def test_triangular():
assert ask(Q.upper_triangular(X + Z.T + Identity(2)),
Q.upper_triangular(X) & Q.lower_triangular(Z)) is True
assert ask(Q.upper_triangular(X * Z.T),
Q.upper_triangular(X) & Q.lower_triangular(Z)) is True
assert ask(Q.lower_triangular(Identity(3))) is True
assert ask(Q.lower_triangular(ZeroMatrix(3, 3))) is True
assert ask(Q.upper_triangular(ZeroMatrix(3, 3))) is True
assert ask(Q.lower_triangular(OneMatrix(1, 1))) is True
assert ask(Q.upper_triangular(OneMatrix(1, 1))) is True
assert ask(Q.lower_triangular(OneMatrix(3, 3))) is False
assert ask(Q.upper_triangular(OneMatrix(3, 3))) is False
assert ask(Q.triangular(X), Q.unit_triangular(X))
assert ask(Q.upper_triangular(X**3), Q.upper_triangular(X))
assert ask(Q.lower_triangular(X**3), Q.lower_triangular(X))
def refine_Determinant(expr, assumptions):
"""
>>> from sympy import MatrixSymbol, Q, assuming, refine, det
>>> X = MatrixSymbol('X', 2, 2)
>>> det(X)
Determinant(X)
>>> with assuming(Q.orthogonal(X)):
... print(refine(det(X)))
1
"""
if ask(Q.orthogonal(expr.arg), assumptions):
return S.One
elif ask(Q.singular(expr.arg), assumptions):
return S.Zero
elif ask(Q.unit_triangular(expr.arg), assumptions):
return S.One
return expr
def refine_Determinant(expr, assumptions):
"""
>>> from sympy import MatrixSymbol, Q, assuming, refine, det
>>> X = MatrixSymbol('X', 2, 2)
>>> det(X)
Determinant(X)
>>> with assuming(Q.orthogonal(X)):
... print(refine(det(X)))
1
"""
if ask(Q.orthogonal(expr.arg), assumptions):
return S.One
elif ask(Q.singular(expr.arg), assumptions):
return S.Zero
elif ask(Q.unit_triangular(expr.arg), assumptions):
return S.One
return expr
def test_refine():
assert refine(det(A), Q.orthogonal(A)) == 1
assert refine(det(A), Q.singular(A)) == 0
assert refine(det(A), Q.unit_triangular(A)) == 1
assert refine(det(A), Q.normal(A)) == det(A)
def get_known_facts(x=None):
"""
Facts between unary predicates.
Parameters
==========
x : Symbol, optional
Placeholder symbol for unary facts. Default is ``Symbol('x')``.
Returns
=======
fact : Known facts in conjugated normal form.
"""
if x is None:
x = Symbol('x')
fact = And(
# primitive predicates for extended real exclude each other.
Exclusive(Q.negative_infinite(x), Q.negative(x), Q.zero(x),
Q.positive(x), Q.positive_infinite(x)),
# build complex plane
Exclusive(Q.real(x), Q.imaginary(x)),
Implies(Q.real(x) | Q.imaginary(x), Q.complex(x)),
# other subsets of complex
Exclusive(Q.transcendental(x), Q.algebraic(x)),
Equivalent(Q.real(x),
Q.rational(x) | Q.irrational(x)),
Exclusive(Q.irrational(x), Q.rational(x)),
Implies(Q.rational(x), Q.algebraic(x)),
# integers
Exclusive(Q.even(x), Q.odd(x)),
Implies(Q.integer(x), Q.rational(x)),
Implies(Q.zero(x), Q.even(x)),
Exclusive(Q.composite(x), Q.prime(x)),
Implies(Q.composite(x) | Q.prime(x),
Q.integer(x) & Q.positive(x)),
Implies(Q.even(x) & Q.positive(x) & ~Q.prime(x), Q.composite(x)),
# hermitian and antihermitian
Implies(Q.real(x), Q.hermitian(x)),
Implies(Q.imaginary(x), Q.antihermitian(x)),
Implies(Q.zero(x),
Q.hermitian(x) | Q.antihermitian(x)),
# define finity and infinity, and build extended real line
Exclusive(Q.infinite(x), Q.finite(x)),
Implies(Q.complex(x), Q.finite(x)),
Implies(
Q.negative_infinite(x) | Q.positive_infinite(x), Q.infinite(x)),
# commutativity
Implies(Q.finite(x) | Q.infinite(x), Q.commutative(x)),
# matrices
Implies(Q.orthogonal(x), Q.positive_definite(x)),
Implies(Q.orthogonal(x), Q.unitary(x)),
Implies(Q.unitary(x) & Q.real_elements(x), Q.orthogonal(x)),
Implies(Q.unitary(x), Q.normal(x)),
Implies(Q.unitary(x), Q.invertible(x)),
Implies(Q.normal(x), Q.square(x)),
Implies(Q.diagonal(x), Q.normal(x)),
Implies(Q.positive_definite(x), Q.invertible(x)),
Implies(Q.diagonal(x), Q.upper_triangular(x)),
Implies(Q.diagonal(x), Q.lower_triangular(x)),
Implies(Q.lower_triangular(x), Q.triangular(x)),
Implies(Q.upper_triangular(x), Q.triangular(x)),
Implies(Q.triangular(x),
Q.upper_triangular(x) | Q.lower_triangular(x)),
Implies(Q.upper_triangular(x) & Q.lower_triangular(x), Q.diagonal(x)),
Implies(Q.diagonal(x), Q.symmetric(x)),
Implies(Q.unit_triangular(x), Q.triangular(x)),
Implies(Q.invertible(x), Q.fullrank(x)),
Implies(Q.invertible(x), Q.square(x)),
Implies(Q.symmetric(x), Q.square(x)),
Implies(Q.fullrank(x) & Q.square(x), Q.invertible(x)),
Equivalent(Q.invertible(x), ~Q.singular(x)),
Implies(Q.integer_elements(x), Q.real_elements(x)),
Implies(Q.real_elements(x), Q.complex_elements(x)),
)
return fact