colour.ootf_inverse#
- colour.ootf_inverse(value: Union[numpy._typing._array_like._SupportsArray[numpy.dtype[Any]], numpy._typing._nested_sequence._NestedSequence[numpy._typing._array_like._SupportsArray[numpy.dtype[Any]]], bool, int, float, complex, str, bytes, numpy._typing._nested_sequence._NestedSequence[Union[bool, int, float, complex, str, bytes]]], function: Union[Literal['ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ'], str] = 'ITU-R BT.2100 PQ', **kwargs: Any) numpy.ndarray[Any, numpy.dtype[Union[numpy.float16, numpy.float32, numpy.float64]]][source]#
Map relative display linear light to scene linear light using given inverse opto-optical transfer function (OOTF / OOCF).
- Parameters
value (Union[numpy._typing._array_like._SupportsArray[numpy.dtype[Any]], numpy._typing._nested_sequence._NestedSequence[numpy._typing._array_like._SupportsArray[numpy.dtype[Any]]], bool, int, float, complex, str, bytes, numpy._typing._nested_sequence._NestedSequence[Union[bool, int, float, complex, str, bytes]]]) – Value.
function (Union[Literal['ITU-R BT.2100 HLG', 'ITU-R BT.2100 PQ'], str]) – Inverse opto-optical transfer function (OOTF / OOCF).
kwargs (Any) – {
colour.models.ootf_inverse_BT2100_HLG(),colour.models.ootf_inverse_BT2100_PQ()}, See the documentation of the previously listed definitions.
- Returns
Luminance of scene linear light.
- Return type
Examples
>>> ootf_inverse(779.988360834115840) 0.1000000... >>> ootf_inverse( ... 63.095734448019336, function="ITU-R BT.2100 HLG" ... ) 0.1000000...