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435 lines
13 KiB
435 lines
13 KiB
"""Implementation of the Kronecker product"""
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from functools import reduce
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from math import prod
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from sympy.core import Mul, sympify
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from sympy.functions import adjoint
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from sympy.matrices.common import ShapeError
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from sympy.matrices.expressions.matexpr import MatrixExpr
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from sympy.matrices.expressions.transpose import transpose
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from sympy.matrices.expressions.special import Identity
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from sympy.matrices.matrices import MatrixBase
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from sympy.strategies import (
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canon, condition, distribute, do_one, exhaust, flatten, typed, unpack)
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from sympy.strategies.traverse import bottom_up
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from sympy.utilities import sift
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from .matadd import MatAdd
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from .matmul import MatMul
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from .matpow import MatPow
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def kronecker_product(*matrices):
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"""
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The Kronecker product of two or more arguments.
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This computes the explicit Kronecker product for subclasses of
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``MatrixBase`` i.e. explicit matrices. Otherwise, a symbolic
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``KroneckerProduct`` object is returned.
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Examples
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========
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For ``MatrixSymbol`` arguments a ``KroneckerProduct`` object is returned.
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Elements of this matrix can be obtained by indexing, or for MatrixSymbols
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with known dimension the explicit matrix can be obtained with
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``.as_explicit()``
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>>> from sympy import kronecker_product, MatrixSymbol
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>>> A = MatrixSymbol('A', 2, 2)
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>>> B = MatrixSymbol('B', 2, 2)
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>>> kronecker_product(A)
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A
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>>> kronecker_product(A, B)
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KroneckerProduct(A, B)
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>>> kronecker_product(A, B)[0, 1]
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A[0, 0]*B[0, 1]
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>>> kronecker_product(A, B).as_explicit()
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Matrix([
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[A[0, 0]*B[0, 0], A[0, 0]*B[0, 1], A[0, 1]*B[0, 0], A[0, 1]*B[0, 1]],
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[A[0, 0]*B[1, 0], A[0, 0]*B[1, 1], A[0, 1]*B[1, 0], A[0, 1]*B[1, 1]],
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[A[1, 0]*B[0, 0], A[1, 0]*B[0, 1], A[1, 1]*B[0, 0], A[1, 1]*B[0, 1]],
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[A[1, 0]*B[1, 0], A[1, 0]*B[1, 1], A[1, 1]*B[1, 0], A[1, 1]*B[1, 1]]])
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For explicit matrices the Kronecker product is returned as a Matrix
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>>> from sympy import Matrix, kronecker_product
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>>> sigma_x = Matrix([
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... [0, 1],
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... [1, 0]])
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...
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>>> Isigma_y = Matrix([
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... [0, 1],
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... [-1, 0]])
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...
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>>> kronecker_product(sigma_x, Isigma_y)
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Matrix([
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[ 0, 0, 0, 1],
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[ 0, 0, -1, 0],
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[ 0, 1, 0, 0],
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[-1, 0, 0, 0]])
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See Also
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========
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KroneckerProduct
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"""
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if not matrices:
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raise TypeError("Empty Kronecker product is undefined")
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if len(matrices) == 1:
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return matrices[0]
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else:
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return KroneckerProduct(*matrices).doit()
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class KroneckerProduct(MatrixExpr):
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"""
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The Kronecker product of two or more arguments.
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The Kronecker product is a non-commutative product of matrices.
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Given two matrices of dimension (m, n) and (s, t) it produces a matrix
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of dimension (m s, n t).
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This is a symbolic object that simply stores its argument without
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evaluating it. To actually compute the product, use the function
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``kronecker_product()`` or call the ``.doit()`` or ``.as_explicit()``
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methods.
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>>> from sympy import KroneckerProduct, MatrixSymbol
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>>> A = MatrixSymbol('A', 5, 5)
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>>> B = MatrixSymbol('B', 5, 5)
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>>> isinstance(KroneckerProduct(A, B), KroneckerProduct)
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True
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"""
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is_KroneckerProduct = True
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def __new__(cls, *args, check=True):
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args = list(map(sympify, args))
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if all(a.is_Identity for a in args):
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ret = Identity(prod(a.rows for a in args))
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if all(isinstance(a, MatrixBase) for a in args):
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return ret.as_explicit()
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else:
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return ret
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if check:
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validate(*args)
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return super().__new__(cls, *args)
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@property
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def shape(self):
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rows, cols = self.args[0].shape
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for mat in self.args[1:]:
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rows *= mat.rows
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cols *= mat.cols
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return (rows, cols)
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def _entry(self, i, j, **kwargs):
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result = 1
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for mat in reversed(self.args):
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i, m = divmod(i, mat.rows)
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j, n = divmod(j, mat.cols)
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result *= mat[m, n]
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return result
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def _eval_adjoint(self):
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return KroneckerProduct(*list(map(adjoint, self.args))).doit()
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def _eval_conjugate(self):
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return KroneckerProduct(*[a.conjugate() for a in self.args]).doit()
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def _eval_transpose(self):
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return KroneckerProduct(*list(map(transpose, self.args))).doit()
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def _eval_trace(self):
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from .trace import trace
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return Mul(*[trace(a) for a in self.args])
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def _eval_determinant(self):
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from .determinant import det, Determinant
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if not all(a.is_square for a in self.args):
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return Determinant(self)
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m = self.rows
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return Mul(*[det(a)**(m/a.rows) for a in self.args])
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def _eval_inverse(self):
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try:
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return KroneckerProduct(*[a.inverse() for a in self.args])
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except ShapeError:
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from sympy.matrices.expressions.inverse import Inverse
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return Inverse(self)
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def structurally_equal(self, other):
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'''Determine whether two matrices have the same Kronecker product structure
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Examples
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========
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>>> from sympy import KroneckerProduct, MatrixSymbol, symbols
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>>> m, n = symbols(r'm, n', integer=True)
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>>> A = MatrixSymbol('A', m, m)
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>>> B = MatrixSymbol('B', n, n)
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>>> C = MatrixSymbol('C', m, m)
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>>> D = MatrixSymbol('D', n, n)
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>>> KroneckerProduct(A, B).structurally_equal(KroneckerProduct(C, D))
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True
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>>> KroneckerProduct(A, B).structurally_equal(KroneckerProduct(D, C))
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False
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>>> KroneckerProduct(A, B).structurally_equal(C)
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False
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'''
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# Inspired by BlockMatrix
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return (isinstance(other, KroneckerProduct)
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and self.shape == other.shape
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and len(self.args) == len(other.args)
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and all(a.shape == b.shape for (a, b) in zip(self.args, other.args)))
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def has_matching_shape(self, other):
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'''Determine whether two matrices have the appropriate structure to bring matrix
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multiplication inside the KroneckerProdut
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Examples
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========
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>>> from sympy import KroneckerProduct, MatrixSymbol, symbols
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>>> m, n = symbols(r'm, n', integer=True)
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>>> A = MatrixSymbol('A', m, n)
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>>> B = MatrixSymbol('B', n, m)
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>>> KroneckerProduct(A, B).has_matching_shape(KroneckerProduct(B, A))
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True
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>>> KroneckerProduct(A, B).has_matching_shape(KroneckerProduct(A, B))
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False
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>>> KroneckerProduct(A, B).has_matching_shape(A)
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False
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'''
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return (isinstance(other, KroneckerProduct)
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and self.cols == other.rows
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and len(self.args) == len(other.args)
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and all(a.cols == b.rows for (a, b) in zip(self.args, other.args)))
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def _eval_expand_kroneckerproduct(self, **hints):
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return flatten(canon(typed({KroneckerProduct: distribute(KroneckerProduct, MatAdd)}))(self))
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def _kronecker_add(self, other):
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if self.structurally_equal(other):
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return self.__class__(*[a + b for (a, b) in zip(self.args, other.args)])
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else:
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return self + other
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def _kronecker_mul(self, other):
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if self.has_matching_shape(other):
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return self.__class__(*[a*b for (a, b) in zip(self.args, other.args)])
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else:
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return self * other
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def doit(self, **hints):
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deep = hints.get('deep', True)
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if deep:
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args = [arg.doit(**hints) for arg in self.args]
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else:
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args = self.args
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return canonicalize(KroneckerProduct(*args))
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def validate(*args):
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if not all(arg.is_Matrix for arg in args):
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raise TypeError("Mix of Matrix and Scalar symbols")
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# rules
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def extract_commutative(kron):
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c_part = []
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nc_part = []
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for arg in kron.args:
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c, nc = arg.args_cnc()
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c_part.extend(c)
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nc_part.append(Mul._from_args(nc))
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c_part = Mul(*c_part)
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if c_part != 1:
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return c_part*KroneckerProduct(*nc_part)
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return kron
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def matrix_kronecker_product(*matrices):
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"""Compute the Kronecker product of a sequence of SymPy Matrices.
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This is the standard Kronecker product of matrices [1].
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Parameters
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==========
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matrices : tuple of MatrixBase instances
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The matrices to take the Kronecker product of.
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Returns
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=======
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matrix : MatrixBase
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The Kronecker product matrix.
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Examples
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========
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>>> from sympy import Matrix
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>>> from sympy.matrices.expressions.kronecker import (
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... matrix_kronecker_product)
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>>> m1 = Matrix([[1,2],[3,4]])
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>>> m2 = Matrix([[1,0],[0,1]])
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>>> matrix_kronecker_product(m1, m2)
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Matrix([
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[1, 0, 2, 0],
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[0, 1, 0, 2],
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[3, 0, 4, 0],
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[0, 3, 0, 4]])
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>>> matrix_kronecker_product(m2, m1)
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Matrix([
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[1, 2, 0, 0],
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[3, 4, 0, 0],
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[0, 0, 1, 2],
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[0, 0, 3, 4]])
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Kronecker_product
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"""
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# Make sure we have a sequence of Matrices
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if not all(isinstance(m, MatrixBase) for m in matrices):
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raise TypeError(
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'Sequence of Matrices expected, got: %s' % repr(matrices)
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)
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# Pull out the first element in the product.
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matrix_expansion = matrices[-1]
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# Do the kronecker product working from right to left.
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for mat in reversed(matrices[:-1]):
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rows = mat.rows
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cols = mat.cols
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# Go through each row appending kronecker product to.
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# running matrix_expansion.
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for i in range(rows):
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start = matrix_expansion*mat[i*cols]
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# Go through each column joining each item
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for j in range(cols - 1):
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start = start.row_join(
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matrix_expansion*mat[i*cols + j + 1]
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)
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# If this is the first element, make it the start of the
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# new row.
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if i == 0:
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next = start
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else:
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next = next.col_join(start)
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matrix_expansion = next
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MatrixClass = max(matrices, key=lambda M: M._class_priority).__class__
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if isinstance(matrix_expansion, MatrixClass):
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return matrix_expansion
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else:
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return MatrixClass(matrix_expansion)
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def explicit_kronecker_product(kron):
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# Make sure we have a sequence of Matrices
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if not all(isinstance(m, MatrixBase) for m in kron.args):
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return kron
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return matrix_kronecker_product(*kron.args)
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rules = (unpack,
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explicit_kronecker_product,
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flatten,
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extract_commutative)
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canonicalize = exhaust(condition(lambda x: isinstance(x, KroneckerProduct),
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do_one(*rules)))
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def _kronecker_dims_key(expr):
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if isinstance(expr, KroneckerProduct):
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return tuple(a.shape for a in expr.args)
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else:
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return (0,)
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def kronecker_mat_add(expr):
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args = sift(expr.args, _kronecker_dims_key)
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nonkrons = args.pop((0,), None)
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if not args:
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return expr
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krons = [reduce(lambda x, y: x._kronecker_add(y), group)
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for group in args.values()]
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if not nonkrons:
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return MatAdd(*krons)
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else:
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return MatAdd(*krons) + nonkrons
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def kronecker_mat_mul(expr):
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# modified from block matrix code
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factor, matrices = expr.as_coeff_matrices()
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i = 0
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while i < len(matrices) - 1:
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A, B = matrices[i:i+2]
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if isinstance(A, KroneckerProduct) and isinstance(B, KroneckerProduct):
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matrices[i] = A._kronecker_mul(B)
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matrices.pop(i+1)
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else:
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i += 1
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return factor*MatMul(*matrices)
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def kronecker_mat_pow(expr):
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if isinstance(expr.base, KroneckerProduct) and all(a.is_square for a in expr.base.args):
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return KroneckerProduct(*[MatPow(a, expr.exp) for a in expr.base.args])
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else:
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return expr
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def combine_kronecker(expr):
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"""Combine KronekeckerProduct with expression.
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If possible write operations on KroneckerProducts of compatible shapes
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as a single KroneckerProduct.
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Examples
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========
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>>> from sympy.matrices.expressions import combine_kronecker
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>>> from sympy import MatrixSymbol, KroneckerProduct, symbols
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>>> m, n = symbols(r'm, n', integer=True)
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>>> A = MatrixSymbol('A', m, n)
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>>> B = MatrixSymbol('B', n, m)
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>>> combine_kronecker(KroneckerProduct(A, B)*KroneckerProduct(B, A))
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KroneckerProduct(A*B, B*A)
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>>> combine_kronecker(KroneckerProduct(A, B)+KroneckerProduct(B.T, A.T))
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KroneckerProduct(A + B.T, B + A.T)
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>>> C = MatrixSymbol('C', n, n)
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>>> D = MatrixSymbol('D', m, m)
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>>> combine_kronecker(KroneckerProduct(C, D)**m)
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KroneckerProduct(C**m, D**m)
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"""
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def haskron(expr):
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return isinstance(expr, MatrixExpr) and expr.has(KroneckerProduct)
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rule = exhaust(
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bottom_up(exhaust(condition(haskron, typed(
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{MatAdd: kronecker_mat_add,
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MatMul: kronecker_mat_mul,
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MatPow: kronecker_mat_pow})))))
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result = rule(expr)
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doit = getattr(result, 'doit', None)
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if doit is not None:
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return doit()
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else:
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return result
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