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150 lines
4.3 KiB
150 lines
4.3 KiB
"""The anti-commutator: ``{A,B} = A*B + B*A``."""
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from sympy.core.expr import Expr
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from sympy.core.mul import Mul
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from sympy.core.numbers import Integer
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from sympy.core.singleton import S
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from sympy.printing.pretty.stringpict import prettyForm
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from sympy.physics.quantum.operator import Operator
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from sympy.physics.quantum.dagger import Dagger
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__all__ = [
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'AntiCommutator'
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]
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#-----------------------------------------------------------------------------
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# Anti-commutator
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#-----------------------------------------------------------------------------
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class AntiCommutator(Expr):
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"""The standard anticommutator, in an unevaluated state.
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Explanation
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===========
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Evaluating an anticommutator is defined [1]_ as: ``{A, B} = A*B + B*A``.
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This class returns the anticommutator in an unevaluated form. To evaluate
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the anticommutator, use the ``.doit()`` method.
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Canonical ordering of an anticommutator is ``{A, B}`` for ``A < B``. The
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arguments of the anticommutator are put into canonical order using
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``__cmp__``. If ``B < A``, then ``{A, B}`` is returned as ``{B, A}``.
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Parameters
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==========
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A : Expr
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The first argument of the anticommutator {A,B}.
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B : Expr
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The second argument of the anticommutator {A,B}.
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Examples
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========
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>>> from sympy import symbols
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>>> from sympy.physics.quantum import AntiCommutator
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>>> from sympy.physics.quantum import Operator, Dagger
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>>> x, y = symbols('x,y')
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>>> A = Operator('A')
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>>> B = Operator('B')
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Create an anticommutator and use ``doit()`` to multiply them out.
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>>> ac = AntiCommutator(A,B); ac
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{A,B}
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>>> ac.doit()
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A*B + B*A
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The commutator orders it arguments in canonical order:
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>>> ac = AntiCommutator(B,A); ac
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{A,B}
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Commutative constants are factored out:
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>>> AntiCommutator(3*x*A,x*y*B)
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3*x**2*y*{A,B}
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Adjoint operations applied to the anticommutator are properly applied to
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the arguments:
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>>> Dagger(AntiCommutator(A,B))
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{Dagger(A),Dagger(B)}
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Commutator
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"""
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is_commutative = False
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def __new__(cls, A, B):
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r = cls.eval(A, B)
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if r is not None:
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return r
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obj = Expr.__new__(cls, A, B)
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return obj
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@classmethod
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def eval(cls, a, b):
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if not (a and b):
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return S.Zero
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if a == b:
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return Integer(2)*a**2
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if a.is_commutative or b.is_commutative:
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return Integer(2)*a*b
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# [xA,yB] -> xy*[A,B]
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ca, nca = a.args_cnc()
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cb, ncb = b.args_cnc()
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c_part = ca + cb
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if c_part:
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return Mul(Mul(*c_part), cls(Mul._from_args(nca), Mul._from_args(ncb)))
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# Canonical ordering of arguments
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#The Commutator [A,B] is on canonical form if A < B.
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if a.compare(b) == 1:
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return cls(b, a)
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def doit(self, **hints):
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""" Evaluate anticommutator """
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A = self.args[0]
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B = self.args[1]
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if isinstance(A, Operator) and isinstance(B, Operator):
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try:
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comm = A._eval_anticommutator(B, **hints)
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except NotImplementedError:
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try:
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comm = B._eval_anticommutator(A, **hints)
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except NotImplementedError:
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comm = None
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if comm is not None:
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return comm.doit(**hints)
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return (A*B + B*A).doit(**hints)
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def _eval_adjoint(self):
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return AntiCommutator(Dagger(self.args[0]), Dagger(self.args[1]))
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def _sympyrepr(self, printer, *args):
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return "%s(%s,%s)" % (
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self.__class__.__name__, printer._print(
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self.args[0]), printer._print(self.args[1])
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)
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def _sympystr(self, printer, *args):
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return "{%s,%s}" % (
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printer._print(self.args[0]), printer._print(self.args[1]))
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def _pretty(self, printer, *args):
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pform = printer._print(self.args[0], *args)
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pform = prettyForm(*pform.right(prettyForm(',')))
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pform = prettyForm(*pform.right(printer._print(self.args[1], *args)))
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pform = prettyForm(*pform.parens(left='{', right='}'))
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return pform
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def _latex(self, printer, *args):
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return "\\left\\{%s,%s\\right\\}" % tuple([
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printer._print(arg, *args) for arg in self.args])
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