pylops_distributed.BlockDiag¶

class pylops_distributed.BlockDiag(ops, chunks=None, compute=(False, False), todask=(False, False), dtype=None)[source]¶

Block-diagonal operator.

Create a block-diagonal operator from N linear operators.

Parameters:

ops : list: Linear operators to be stacked
chunks : tuple, optional: Chunks for model and data (an array with a single chunk is created if chunks is not provided)
compute : tuple, optional: Compute the outcome of forward and adjoint or simply define the graph and return a dask.array
todask : tuple, optional: Apply dask.array.from_array to model and data before applying forward and adjoint respectively
dtype : str, optional: Type of elements in input array.

Notes

Refer to pylops.basicoperators.VStack for implementation details.

Attributes:	shape : `tuple` Operator shape explicit : `bool` Operator contains a matrix that can be solved explicitly (`True`) or not (`False`)

Methods

`__init__`(ops[, chunks, compute, todask, dtype])	Initialize this LinearOperator.
`adjoint`()	Hermitian adjoint.
`apply_columns`(cols)	Apply subset of columns of operator
`cond`([uselobpcg])	Condition number of linear operator.
`conj`()	Complex conjugate operator
`div`(y[, niter])	Solve the linear problem \(\mathbf{y}=\mathbf{A}\mathbf{x}\).
`dot`(x)	Matrix-vector multiplication.
`eigs`([neigs, symmetric, niter, uselobpcg])	Most significant eigenvalues of linear operator.
`matmat`(X)	Matrix-matrix multiplication.
`matvec`(x)	Matrix-vector multiplication.
`rmatmat`(X)	Adjoint matrix-matrix multiplication.
`rmatvec`(x)	Adjoint Matrix-vector multiplication.
`todense`()	Return dense matrix.
`tosparse`()	Return sparse matrix.
`transpose`()	Transpose this linear operator.