array([ 95, 470, 705])
    """

    in_r = to_domain_1(in_r)

    if not in_reflection:
        in_r = in_r * 0.9

    cut1 = constants.cut1
    a = constants.a
    b = constants.b
    c = constants.c
    d = constants.d
    e = constants.e
    f = constants.f

    out_r = np.where(
        in_r < cut1,
        e * in_r + f,
        c * np.log10(a * in_r + b) + d,
    )

    out_r = (out_r if out_normalised_code_value else legal_to_full(
        out_r, bit_depth))

    return as_float(from_range_1(out_r))
Exemplo n.º 35
0
def log_encoding_VLog(L_in,
                      bit_depth=10,
                      out_legal=True,
                      in_reflection=True,
                      constants=VLOG_CONSTANTS):
    """
    Defines the *Panasonic V-Log* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    L_in : numeric or array_like
        Linear reflection data :math`L_{in}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_legal : bool, optional
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded in legal range.
    in_reflection : bool, optional
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants : Structure, optional
        *Panasonic V-Log* constants.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`V_{out}`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_encoding_VLog(0.18)  # doctest: +ELLIPSIS
    0.4233114...
    """

    L_in = to_domain_1(L_in)

    if not in_reflection:
        L_in = L_in * 0.9

    cut1 = constants.cut1
    b = constants.b
    c = constants.c
    d = constants.d

    V_out = np.where(
        L_in < cut1,
        5.6 * L_in + 0.125,
        c * np.log10(L_in + b) + d,
    )

    V_out = V_out if out_legal else legal_to_full(V_out, bit_depth)

    return as_float(from_range_1(V_out))
Exemplo n.º 36
0
def YCbCr_to_RGB(YCbCr,
                 K=YCBCR_WEIGHTS['ITU-R BT.709'],
                 in_bits=8,
                 in_legal=True,
                 in_int=False,
                 out_bits=10,
                 out_legal=False,
                 out_int=False,
                 **kwargs):
    """
    Converts an array of *Y'CbCr* colour encoding values to the corresponding
    *R'G'B'* values array.

    Parameters
    ----------
    YCbCr : array_like
        Input *Y'CbCr* colour encoding array of integer or float values.
    K : array_like, optional
        Luma weighting coefficients of red and blue. See
        :attr:`colour.YCBCR_WEIGHTS` for presets. Default is
        *(0.2126, 0.0722)*, the weightings for *ITU-R BT.709*.
    in_bits : int, optional
        Bit depth for integer input, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Default is *10*.
    in_legal : bool, optional
        Whether to treat the input values as legal range. Default is *False*.
    in_int : bool, optional
        Whether to treat the input values as ``in_bits`` integer code values.
        Default is *False*.
    out_bits : int, optional
        Bit depth for integer output, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Ignored if ``out_legal`` and
        ``out_int`` are both *False*. Default is *8*.
    out_legal : bool, optional
        Whether to return legal range values. Default is *True*.
    out_int : bool, optional
        Whether to return values as ``out_bits`` integer code values. Default
        is *False*.

    Other Parameters
    ----------------
    in_range : array_like, optional
        Array overriding the computed range such as
        *in_range = (Y_min, Y_max, C_min, C_max)*. If ``in_range`` is
        undefined, *Y_min*, *Y_max*, *C_min* and *C_max* will be computed using
        :func:`colour.models.rgb.ycbcr.YCbCr_ranges` definition.
    out_range : array_like, optional
        Array overriding the computed range such as
        *out_range = (RGB_min, RGB_max)*. If ``out_range`` is undefined,
        *RGB_min* and *RGB_max* will be computed using :func:`colour.CV_range`
        definition.

    Returns
    -------
    ndarray
        *R'G'B'* array of integer or float values.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``YCbCr``      | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``RGB``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has input and output integer switches, thus the
        domain-range scale information is only given for the floating point
        mode.

    Warning
    -------
    For *Recommendation ITU-R BT.2020*, :func:`colour.YCbCr_to_RGB`
    definition is only applicable to the non-constant luminance implementation.
    :func:`colour.YcCbcCrc_to_RGB` definition should be used for the constant
    luminance case as per :cite:`InternationalTelecommunicationUnion2015h`.

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2011e`,
    :cite:`InternationalTelecommunicationUnion2015i`,
    :cite:`SocietyofMotionPictureandTelevisionEngineers1999b`,
    :cite:`Wikipedia2004d`

    Examples
    --------
    >>> YCbCr = np.array([502, 512, 512])
    >>> YCbCr_to_RGB(YCbCr, in_bits=10, in_legal=True, in_int=True)
    array([ 0.5,  0.5,  0.5])
    """

    if in_int:
        YCbCr = as_float_array(YCbCr)
    else:
        YCbCr = to_domain_1(YCbCr)

    Y, Cb, Cr = tsplit(YCbCr.astype(DEFAULT_FLOAT_DTYPE))
    Kr, Kb = K
    Y_min, Y_max, C_min, C_max = kwargs.get(
        'in_range', YCbCr_ranges(in_bits, in_legal, in_int))
    RGB_min, RGB_max = kwargs.get('out_range',
                                  CV_range(out_bits, out_legal, out_int))

    Y -= Y_min
    Cb -= (C_max + C_min) / 2
    Cr -= (C_max + C_min) / 2
    Y *= 1 / (Y_max - Y_min)
    Cb *= 1 / (C_max - C_min)
    Cr *= 1 / (C_max - C_min)
    R = Y + (2 - 2 * Kr) * Cr
    B = Y + (2 - 2 * Kb) * Cb
    G = (Y - Kr * R - Kb * B) / (1 - Kr - Kb)

    RGB = tstack([R, G, B])
    RGB *= RGB_max - RGB_min
    RGB += RGB_min
    RGB = np.round(RGB).astype(DEFAULT_INT_DTYPE) if out_int else from_range_1(
        RGB)

    return RGB
Exemplo n.º 37
0
def RGB_to_YCbCr(RGB,
                 K=YCBCR_WEIGHTS['ITU-R BT.709'],
                 in_bits=10,
                 in_legal=False,
                 in_int=False,
                 out_bits=8,
                 out_legal=True,
                 out_int=False,
                 **kwargs):
    """
    Converts an array of *R'G'B'* values to the corresponding *Y'CbCr* colour
    encoding values array.

    Parameters
    ----------
    RGB : array_like
        Input *R'G'B'* array of floats or integer values.
    K : array_like, optional
        Luma weighting coefficients of red and blue. See
        :attr:`colour.YCBCR_WEIGHTS` for presets. Default is
        *(0.2126, 0.0722)*, the weightings for *ITU-R BT.709*.
    in_bits : int, optional
        Bit depth for integer input, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Default is *10*.
    in_legal : bool, optional
        Whether to treat the input values as legal range. Default is *False*.
    in_int : bool, optional
        Whether to treat the input values as ``in_bits`` integer code values.
        Default is *False*.
    out_bits : int, optional
        Bit depth for integer output, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Ignored if ``out_legal`` and
        ``out_int`` are both *False*. Default is *8*.
    out_legal : bool, optional
        Whether to return legal range values. Default is *True*.
    out_int : bool, optional
        Whether to return values as ``out_bits`` integer code values. Default
        is *False*.

    Other Parameters
    ----------------
    in_range : array_like, optional
        Array overriding the computed range such as
        *in_range = (RGB_min, RGB_max)*. If ``in_range`` is undefined,
        *RGB_min* and *RGB_max* will be computed using :func:`colour.CV_range`
        definition.
    out_range : array_like, optional
        Array overriding the computed range such as
        *out_range = (Y_min, Y_max, C_min, C_max)`. If ``out_range`` is
        undefined, *Y_min*, *Y_max*, *C_min* and *C_max* will be computed
        using :func:`colour.models.rgb.ycbcr.YCbCr_ranges` definition.

    Returns
    -------
    ndarray
        *Y'CbCr* colour encoding array of integer or float values.

    Warning
    -------
    For *Recommendation ITU-R BT.2020*, :func:`colour.RGB_to_YCbCr` definition
    is only applicable to the non-constant luminance implementation.
    :func:`colour.RGB_to_YcCbcCrc` definition should be used for the constant
    luminance case as per :cite:`InternationalTelecommunicationUnion2015h`.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``RGB``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``YCbCr``      | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has input and output integer switches, thus the
        domain-range scale information is only given for the floating point
        mode.
    -   The default arguments, ``**{'in_bits': 10, 'in_legal': False,
        'in_int': False, 'out_bits': 8, 'out_legal': True, 'out_int': False}``
        transform a float *R'G'B'* input array normalised to domain [0, 1]
        (``in_bits`` is ignored) to a float *Y'CbCr* output array where *Y'* is
        normalised to range [16 / 255, 235 / 255] and *Cb* and *Cr* are
        normalised to range [16 / 255, 240./255]. The float values are
        calculated based on an [0, 255] integer range, but no 8-bit
        quantisation or clamping are performed.

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2011e`,
    :cite:`InternationalTelecommunicationUnion2015i`,
    :cite:`SocietyofMotionPictureandTelevisionEngineers1999b`,
    :cite:`Wikipedia2004d`

    Examples
    --------
    >>> RGB = np.array([1.0, 1.0, 1.0])
    >>> RGB_to_YCbCr(RGB)  # doctest: +ELLIPSIS
    array([ 0.9215686...,  0.5019607...,  0.5019607...])

    Matching float output of The Foundry Nuke's Colorspace node set to YCbCr:

    >>> RGB_to_YCbCr(RGB,
    ...              out_range=(16 / 255, 235 / 255, 15.5 / 255, 239.5 / 255))
    ... # doctest: +ELLIPSIS
    array([ 0.9215686...,  0.5       ,  0.5       ])

    Matching float output of The Foundry Nuke's Colorspace node set to YPbPr:

    >>> RGB_to_YCbCr(RGB, out_legal=False, out_int=False)
    ... # doctest: +ELLIPSIS
    array([ 1.,  0.,  0.])

    Creating integer code values as per standard 10-bit SDI:

    >>> RGB_to_YCbCr(RGB, out_legal=True, out_bits=10, out_int=True)
    array([940, 512, 512])

    For JFIF JPEG conversion as per ITU-T T.871
    :cite:`InternationalTelecommunicationUnion2011e`:

    >>> RGB = np.array([102, 0, 51])
    >>> RGB_to_YCbCr(RGB, K=YCBCR_WEIGHTS['ITU-R BT.601'], in_range=(0, 255),
    ...              out_range=(0, 255, 0, 256), out_int=True)
    array([ 36, 136, 175])

    Note the use of 256 for the max *Cb / Cr* value, which is required so that
    the *Cb* and *Cr* output is centered about 128. Using 255 centres it
    about 127.5, meaning that there is no integer code value to represent
    achromatic colours. This does however create the possibility of output
    integer codes with value of 256, which cannot be stored in 8-bit integer
    representation. Recommendation ITU-T T.871 specifies these should be
    clamped to 255.

    These JFIF JPEG ranges are also obtained as follows:

    >>> RGB_to_YCbCr(RGB, K=YCBCR_WEIGHTS['ITU-R BT.601'], in_bits=8,
    ...              in_int=True, out_legal=False, out_int=True)
    array([ 36, 136, 175])
    """

    if in_int:
        RGB = as_float_array(RGB)
    else:
        RGB = to_domain_1(RGB)

    Kr, Kb = K
    RGB_min, RGB_max = kwargs.get('in_range',
                                  CV_range(in_bits, in_legal, in_int))
    Y_min, Y_max, C_min, C_max = kwargs.get(
        'out_range', YCbCr_ranges(out_bits, out_legal, out_int))

    RGB_float = RGB.astype(DEFAULT_FLOAT_DTYPE) - RGB_min
    RGB_float *= 1 / (RGB_max - RGB_min)
    R, G, B = tsplit(RGB_float)

    Y = Kr * R + (1 - Kr - Kb) * G + Kb * B
    Cb = 0.5 * (B - Y) / (1 - Kb)
    Cr = 0.5 * (R - Y) / (1 - Kr)
    Y *= Y_max - Y_min
    Y += Y_min
    Cb *= C_max - C_min
    Cr *= C_max - C_min
    Cb += (C_max + C_min) / 2
    Cr += (C_max + C_min) / 2

    YCbCr = tstack([Y, Cb, Cr])
    YCbCr = np.round(YCbCr).astype(
        DEFAULT_INT_DTYPE) if out_int else from_range_1(YCbCr)

    return YCbCr
Exemplo n.º 38
0
def log_encoding_CanonLog(x,
                          bit_depth=10,
                          out_normalised_code_value=True,
                          in_reflection=True,
                          **kwargs):
    """
    Defines the *Canon Log* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_normalised_code_value : bool, optional
        Whether the *Canon Log* non-linear data is encoded as normalised code
        values.
    in_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        *Canon Log* non-linear data.

    References
    ----------
    :cite:`Thorpe2012a`

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    Examples
    --------
    >>> log_encoding_CanonLog(0.18) * 100  # doctest: +ELLIPSIS
    34.3389651...

    The values of *Table 2 Canon-Log Code Values* table in :cite:`Thorpe2012a`
    are obtained as follows:

    >>> x = np.array([0, 2, 18, 90, 720]) / 100
    >>> np.around(log_encoding_CanonLog(x) * (2 ** 10 - 1)).astype(np.int)
    array([ 128,  169,  351,  614, 1016])
    >>> np.around(log_encoding_CanonLog(x, 10, False) * 100, 1)
    array([   7.3,   12. ,   32.8,   62.7,  108.7])
    """

    out_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['out_legal', 'out_normalised_code_value']],
        }, **kwargs).get('out_normalised_code_value',
                         out_normalised_code_value)

    x = to_domain_1(x)

    if in_reflection:
        x = x / 0.9

    with domain_range_scale('ignore'):
        clog = np.where(
            x < log_decoding_CanonLog(0.0730597, bit_depth, False),
            -(0.529136 * (np.log10(-x * 10.1596 + 1)) - 0.0730597),
            0.529136 * np.log10(10.1596 * x + 1) + 0.0730597,
        )

    clog = (full_to_legal(clog, bit_depth)
            if out_normalised_code_value else clog)

    return as_float(from_range_1(clog))
Exemplo n.º 39
0
def log_decoding_CanonLog3(clog3,
                           bit_depth=10,
                           in_normalised_code_value=True,
                           out_reflection=True,
                           **kwargs):
    """
    Defines the *Canon Log 3* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    clog3 : numeric or array_like
        *Canon Log 3* non-linear data.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_normalised_code_value : bool, optional
        Whether the *Canon Log 3* non-linear data is encoded with normalised
        code values.
    out_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog3``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Canona`

    Examples
    --------
    >>> log_decoding_CanonLog3(34.338936938868677 / 100)  # doctest: +ELLIPSIS
    0.1800000...
    """

    in_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['in_legal', 'in_normalised_code_value']],
        }, **kwargs).get('in_normalised_code_value', in_normalised_code_value)

    clog3 = to_domain_1(clog3)

    clog3 = (legal_to_full(clog3, bit_depth)
             if in_normalised_code_value else clog3)

    x = np.select(
        (clog3 < 0.04076162, clog3 <= 0.105357102, clog3 > 0.105357102),
        (-(10**((0.07623209 - clog3) / 0.42889912) - 1) / 14.98325,
         (clog3 - 0.073059361) / 2.3069815,
         (10**((clog3 - 0.069886632) / 0.42889912) - 1) / 14.98325))

    if out_reflection:
        x = x * 0.9

    return as_float(from_range_1(x))
Exemplo n.º 40
0
def log_decoding_VLog(
    V_out: FloatingOrArrayLike,
    bit_depth: Integer = 10,
    in_normalised_code_value: Boolean = True,
    out_reflection: Boolean = True,
    constants: Structure = CONSTANTS_VLOG,
) -> FloatingOrNDArray:
    """
    Define the *Panasonic V-Log* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    V_out
        Non-linear data :math:`V_{out}`.
    bit_depth
        Bit depth used for conversion.
    in_normalised_code_value
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded as normalised code values.
    out_reflection
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants
        *Panasonic V-Log* constants.

    Returns
    -------
    :class:`numpy.floating` or :class:`numpy.ndarray`
        Linear reflection data :math`L_{in}`.

    Notes
    -----
    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_decoding_VLog(0.423311448760136)  # doctest: +ELLIPSIS
    0.1799999...
    """

    V_out = to_domain_1(V_out)

    V_out = (V_out if in_normalised_code_value else full_to_legal(
        V_out, bit_depth))

    cut2 = constants.cut2
    b = constants.b
    c = constants.c
    d = constants.d

    L_in = np.where(
        V_out < cut2,
        (V_out - 0.125) / 5.6,
        10**((V_out - d) / c) - b,
    )

    if not out_reflection:
        L_in = L_in / 0.9

    return as_float(from_range_1(L_in))
Exemplo n.º 41
0
def log_decoding_CanonLog2(clog2,
                           bit_depth=10,
                           in_normalised_code_value=True,
                           out_reflection=True,
                           **kwargs):
    """
    Defines the *Canon Log 2* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    clog2 : numeric or array_like
        *Canon Log 2* non-linear data.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_normalised_code_value : bool, optional
        Whether the *Canon Log 2* non-linear data is encoded with normalised
        code values.
    out_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog2``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Canona`

    Examples
    --------
    >>> log_decoding_CanonLog2(39.825469498316735 / 100)  # doctest: +ELLIPSIS
    0.1799999...
    """

    in_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['in_legal', 'in_normalised_code_value']],
        }, **kwargs).get('in_normalised_code_value', in_normalised_code_value)

    clog2 = to_domain_1(clog2)

    clog2 = (legal_to_full(clog2, bit_depth)
             if in_normalised_code_value else clog2)

    x = np.where(
        clog2 < 0.035388128,
        -(10**((0.035388128 - clog2) / 0.281863093) - 1) / 87.09937546,
        (10**((clog2 - 0.035388128) / 0.281863093) - 1) / 87.09937546,
    )

    if out_reflection:
        x = x * 0.9

    return as_float(from_range_1(x))
Exemplo n.º 42
0
def log_encoding_CanonLog2(x,
                           bit_depth=10,
                           out_normalised_code_value=True,
                           in_reflection=True,
                           **kwargs):
    """
    Defines the *Canon Log 2* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_normalised_code_value : bool, optional
        Whether the *Canon Log 2* non-linear data is encoded as normalised
        code values.
    in_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        *Canon Log 2* non-linear data.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog2``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Canona`

    Examples
    --------
    >>> log_encoding_CanonLog2(0.18) * 100  # doctest: +ELLIPSIS
    39.8254694...
    """

    out_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['out_legal', 'out_normalised_code_value']],
        }, **kwargs).get('out_normalised_code_value',
                         out_normalised_code_value)

    x = to_domain_1(x)

    if in_reflection:
        x = x / 0.9

    with domain_range_scale('ignore'):
        clog2 = np.where(
            x < log_decoding_CanonLog2(0.035388128, bit_depth, False),
            -(0.281863093 * (np.log10(-x * 87.09937546 + 1)) - 0.035388128),
            0.281863093 * np.log10(x * 87.09937546 + 1) + 0.035388128,
        )

    clog2 = (full_to_legal(clog2, bit_depth)
             if out_normalised_code_value else clog2)

    return as_float(from_range_1(clog2))
Exemplo n.º 43
0
def log_decoding_CanonLog(clog,
                          bit_depth=10,
                          in_normalised_code_value=True,
                          out_reflection=True,
                          **kwargs):
    """
    Defines the *Canon Log* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    clog : numeric or array_like
        *Canon Log* non-linear data.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_normalised_code_value : bool, optional
        Whether the *Canon Log* non-linear data is encoded with normalised
        code values.
    out_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`x`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Thorpe2012a`

    Examples
    --------
    >>> log_decoding_CanonLog(34.338965172606912 / 100)  # doctest: +ELLIPSIS
    0.17999999...
    """

    in_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['in_legal', 'in_normalised_code_value']],
        }, **kwargs).get('in_normalised_code_value', in_normalised_code_value)

    clog = to_domain_1(clog)

    clog = (legal_to_full(clog, bit_depth)
            if in_normalised_code_value else clog)

    x = np.where(
        clog < 0.0730597,
        -(10**((0.0730597 - clog) / 0.529136) - 1) / 10.1596,
        (10**((clog - 0.0730597) / 0.529136) - 1) / 10.1596,
    )

    if out_reflection:
        x = x * 0.9

    return as_float(from_range_1(x))
Exemplo n.º 44
0
def RGB_to_YcCbcCrc(RGB,
                    out_bits=10,
                    out_legal=True,
                    out_int=False,
                    is_12_bits_system=False,
                    **kwargs):
    """
    Converts an array of *RGB* linear values to the corresponding *Yc'Cbc'Crc'*
    colour encoding values array.

    Parameters
    ----------
    RGB : array_like
        Input *RGB* array of linear float values.
    out_bits : int, optional
        Bit depth for integer output, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Ignored if ``out_legal`` and
        ``out_int`` are both *False*. Default is *10*.
    out_legal : bool, optional
        Whether to return legal range values. Default is *True*.
    out_int : bool, optional
        Whether to return values as ``out_bits`` integer code values. Default
        is *False*.
    is_12_bits_system : bool, optional
        *Recommendation ITU-R BT.2020* OETF (OECF) adopts different parameters
        for 10 and 12 bit systems. Default is *False*.

    Other Parameters
    ----------------
    out_range : array_like, optional
        Array overriding the computed range such as
        *out_range = (Y_min, Y_max, C_min, C_max)*. If ``out_range`` is
        undefined, *Y_min*, *Y_max*, *C_min* and *C_max* will be computed
        using :func:`colour.models.rgb.ycbcr.YCbCr_ranges` definition.

    Returns
    -------
    ndarray
        *Yc'Cbc'Crc'* colour encoding array of integer or float values.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``RGB``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``YcCbcCrc``   | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has input and output integer switches, thus the
        domain-range scale information is only given for the floating point
        mode.

    Warning
    -------
    This definition is specifically for usage with
    *Recommendation ITU-R BT.2020* when adopting the constant luminance
    implementation.

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2015h`, :cite:`Wikipedia2004d`

    Examples
    --------
    >>> RGB = np.array([0.18, 0.18, 0.18])
    >>> RGB_to_YcCbcCrc(RGB, out_legal=True, out_bits=10, out_int=True,
    ...                 is_12_bits_system=False)
    array([422, 512, 512])
    """

    R, G, B = tsplit(to_domain_1(RGB))
    Y_min, Y_max, C_min, C_max = kwargs.get(
        'out_range', YCbCr_ranges(out_bits, out_legal, out_int))

    Yc = 0.2627 * R + 0.6780 * G + 0.0593 * B

    with domain_range_scale('ignore'):
        Yc = oetf_BT2020(Yc, is_12_bits_system=is_12_bits_system)
        R = oetf_BT2020(R, is_12_bits_system=is_12_bits_system)
        B = oetf_BT2020(B, is_12_bits_system=is_12_bits_system)

    Cbc = np.where((B - Yc) <= 0, (B - Yc) / 1.9404, (B - Yc) / 1.5816)
    Crc = np.where((R - Yc) <= 0, (R - Yc) / 1.7184, (R - Yc) / 0.9936)
    Yc *= Y_max - Y_min
    Yc += Y_min
    Cbc *= C_max - C_min
    Crc *= C_max - C_min
    Cbc += (C_max + C_min) / 2
    Crc += (C_max + C_min) / 2

    YcCbcCrc = tstack([Yc, Cbc, Crc])
    YcCbcCrc = (np.round(YcCbcCrc).astype(DEFAULT_INT_DTYPE)
                if out_int else from_range_1(YcCbcCrc))

    return YcCbcCrc
Exemplo n.º 45
0
def XYZ_to_hdr_CIELab(
        XYZ,
        illuminant=ILLUMINANTS['CIE 1931 2 Degree Standard Observer']['D65'],
        Y_s=0.2,
        Y_abs=100,
        method='Fairchild 2011'):
    """
    Converts from *CIE XYZ* tristimulus values to *hdr-CIELAB* colourspace.

    Parameters
    ----------
    XYZ : array_like
        *CIE XYZ* tristimulus values.
    illuminant : array_like, optional
        Reference *illuminant* *xy* chromaticity coordinates or *CIE xyY*
        colourspace array.
    Y_s : numeric or array_like
        Relative luminance :math:`Y_s` of the surround.
    Y_abs : numeric or array_like
        Absolute luminance :math:`Y_{abs}` of the scene diffuse white in
        :math:`cd/m^2`.
    method : unicode, optional
        **{'Fairchild 2011', 'Fairchild 2010'}**,
        Computation method.

    Returns
    -------
    ndarray
        *hdr-CIELAB* colourspace array.

    Notes
    -----

    +----------------+-------------------------+---------------------+
    | **Domain**     | **Scale - Reference**   | **Scale - 1**       |
    +================+=========================+=====================+
    | ``XYZ``        | [0, 1]                  | [0, 1]              |
    +----------------+-------------------------+---------------------+
    | ``illuminant`` | [0, 1]                  | [0, 1]              |
    +----------------+-------------------------+---------------------+
    | ``Y_s``        | [0, 1]                  | [0, 1]              |
    +----------------+-------------------------+---------------------+

    +----------------+-------------------------+---------------------+
    | **Range**      | **Scale - Reference**   | **Scale - 1**       |
    +================+=========================+=====================+
    | ``Lab_hdr``    | ``L_hdr`` : [0, 100]    | ``L_hdr`` : [0, 1]  |
    |                |                         |                     |
    |                | ``a_hdr`` : [-100, 100] | ``a_hdr`` : [-1, 1] |
    |                |                         |                     |
    |                | ``b_hdr`` : [-100, 100] | ``b_hdr`` : [-1, 1] |
    +----------------+-------------------------+---------------------+

    -   Conversion to polar coordinates to compute the *chroma* :math:`C_{hdr}`
        and *hue* :math:`h_{hdr}` correlates can be safely performed with
        :func:`colour.Lab_to_LCHab` definition.
    -   Conversion to cartesian coordinates from the *Lightness*
        :math:`L_{hdr}`, *chroma* :math:`C_{hdr}` and *hue* :math:`h_{hdr}`
        correlates can be safely performed with :func:`colour.LCHab_to_Lab`
        definition.

    References
    ----------
    :cite:`Fairchild2010`, :cite:`Fairchild2011`

    Examples
    --------
    >>> XYZ = np.array([0.20654008, 0.12197225, 0.05136952])
    >>> XYZ_to_hdr_CIELab(XYZ)  # doctest: +ELLIPSIS
    array([ 51.8700206...,  60.4763385...,  32.1455191...])
    >>> XYZ_to_hdr_CIELab(XYZ, method='Fairchild 2010')  # doctest: +ELLIPSIS
    array([  31.9962111...,  128.0076303...,   48.7695230...])
    """

    X, Y, Z = tsplit(to_domain_1(XYZ))

    X_n, Y_n, Z_n = tsplit(xyY_to_XYZ(xy_to_xyY(illuminant)))

    method_l = method.lower()
    assert method.lower() in [
        m.lower() for m in HDR_CIELAB_METHODS
    ], ('"{0}" method is invalid, must be one of {1}!'.format(
        method, HDR_CIELAB_METHODS))

    if method_l == 'fairchild 2010':
        lightness_callable = lightness_Fairchild2010
    else:
        lightness_callable = lightness_Fairchild2011

    e = exponent_hdr_CIELab(Y_s, Y_abs, method)

    # Domain and range scaling has already be handled.
    with domain_range_scale('ignore'):
        L_hdr = lightness_callable(Y / Y_n, e)
        a_hdr = 5 * (lightness_callable(X / X_n, e) - L_hdr)
        b_hdr = 2 * (L_hdr - lightness_callable(Z / Z_n, e))

    Lab_hdr = tstack([L_hdr, a_hdr, b_hdr])

    return from_range_100(Lab_hdr)
Exemplo n.º 46
0
def YcCbcCrc_to_RGB(YcCbcCrc,
                    in_bits=10,
                    in_legal=True,
                    in_int=False,
                    is_12_bits_system=False,
                    **kwargs):
    """
    Converts an array of *Yc'Cbc'Crc'* colour encoding values to the
    corresponding *RGB* array of linear values.

    Parameters
    ----------
    YcCbcCrc : array_like
        Input *Yc'Cbc'Crc'* colour encoding array of linear float values.
    in_bits : int, optional
        Bit depth for integer input, or used in the calculation of the
        denominator for legal range float values, i.e. 8-bit means the float
        value for legal white is *235 / 255*. Default is *10*.
    in_legal : bool, optional
        Whether to treat the input values as legal range. Default is *False*.
    in_int : bool, optional
        Whether to treat the input values as ``in_bits`` integer code values.
        Default is *False*.
    is_12_bits_system : bool, optional
        *Recommendation ITU-R BT.2020* EOTF (EOCF) adopts different parameters
        for 10 and 12 bit systems. Default is *False*.

    Other Parameters
    ----------------
    in_range : array_like, optional
        Array overriding the computed range such as
        *in_range = (Y_min, Y_max, C_min, C_max)*. If ``in_range`` is
        undefined, *Y_min*, *Y_max*, *C_min* and *C_max* will be computed using
        :func:`colour.models.rgb.ycbcr.YCbCr_ranges` definition.

    Returns
    -------
    ndarray
        *RGB* array of linear float values.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``YcCbcCrc``   | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``RGB``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    -   \\* This definition has input and output integer switches, thus the
        domain-range scale information is only given for the floating point
        mode.

    Warning
    -------
    This definition is specifically for usage with
    *Recommendation ITU-R BT.2020* when adopting the constant luminance
    implementation.

    References
    ----------
    :cite:`InternationalTelecommunicationUnion2015h`,
    :cite:`Wikipedia2004d`

    Examples
    --------
    >>> YcCbcCrc = np.array([1689, 2048, 2048])
    >>> YcCbcCrc_to_RGB(YcCbcCrc, in_legal=True, in_bits=12, in_int=True,
    ...                 is_12_bits_system=True)
    ... # doctest: +ELLIPSIS
    array([ 0.1800903...,  0.1800903...,  0.1800903...])
    """

    if in_int:
        YcCbcCrc = as_float_array(YcCbcCrc)
    else:
        YcCbcCrc = to_domain_1(YcCbcCrc)

    Yc, Cbc, Crc = tsplit(YcCbcCrc.astype(DEFAULT_FLOAT_DTYPE))
    Y_min, Y_max, C_min, C_max = kwargs.get(
        'in_range', YCbCr_ranges(in_bits, in_legal, in_int))

    Yc -= Y_min
    Cbc -= (C_max + C_min) / 2
    Crc -= (C_max + C_min) / 2
    Yc *= 1 / (Y_max - Y_min)
    Cbc *= 1 / (C_max - C_min)
    Crc *= 1 / (C_max - C_min)
    B = np.where(Cbc <= 0, Cbc * 1.9404 + Yc, Cbc * 1.5816 + Yc)
    R = np.where(Crc <= 0, Crc * 1.7184 + Yc, Crc * 0.9936 + Yc)

    with domain_range_scale('ignore'):
        Yc = eotf_BT2020(Yc, is_12_bits_system=is_12_bits_system)
        B = eotf_BT2020(B, is_12_bits_system=is_12_bits_system)
        R = eotf_BT2020(R, is_12_bits_system=is_12_bits_system)

    G = (Yc - 0.0593 * B - 0.2627 * R) / 0.6780

    RGB = tstack([R, G, B])

    return from_range_1(RGB)
Exemplo n.º 47
0
def log_decoding_FLog(out_r,
                      bit_depth=10,
                      in_normalised_code_value=True,
                      out_reflection=True,
                      constants=FLOG_CONSTANTS):
    """
    Defines the *Fujifilm F-Log* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    out_r : numeric or array_like
        Non-linear data :math:`out`.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_normalised_code_value : bool, optional
        Whether the non-linear *Fujifilm F-Log* data :math:`out` is encoded as
        normalised code values.
    out_reflection : bool, optional
        Whether the light level :math`in` to a camera is reflection.
    constants : Structure, optional
        *Fujifilm F-Log* constants.

    Returns
    -------
    numeric or ndarray
        Linear reflection data :math`in`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``out_r``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``in_r``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Fujifilm2016`

    Examples
    --------
    >>> log_decoding_FLog(0.45931845866162124)  # doctest: +ELLIPSIS
    0.1800000...
    """

    out_r = to_domain_1(out_r)

    out_r = (out_r if in_normalised_code_value else full_to_legal(
        out_r, bit_depth))

    cut2 = constants.cut2
    a = constants.a
    b = constants.b
    c = constants.c
    d = constants.d
    e = constants.e
    f = constants.f

    in_r = np.where(
        out_r < cut2,
        (out_r - f) / e,
        (10**((out_r - d) / c)) / a - b / a,
    )

    if not out_reflection:
        in_r = in_r / 0.9

    return as_float(from_range_1(in_r))
Exemplo n.º 48
0
def oetf_inverse_ARIBSTDB67(
    E_p: FloatingOrArrayLike,
    r: FloatingOrArrayLike = 0.5,
    constants: Structure = CONSTANTS_ARIBSTDB67,
) -> FloatingOrNDArray:
    """
    Define *ARIB STD-B67 (Hybrid Log-Gamma)* inverse opto-electrical transfer
    function (OETF).

    Parameters
    ----------
    E_p
        Non-linear signal :math:`E'`.
    r
        Video level corresponding to reference white level.
    constants
        *ARIB STD-B67 (Hybrid Log-Gamma)* constants.

    Returns
    -------
    :class:`numpy.floating` or :class:`numpy.ndarray`
        Voltage :math:`E` normalised by the reference white level and
        proportional to the implicit light intensity that would be detected
        with a reference camera color channel R, G, B.

    Notes
    -----
    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E_p``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    -   This definition uses the *mirror* negative number handling mode of
        :func:`colour.models.gamma_function` definition to the sign of negative
        numbers.

    References
    ----------
    :cite:`AssociationofRadioIndustriesandBusinesses2015a`

    Examples
    --------
    >>> oetf_inverse_ARIBSTDB67(0.212132034355964)  # doctest: +ELLIPSIS
    0.1799999...
    """

    E_p = to_domain_1(E_p)

    a = constants.a
    b = constants.b
    c = constants.c

    with domain_range_scale("ignore"):
        E = np.where(
            E_p <= oetf_ARIBSTDB67(1),
            gamma_function((E_p / r), 2, "mirror"),
            np.exp((E_p - c) / a) + b,
        )

    return as_float(from_range_1(E))
Exemplo n.º 49
0
def log_decoding_VLog(V_out,
                      bit_depth=10,
                      in_normalised_code_value=True,
                      out_reflection=True,
                      constants=VLOG_CONSTANTS,
                      **kwargs):
    """
    Defines the *Panasonic V-Log* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    V_out : numeric or array_like
        Non-linear data :math:`V_{out}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_normalised_code_value : bool, optional
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded as normalised code values.
    out_reflection : bool, optional
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants : Structure, optional
        *Panasonic V-Log* constants.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        Linear reflection data :math`L_{in}`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_decoding_VLog(0.423311448760136)  # doctest: +ELLIPSIS
    0.1799999...
    """

    in_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['in_legal', 'in_normalised_code_value']],
        }, **kwargs).get('in_normalised_code_value', in_normalised_code_value)

    V_out = to_domain_1(V_out)

    V_out = (V_out if in_normalised_code_value else full_to_legal(
        V_out, bit_depth))

    cut2 = constants.cut2
    b = constants.b
    c = constants.c
    d = constants.d

    L_in = np.where(
        V_out < cut2,
        (V_out - 0.125) / 5.6,
        10**((V_out - d) / c) - b,
    )

    if not out_reflection:
        L_in = L_in / 0.9

    return as_float(from_range_1(L_in))
Exemplo n.º 50
0
def oetf_ARIBSTDB67(
    E: FloatingOrArrayLike,
    r: FloatingOrArrayLike = 0.5,
    constants: Structure = CONSTANTS_ARIBSTDB67,
) -> FloatingOrNDArray:
    """
    Define *ARIB STD-B67 (Hybrid Log-Gamma)* opto-electrical transfer
    function (OETF).

    Parameters
    ----------
    E
        Voltage normalised by the reference white level and proportional to
        the implicit light intensity that would be detected with a reference
        camera color channel R, G, B.
    r
        Video level corresponding to reference white level.
    constants
        *ARIB STD-B67 (Hybrid Log-Gamma)* constants.

    Returns
    -------
    :class:`numpy.floating` or :class:`numpy.ndarray`
        Resulting non-linear signal :math:`E'`.

    Notes
    -----
    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``E_p``    | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    -   This definition uses the *mirror* negative number handling mode of
        :func:`colour.models.gamma_function` definition to the sign of negative
        numbers.

    References
    ----------
    :cite:`AssociationofRadioIndustriesandBusinesses2015a`

    Examples
    --------
    >>> oetf_ARIBSTDB67(0.18)  # doctest: +ELLIPSIS
    0.2121320...
    """

    E = to_domain_1(E)
    r = as_float_array(r)

    a = constants.a
    b = constants.b
    c = constants.c

    E_p = np.where(E <= 1, r * gamma_function(E, 0.5, "mirror"),
                   a * np.log(E - b) + c)

    return as_float(from_range_1(E_p))
Exemplo n.º 51
0
def cctf_encoding_ROMMRGB(X, bit_depth=8, out_int=False):
    """
    Defines the *ROMM RGB* encoding colour component transfer function
    (Encoding CCTF).

    Parameters
    ----------
    X : numeric or array_like
        Linear data :math:`X_{ROMM}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_int : bool, optional
        Whether to return value as integer code value or float equivalent of a
        code value at a given bit depth.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`X'_{ROMM}`.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X``          | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X_p``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    \\* This definition has an output integer switch, thus the domain-range
    scale information is only given for the floating point mode.

    References
    ----------
    :cite:`ANSI2003a`, :cite:`Spaulding2000b`

    Examples
    --------
    >>> cctf_encoding_ROMMRGB(0.18)  # doctest: +ELLIPSIS
    0.3857114...
    >>> cctf_encoding_ROMMRGB(0.18, out_int=True)
    98
    """

    X = to_domain_1(X)

    I_max = 2**bit_depth - 1

    E_t = 16**(1.8 / (1 - 1.8))

    X_p = np.where(X < E_t, X * 16 * I_max, spow(X, 1 / 1.8) * I_max)

    if out_int:
        return as_int(np.round(X_p))
    else:
        return as_float(from_range_1(X_p / I_max))
Exemplo n.º 52
0
def log_encoding_Log3G10(x, legacy_curve=False):
    """
    Defines the *Log3G10* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    legacy_curve : bool, optional
        Whether to use the v1 *Log3G10* log encoding curve. Default is *False*.

    Returns
    -------
    numeric or ndarray
        Non-linear data :math:`y`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``y``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    -   The v1 *Log3G10* log encoding curve is the one used in *REDCINE-X beta
        42*. *Resolve 12.5.2* also uses the v1 curve. *RED* is planning to use
        v2 *Log3G10* log encoding curve in the release version of the
        *RED SDK*.
        Use the `legacy_curve=True` argument to switch to the v1 curve for
        compatibility with the current (as of September 21, 2016) *RED SDK*.
    -   The intent of the v1 *Log3G10* log encoding curve is that zero maps to
        zero, 0.18 maps to 1/3, and 10 stops above 0.18 maps to 1.0.
        The name indicates this in a similar way to the naming conventions of
        *Sony HyperGamma* curves.

        The constants used in the functions do not in fact quite hit these
        values, but rather than use corrected constants, the functions here
        use the official *RED* values, in order to match the output of the
        *RED SDK*.

        For those interested, solving for constants which exactly hit 1/3
        and 1.0 yields the following values::

            B = 25 * (np.sqrt(4093.0) - 3) / 9
            A = 1 / np.log10(B * 184.32 + 1)

        where the function takes the form::

            Log3G10(x) = A * np.log10(B * x + 1)

        Similarly for *Log3G12*, the values which hit exactly 1/3 and 1.0
        are::

            B = 25 * (np.sqrt(16381.0) - 3) / 9
            A = 1 / np.log10(B * 737.28 + 1)

    References
    ----------
    :cite:`Nattress2016a`

    Examples
    --------
    >>> log_encoding_Log3G10(0.18, legacy_curve=True)  # doctest: +ELLIPSIS
    0.3333336...
    >>> log_encoding_Log3G10(0.0)  # doctest: +ELLIPSIS
    0.0915514...
    """

    x = to_domain_1(x)

    if legacy_curve:
        y = np.sign(x) * 0.222497 * np.log10((np.abs(x) * 169.379333) + 1)
    else:
        y = (np.sign(x + 0.01) * 0.224282 *
             np.log10((np.abs(x + 0.01) * 155.975327) + 1))

    return from_range_1(y)
Exemplo n.º 53
0
def log_decoding_ERIMMRGB(X_p,
                          bit_depth=8,
                          in_int=False,
                          E_min=0.001,
                          E_clip=316.2):
    """
    Defines the *ERIMM RGB* log decoding curve / electro-optical transfer
    function (EOTF / EOCF).

    Parameters
    ----------
    X_p : numeric or array_like
        Non-linear data :math:`X'_{ERIMM}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_int : bool, optional
        Whether to treat the input value as integer code value or float
        equivalent of a code value at a given bit depth.
    E_min : numeric, optional
        Minimum exposure limit.
    E_clip : numeric, optional
        Maximum exposure limit.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`X_{ERIMM}`.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X_p``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X``          | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    \\* This definition has an input integer switch, thus the domain-range
    scale information is only given for the floating point mode.

    References
    ----------
    :cite:`Spaulding2000b`

    Examples
    --------
    >>> log_decoding_ERIMMRGB(0.410052389492129) # doctest: +ELLIPSIS
    0.1...
    >>> log_decoding_ERIMMRGB(105, in_int=True) # doctest: +ELLIPSIS
    0.1...
    """

    X_p = to_domain_1(X_p)

    I_max = 2**bit_depth - 1

    if not in_int:
        X_p = X_p * I_max

    E_t = np.exp(1) * E_min

    X = np.where(
        X_p <= I_max * ((np.log(E_t) - np.log(E_min)) /
                        (np.log(E_clip) - np.log(E_min))),
        ((np.log(E_clip) - np.log(E_min)) / (np.log(E_t) - np.log(E_min))) *
        ((X_p * E_t) / I_max),
        np.exp((X_p / I_max) * (np.log(E_clip) - np.log(E_min)) +
               np.log(E_min)),
    )

    return as_float(from_range_1(X))
Exemplo n.º 54
0
def XYZ_to_Lab(
        XYZ,
        illuminant=ILLUMINANTS['CIE 1931 2 Degree Standard Observer']['D65']):
    """
    Converts from *CIE XYZ* tristimulus values to *CIE L\\*a\\*b\\**
    colourspace.

    Parameters
    ----------
    XYZ : array_like
        *CIE XYZ* tristimulus values.
    illuminant : array_like, optional
        Reference *illuminant* *xy* chromaticity coordinates or *CIE xyY*
        colourspace array.

    Returns
    -------
    ndarray
        *CIE L\\*a\\*b\\** colourspace array.

    Notes
    -----

    +----------------+-----------------------+-----------------+
    | **Domain**     | **Scale - Reference** | **Scale - 1**   |
    +================+=======================+=================+
    | ``XYZ``        | [0, 1]                | [0, 1]          |
    +----------------+-----------------------+-----------------+
    | ``illuminant`` | [0, 1]                | [0, 1]          |
    +----------------+-----------------------+-----------------+

    +----------------+-----------------------+-----------------+
    | **Range**      | **Scale - Reference** | **Scale - 1**   |
    +================+=======================+=================+
    | ``Lab``        | ``L`` : [0, 100]      | ``L`` : [0, 1]  |
    |                |                       |                 |
    |                | ``a`` : [-100, 100]   | ``a`` : [-1, 1] |
    |                |                       |                 |
    |                | ``b`` : [-100, 100]   | ``b`` : [-1, 1] |
    +----------------+-----------------------+-----------------+

    References
    ----------
    :cite:`CIETC1-482004m`

    Examples
    --------
    >>> XYZ = np.array([0.20654008, 0.12197225, 0.05136952])
    >>> XYZ_to_Lab(XYZ)  # doctest: +ELLIPSIS
    array([ 41.5278752...,  52.6385830...,  26.9231792...])
    """

    X, Y, Z = tsplit(to_domain_1(XYZ))

    X_n, Y_n, Z_n = tsplit(xyY_to_XYZ(xy_to_xyY(illuminant)))

    f_X_X_n = intermediate_lightness_function_CIE1976(X, X_n)
    f_Y_Y_n = intermediate_lightness_function_CIE1976(Y, Y_n)
    f_Z_Z_n = intermediate_lightness_function_CIE1976(Z, Z_n)

    L = 116 * f_Y_Y_n - 16
    a = 500 * (f_X_X_n - f_Y_Y_n)
    b = 200 * (f_Y_Y_n - f_Z_Z_n)

    Lab = tstack([L, a, b])

    return from_range_100(Lab)
Exemplo n.º 55
0
def cctf_decoding_RIMMRGB(X_p, bit_depth=8, in_int=False, E_clip=2.0):
    """
    Defines the *RIMM RGB* decoding colour component transfer function
    (Encoding CCTF).

    Parameters
    ----------
    X_p : numeric or array_like
        Non-linear data :math:`X'_{RIMM}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_int : bool, optional
        Whether to treat the input value as integer code value or float
        equivalent of a code value at a given bit depth.
    E_clip : numeric, optional
        Maximum exposure level.

    Returns
    -------
    numeric or ndarray
        Linear data :math:`X_{RIMM}`.

    Notes
    -----

    +----------------+-----------------------+---------------+
    | **Domain \\***  | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X_p``        | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    +----------------+-----------------------+---------------+
    | **Range \\***   | **Scale - Reference** | **Scale - 1** |
    +================+=======================+===============+
    | ``X``          | [0, 1]                | [0, 1]        |
    +----------------+-----------------------+---------------+

    \\* This definition has an input integer switch, thus the domain-range
    scale information is only given for the floating point mode.

    References
    ----------
    :cite:`Spaulding2000b`

    Examples
    --------
    >>> cctf_decoding_RIMMRGB(0.291673732475746)  # doctest: +ELLIPSIS
    0.1...
    >>> cctf_decoding_RIMMRGB(74, in_int=True)  # doctest: +ELLIPSIS
    0.1...
    """

    X_p = to_domain_1(X_p)

    I_max = 2**bit_depth - 1

    if not in_int:
        X_p = X_p * I_max

    V_clip = 1.099 * spow(E_clip, 0.45) - 0.099

    m = V_clip * X_p / I_max

    with domain_range_scale('ignore'):
        X = np.where(
            X_p / I_max < cctf_encoding_RIMMRGB(
                0.018, bit_depth, E_clip=E_clip),
            m / 4.5,
            spow((m + 0.099) / 1.099, 1 / 0.45),
        )

    return as_float(from_range_1(X))
Exemplo n.º 56
0
def JzAzBz_to_XYZ(JzAzBz, constants=JZAZBZ_CONSTANTS):
    """
    Converts from :math:`J_zA_zB_z` colourspace to *CIE XYZ* tristimulus
    values.

    Parameters
    ----------
    JzAzBz : array_like
        :math:`J_zA_zB_z` colourspace array  where :math:`J_z` is Lightness,
        :math:`A_z` is redness-greenness and :math:`B_z` is
        yellowness-blueness.
    constants : Structure, optional
        :math:`J_zA_zB_z` colourspace constants.

    Returns
    -------
    ndarray
        *CIE XYZ* tristimulus values under
        *CIE Standard Illuminant D Series D65*.

    Notes
    -----

    +------------+-----------------------+------------------+
    | **Domain** | **Scale - Reference** | **Scale - 1**    |
    +============+=======================+==================+
    | ``JzAzBz`` | ``Jz`` : [0, 1]       | ``Jz`` : [0, 1]  |
    |            |                       |                  |
    |            | ``Az`` : [-1, 1]      | ``Az`` : [-1, 1] |
    |            |                       |                  |
    |            | ``Bz`` : [-1, 1]      | ``Bz`` : [-1, 1] |
    +------------+-----------------------+------------------+

    +------------+-----------------------+------------------+
    | **Range**  | **Scale - Reference** | **Scale - 1**    |
    +============+=======================+==================+
    | ``XYZ``    | [0, 1]                | [0, 1]           |
    +------------+-----------------------+------------------+

    References
    ----------
    :cite:`Safdar2017`

    Examples
    --------
    >>> JzAzBz = np.array([0.00535048, 0.00924302, 0.00526007])
    >>> JzAzBz_to_XYZ(JzAzBz)  # doctest: +ELLIPSIS
    array([ 0.2065402...,  0.1219723...,  0.0513696...])
    """

    J_z, A_z, B_z = tsplit(to_domain_1(JzAzBz))

    I_z = ((J_z + constants.d_0) / (1 + constants.d - constants.d *
                                    (J_z + constants.d_0)))
    LMS_p = dot_vector(JZAZBZ_IZAZBZ_TO_LMS_P_MATRIX, tstack([I_z, A_z, B_z]))

    with domain_range_scale('ignore'):
        LMS = eotf_ST2084(LMS_p, 10000, constants)

    X_p_D65, Y_p_D65, Z_p_D65 = tsplit(
        dot_vector(JZAZBZ_LMS_TO_XYZ_MATRIX, LMS))

    X_D65 = (X_p_D65 + (constants.b - 1) * Z_p_D65) / constants.b
    Y_D65 = (Y_p_D65 + (constants.g - 1) * X_D65) / constants.g

    XYZ_D65 = tstack([X_D65, Y_D65, Z_p_D65])

    return from_range_1(XYZ_D65)
Exemplo n.º 57
0
def XYZ_to_JzAzBz(XYZ_D65, constants=JZAZBZ_CONSTANTS):
    """
    Converts from *CIE XYZ* tristimulus values to :math:`J_zA_zB_z`
    colourspace.

    Parameters
    ----------
    XYZ_D65 : array_like
        *CIE XYZ* tristimulus values under
        *CIE Standard Illuminant D Series D65*.
    constants : Structure, optional
        :math:`J_zA_zB_z` colourspace constants.

    Returns
    -------
    ndarray
        :math:`J_zA_zB_z` colourspace array where :math:`J_z` is Lightness,
        :math:`A_z` is redness-greenness and :math:`B_z` is
        yellowness-blueness.

    Notes
    -----

    +------------+-----------------------+------------------+
    | **Domain** | **Scale - Reference** | **Scale - 1**    |
    +============+=======================+==================+
    | ``XYZ``    | [0, 1]                | [0, 1]           |
    +------------+-----------------------+------------------+

    +------------+-----------------------+------------------+
    | **Range**  | **Scale - Reference** | **Scale - 1**    |
    +============+=======================+==================+
    | ``JzAzBz`` | ``Jz`` : [0, 1]       | ``Jz`` : [0, 1]  |
    |            |                       |                  |
    |            | ``Az`` : [-1, 1]      | ``Az`` : [-1, 1] |
    |            |                       |                  |
    |            | ``Bz`` : [-1, 1]      | ``Bz`` : [-1, 1] |
    +------------+-----------------------+------------------+

    References
    ----------
    :cite:`Safdar2017`

    Examples
    --------
    >>> XYZ = np.array([0.20654008, 0.12197225, 0.05136952])
    >>> XYZ_to_JzAzBz(XYZ)  # doctest: +ELLIPSIS
    array([ 0.0053504...,  0.0092430...,  0.0052600...])
    """

    X_D65, Y_D65, Z_D65 = tsplit(to_domain_1(XYZ_D65))

    X_p_D65 = constants.b * X_D65 - (constants.b - 1) * Z_D65
    Y_p_D65 = constants.g * Y_D65 - (constants.g - 1) * X_D65

    XYZ_p_D65 = tstack([X_p_D65, Y_p_D65, Z_D65])

    LMS = dot_vector(JZAZBZ_XYZ_TO_LMS_MATRIX, XYZ_p_D65)

    with domain_range_scale('ignore'):
        LMS_p = oetf_ST2084(LMS, 10000, constants)

    I_z, A_z, B_z = tsplit(dot_vector(JZAZBZ_LMS_P_TO_IZAZBZ_MATRIX, LMS_p))

    J_z = ((1 + constants.d) * I_z) / (1 + constants.d * I_z) - constants.d_0

    JzAzBz = tstack([J_z, A_z, B_z])

    return from_range_1(JzAzBz)
Exemplo n.º 58
0
def log_decoding_VLog(V_out,
                      bit_depth=10,
                      in_legal=True,
                      out_reflection=True,
                      constants=VLOG_CONSTANTS):
    """
    Defines the *Panasonic V-Log* log decoding curve / electro-optical transfer
    function.

    Parameters
    ----------
    V_out : numeric or array_like
        Non-linear data :math:`V_{out}`.
    bit_depth : int, optional
        Bit depth used for conversion.
    in_legal : bool, optional
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded in legal range.
    out_reflection : bool, optional
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants : Structure, optional
        *Panasonic V-Log* constants.

    Returns
    -------
    numeric or ndarray
        Linear reflection data :math`L_{in}`.

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_decoding_VLog(0.423311448760136)  # doctest: +ELLIPSIS
    0.1799999...
    """

    V_out = to_domain_1(V_out)

    V_out = V_out if in_legal else full_to_legal(V_out, bit_depth)

    cut2 = constants.cut2
    b = constants.b
    c = constants.c
    d = constants.d

    L_in = np.where(
        V_out < cut2,
        (V_out - 0.125) / 5.6,
        10**((V_out - d) / c) - b,
    )

    if not out_reflection:
        L_in = L_in / 0.9

    return as_float(from_range_1(L_in))
Exemplo n.º 59
0
def log_encoding_CanonLog3(x,
                           bit_depth=10,
                           out_normalised_code_value=True,
                           in_reflection=True,
                           **kwargs):
    """
    Defines the *Canon Log 3* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    x : numeric or array_like
        Linear data :math:`x`.
    bit_depth : int, optional
        Bit depth used for conversion.
    out_normalised_code_value : bool, optional
        Whether the *Canon Log 3* non-linear data is encoded as normalised code
        values.
    in_reflection : bool, optional
        Whether the light level :math:`x` to a camera is reflection.

    Other Parameters
    ----------------
    \\**kwargs : dict, optional
        Keywords arguments for deprecation management.

    Returns
    -------
    numeric or ndarray
        *Canon Log 3* non-linear data.

    Notes
    -----
    -   Introspection of the grafting points by Shaw, N. (2018) shows that the
        *Canon Log 3* IDT was likely derived from its encoding curve as the
        later is grafted at *+/-0.014*::

            >>> clog3 = 0.04076162
            >>> (clog3 - 0.073059361) / 2.3069815
            -0.014000000000000002
            >>> clog3 = 0.105357102
            >>> (clog3 - 0.073059361) / 2.3069815
            0.013999999999999997

    Notes
    -----

    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``x``      | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``clog3``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Canona`

    Examples
    --------
    >>> log_encoding_CanonLog3(0.18) * 100  # doctest: +ELLIPSIS
    34.3389369...
    """

    out_normalised_code_value = handle_arguments_deprecation(
        {
            'ArgumentRenamed': [['out_legal', 'out_normalised_code_value']],
        }, **kwargs).get('out_normalised_code_value',
                         out_normalised_code_value)

    x = to_domain_1(x)

    if in_reflection:
        x = x / 0.9

    with domain_range_scale('ignore'):
        clog3 = np.select(
            (x < log_decoding_CanonLog3(0.04076162, bit_depth, False, False),
             x <= log_decoding_CanonLog3(0.105357102, bit_depth, False, False),
             x > log_decoding_CanonLog3(0.105357102, bit_depth, False, False)),
            (-0.42889912 * np.log10(-x * 14.98325 + 1) + 0.07623209,
             2.3069815 * x + 0.073059361,
             0.42889912 * np.log10(x * 14.98325 + 1) + 0.069886632))

    clog3 = (full_to_legal(clog3, bit_depth)
             if out_normalised_code_value else clog3)

    return as_float(from_range_1(clog3))
Exemplo n.º 60
0
def log_encoding_VLog(
    L_in: FloatingOrArrayLike,
    bit_depth: Integer = 10,
    out_normalised_code_value: Boolean = True,
    in_reflection: Boolean = True,
    constants: Structure = CONSTANTS_VLOG,
) -> FloatingOrNDArray:
    """
    Define the *Panasonic V-Log* log encoding curve / opto-electronic transfer
    function.

    Parameters
    ----------
    L_in
        Linear reflection data :math`L_{in}`.
    bit_depth
        Bit depth used for conversion.
    out_normalised_code_value
        Whether the non-linear *Panasonic V-Log* data :math:`V_{out}` is
        encoded as normalised code values.
    in_reflection
        Whether the light level :math`L_{in}` to a camera is reflection.
    constants
        *Panasonic V-Log* constants.

    Returns
    -------
    :class:`numpy.floating` or :class:`numpy.ndarray`
        Non-linear data :math:`V_{out}`.

    Notes
    -----
    +------------+-----------------------+---------------+
    | **Domain** | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``L_in``   | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    +------------+-----------------------+---------------+
    | **Range**  | **Scale - Reference** | **Scale - 1** |
    +============+=======================+===============+
    | ``V_out``  | [0, 1]                | [0, 1]        |
    +------------+-----------------------+---------------+

    References
    ----------
    :cite:`Panasonic2014a`

    Examples
    --------
    >>> log_encoding_VLog(0.18)  # doctest: +ELLIPSIS
    0.4233114...

    The values of *Fig.2.2 V-Log Code Value* table in :cite:`Panasonic2014a`
    are obtained as follows:

    >>> L_in = np.array([0, 18, 90]) / 100
    >>> np.around(log_encoding_VLog(L_in, 10, False) * 100).astype(np.int)
    array([ 7, 42, 61])
    >>> np.around(log_encoding_VLog(L_in) * (2 ** 10 - 1)).astype(np.int)
    array([128, 433, 602])
    >>> np.around(log_encoding_VLog(L_in) * (2 ** 12 - 1)).astype(np.int)
    array([ 512, 1733, 2409])

    Note that some values in the last column values of
    *Fig.2.2 V-Log Code Value* table in :cite:`Panasonic2014a` are different
    by a code: [512, 1732, 2408].
    """

    L_in = to_domain_1(L_in)

    if not in_reflection:
        L_in = L_in * 0.9

    cut1 = constants.cut1
    b = constants.b
    c = constants.c
    d = constants.d

    V_out = np.where(
        L_in < cut1,
        5.6 * L_in + 0.125,
        c * np.log10(L_in + b) + d,
    )

    V_out_cv = (V_out if out_normalised_code_value else legal_to_full(
        V_out, bit_depth))

    return as_float(from_range_1(V_out_cv))