Source code for pylops.basicoperators.real

__all__ = ["Real"]
from typing import Union

import numpy as np

from pylops import LinearOperator
from pylops.utils._internal import _value_or_sized_to_tuple
from pylops.utils.typing import DTypeLike, InputDimsLike, NDArray


[docs]class Real(LinearOperator): r"""Real operator. Return the real component of the input. The adjoint returns a complex number with the same real component as the input and zero imaginary component. Parameters ---------- dims : :obj:`int` or :obj:`tuple` Number of samples for each dimension dtype : :obj:`str`, optional Type of elements in input array. name : :obj:`str`, optional .. versionadded:: 2.0.0 Name of operator (to be used by :func:`pylops.utils.describe.describe`) Attributes ---------- shape : :obj:`tuple` Operator shape explicit : :obj:`bool` Operator contains a matrix that can be solved explicitly (``True``) or not (``False``) Notes ----- In forward mode: .. math:: y_{i} = \Re\{x_{i}\} \quad \forall i=0,\ldots,N-1 In adjoint mode: .. math:: x_{i} = \Re\{y_{i}\} + 0i \quad \forall i=0,\ldots,N-1 """ def __init__( self, dims: Union[int, InputDimsLike], dtype: DTypeLike = "complex128", name: str = "R", ) -> None: dims = _value_or_sized_to_tuple(dims) super().__init__( dtype=np.dtype(dtype), dims=dims, dimsd=dims, clinear=False, name=name ) self.rdtype = np.real(np.ones(1, self.dtype)).dtype def _matvec(self, x: NDArray) -> NDArray: return x.real.astype(self.rdtype) def _rmatvec(self, x: NDArray) -> NDArray: return (x.real + 0j).astype(self.dtype)