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1015 lines
30 KiB
1015 lines
30 KiB
"""Dirac notation for states."""
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from sympy.core.cache import cacheit
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from sympy.core.containers import Tuple
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from sympy.core.expr import Expr
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from sympy.core.function import Function
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from sympy.core.numbers import oo, equal_valued
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from sympy.core.singleton import S
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from sympy.functions.elementary.complexes import conjugate
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from sympy.functions.elementary.miscellaneous import sqrt
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from sympy.integrals.integrals import integrate
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from sympy.printing.pretty.stringpict import stringPict
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from sympy.physics.quantum.qexpr import QExpr, dispatch_method
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__all__ = [
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'KetBase',
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'BraBase',
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'StateBase',
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'State',
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'Ket',
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'Bra',
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'TimeDepState',
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'TimeDepBra',
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'TimeDepKet',
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'OrthogonalKet',
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'OrthogonalBra',
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'OrthogonalState',
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'Wavefunction'
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]
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#-----------------------------------------------------------------------------
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# States, bras and kets.
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#-----------------------------------------------------------------------------
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# ASCII brackets
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_lbracket = "<"
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_rbracket = ">"
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_straight_bracket = "|"
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# Unicode brackets
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# MATHEMATICAL ANGLE BRACKETS
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_lbracket_ucode = "\N{MATHEMATICAL LEFT ANGLE BRACKET}"
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_rbracket_ucode = "\N{MATHEMATICAL RIGHT ANGLE BRACKET}"
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# LIGHT VERTICAL BAR
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_straight_bracket_ucode = "\N{LIGHT VERTICAL BAR}"
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# Other options for unicode printing of <, > and | for Dirac notation.
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# LEFT-POINTING ANGLE BRACKET
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# _lbracket = "\u2329"
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# _rbracket = "\u232A"
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# LEFT ANGLE BRACKET
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# _lbracket = "\u3008"
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# _rbracket = "\u3009"
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# VERTICAL LINE
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# _straight_bracket = "\u007C"
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class StateBase(QExpr):
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"""Abstract base class for general abstract states in quantum mechanics.
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All other state classes defined will need to inherit from this class. It
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carries the basic structure for all other states such as dual, _eval_adjoint
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and label.
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This is an abstract base class and you should not instantiate it directly,
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instead use State.
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"""
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@classmethod
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def _operators_to_state(self, ops, **options):
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""" Returns the eigenstate instance for the passed operators.
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This method should be overridden in subclasses. It will handle being
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passed either an Operator instance or set of Operator instances. It
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should return the corresponding state INSTANCE or simply raise a
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NotImplementedError. See cartesian.py for an example.
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"""
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raise NotImplementedError("Cannot map operators to states in this class. Method not implemented!")
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def _state_to_operators(self, op_classes, **options):
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""" Returns the operators which this state instance is an eigenstate
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of.
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This method should be overridden in subclasses. It will be called on
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state instances and be passed the operator classes that we wish to make
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into instances. The state instance will then transform the classes
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appropriately, or raise a NotImplementedError if it cannot return
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operator instances. See cartesian.py for examples,
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"""
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raise NotImplementedError(
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"Cannot map this state to operators. Method not implemented!")
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@property
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def operators(self):
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"""Return the operator(s) that this state is an eigenstate of"""
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from .operatorset import state_to_operators # import internally to avoid circular import errors
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return state_to_operators(self)
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def _enumerate_state(self, num_states, **options):
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raise NotImplementedError("Cannot enumerate this state!")
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def _represent_default_basis(self, **options):
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return self._represent(basis=self.operators)
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#-------------------------------------------------------------------------
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# Dagger/dual
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#-------------------------------------------------------------------------
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@property
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def dual(self):
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"""Return the dual state of this one."""
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return self.dual_class()._new_rawargs(self.hilbert_space, *self.args)
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@classmethod
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def dual_class(self):
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"""Return the class used to construct the dual."""
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raise NotImplementedError(
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'dual_class must be implemented in a subclass'
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)
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def _eval_adjoint(self):
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"""Compute the dagger of this state using the dual."""
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return self.dual
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#-------------------------------------------------------------------------
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# Printing
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#-------------------------------------------------------------------------
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def _pretty_brackets(self, height, use_unicode=True):
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# Return pretty printed brackets for the state
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# Ideally, this could be done by pform.parens but it does not support the angled < and >
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# Setup for unicode vs ascii
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if use_unicode:
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lbracket, rbracket = getattr(self, 'lbracket_ucode', ""), getattr(self, 'rbracket_ucode', "")
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slash, bslash, vert = '\N{BOX DRAWINGS LIGHT DIAGONAL UPPER RIGHT TO LOWER LEFT}', \
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'\N{BOX DRAWINGS LIGHT DIAGONAL UPPER LEFT TO LOWER RIGHT}', \
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'\N{BOX DRAWINGS LIGHT VERTICAL}'
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else:
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lbracket, rbracket = getattr(self, 'lbracket', ""), getattr(self, 'rbracket', "")
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slash, bslash, vert = '/', '\\', '|'
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# If height is 1, just return brackets
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if height == 1:
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return stringPict(lbracket), stringPict(rbracket)
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# Make height even
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height += (height % 2)
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brackets = []
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for bracket in lbracket, rbracket:
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# Create left bracket
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if bracket in {_lbracket, _lbracket_ucode}:
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bracket_args = [ ' ' * (height//2 - i - 1) +
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slash for i in range(height // 2)]
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bracket_args.extend(
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[' ' * i + bslash for i in range(height // 2)])
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# Create right bracket
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elif bracket in {_rbracket, _rbracket_ucode}:
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bracket_args = [ ' ' * i + bslash for i in range(height // 2)]
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bracket_args.extend([ ' ' * (
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height//2 - i - 1) + slash for i in range(height // 2)])
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# Create straight bracket
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elif bracket in {_straight_bracket, _straight_bracket_ucode}:
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bracket_args = [vert] * height
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else:
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raise ValueError(bracket)
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brackets.append(
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stringPict('\n'.join(bracket_args), baseline=height//2))
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return brackets
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def _sympystr(self, printer, *args):
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contents = self._print_contents(printer, *args)
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return '%s%s%s' % (getattr(self, 'lbracket', ""), contents, getattr(self, 'rbracket', ""))
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def _pretty(self, printer, *args):
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from sympy.printing.pretty.stringpict import prettyForm
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# Get brackets
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pform = self._print_contents_pretty(printer, *args)
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lbracket, rbracket = self._pretty_brackets(
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pform.height(), printer._use_unicode)
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# Put together state
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pform = prettyForm(*pform.left(lbracket))
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pform = prettyForm(*pform.right(rbracket))
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return pform
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def _latex(self, printer, *args):
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contents = self._print_contents_latex(printer, *args)
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# The extra {} brackets are needed to get matplotlib's latex
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# rendered to render this properly.
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return '{%s%s%s}' % (getattr(self, 'lbracket_latex', ""), contents, getattr(self, 'rbracket_latex', ""))
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class KetBase(StateBase):
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"""Base class for Kets.
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This class defines the dual property and the brackets for printing. This is
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an abstract base class and you should not instantiate it directly, instead
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use Ket.
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"""
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lbracket = _straight_bracket
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rbracket = _rbracket
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lbracket_ucode = _straight_bracket_ucode
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rbracket_ucode = _rbracket_ucode
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lbracket_latex = r'\left|'
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rbracket_latex = r'\right\rangle '
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@classmethod
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def default_args(self):
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return ("psi",)
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@classmethod
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def dual_class(self):
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return BraBase
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def __mul__(self, other):
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"""KetBase*other"""
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from sympy.physics.quantum.operator import OuterProduct
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if isinstance(other, BraBase):
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return OuterProduct(self, other)
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else:
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return Expr.__mul__(self, other)
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def __rmul__(self, other):
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"""other*KetBase"""
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from sympy.physics.quantum.innerproduct import InnerProduct
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if isinstance(other, BraBase):
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return InnerProduct(other, self)
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else:
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return Expr.__rmul__(self, other)
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#-------------------------------------------------------------------------
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# _eval_* methods
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#-------------------------------------------------------------------------
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def _eval_innerproduct(self, bra, **hints):
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"""Evaluate the inner product between this ket and a bra.
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This is called to compute <bra|ket>, where the ket is ``self``.
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This method will dispatch to sub-methods having the format::
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``def _eval_innerproduct_BraClass(self, **hints):``
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Subclasses should define these methods (one for each BraClass) to
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teach the ket how to take inner products with bras.
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"""
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return dispatch_method(self, '_eval_innerproduct', bra, **hints)
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def _apply_from_right_to(self, op, **options):
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"""Apply an Operator to this Ket as Operator*Ket
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This method will dispatch to methods having the format::
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``def _apply_from_right_to_OperatorName(op, **options):``
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Subclasses should define these methods (one for each OperatorName) to
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teach the Ket how to implement OperatorName*Ket
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Parameters
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==========
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op : Operator
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The Operator that is acting on the Ket as op*Ket
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options : dict
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A dict of key/value pairs that control how the operator is applied
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to the Ket.
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"""
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return dispatch_method(self, '_apply_from_right_to', op, **options)
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class BraBase(StateBase):
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"""Base class for Bras.
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This class defines the dual property and the brackets for printing. This
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is an abstract base class and you should not instantiate it directly,
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instead use Bra.
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"""
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lbracket = _lbracket
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rbracket = _straight_bracket
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lbracket_ucode = _lbracket_ucode
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rbracket_ucode = _straight_bracket_ucode
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lbracket_latex = r'\left\langle '
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rbracket_latex = r'\right|'
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@classmethod
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def _operators_to_state(self, ops, **options):
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state = self.dual_class()._operators_to_state(ops, **options)
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return state.dual
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def _state_to_operators(self, op_classes, **options):
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return self.dual._state_to_operators(op_classes, **options)
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def _enumerate_state(self, num_states, **options):
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dual_states = self.dual._enumerate_state(num_states, **options)
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return [x.dual for x in dual_states]
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@classmethod
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def default_args(self):
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return self.dual_class().default_args()
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@classmethod
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def dual_class(self):
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return KetBase
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def __mul__(self, other):
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"""BraBase*other"""
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from sympy.physics.quantum.innerproduct import InnerProduct
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if isinstance(other, KetBase):
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return InnerProduct(self, other)
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else:
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return Expr.__mul__(self, other)
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def __rmul__(self, other):
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"""other*BraBase"""
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from sympy.physics.quantum.operator import OuterProduct
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if isinstance(other, KetBase):
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return OuterProduct(other, self)
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else:
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return Expr.__rmul__(self, other)
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def _represent(self, **options):
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"""A default represent that uses the Ket's version."""
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from sympy.physics.quantum.dagger import Dagger
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return Dagger(self.dual._represent(**options))
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class State(StateBase):
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"""General abstract quantum state used as a base class for Ket and Bra."""
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pass
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class Ket(State, KetBase):
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"""A general time-independent Ket in quantum mechanics.
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Inherits from State and KetBase. This class should be used as the base
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class for all physical, time-independent Kets in a system. This class
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and its subclasses will be the main classes that users will use for
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expressing Kets in Dirac notation [1]_.
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Parameters
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==========
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args : tuple
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The list of numbers or parameters that uniquely specify the
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ket. This will usually be its symbol or its quantum numbers. For
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time-dependent state, this will include the time.
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Examples
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========
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Create a simple Ket and looking at its properties::
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>>> from sympy.physics.quantum import Ket
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>>> from sympy import symbols, I
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>>> k = Ket('psi')
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>>> k
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|psi>
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>>> k.hilbert_space
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H
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>>> k.is_commutative
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False
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>>> k.label
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(psi,)
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Ket's know about their associated bra::
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>>> k.dual
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<psi|
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>>> k.dual_class()
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<class 'sympy.physics.quantum.state.Bra'>
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Take a linear combination of two kets::
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>>> k0 = Ket(0)
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>>> k1 = Ket(1)
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>>> 2*I*k0 - 4*k1
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2*I*|0> - 4*|1>
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Compound labels are passed as tuples::
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>>> n, m = symbols('n,m')
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>>> k = Ket(n,m)
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>>> k
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|nm>
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Bra-ket_notation
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"""
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@classmethod
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def dual_class(self):
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return Bra
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class Bra(State, BraBase):
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"""A general time-independent Bra in quantum mechanics.
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Inherits from State and BraBase. A Bra is the dual of a Ket [1]_. This
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class and its subclasses will be the main classes that users will use for
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expressing Bras in Dirac notation.
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Parameters
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==========
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args : tuple
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The list of numbers or parameters that uniquely specify the
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ket. This will usually be its symbol or its quantum numbers. For
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time-dependent state, this will include the time.
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Examples
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========
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Create a simple Bra and look at its properties::
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>>> from sympy.physics.quantum import Bra
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>>> from sympy import symbols, I
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>>> b = Bra('psi')
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>>> b
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<psi|
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>>> b.hilbert_space
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H
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>>> b.is_commutative
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False
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Bra's know about their dual Ket's::
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>>> b.dual
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|psi>
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>>> b.dual_class()
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<class 'sympy.physics.quantum.state.Ket'>
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Like Kets, Bras can have compound labels and be manipulated in a similar
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manner::
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>>> n, m = symbols('n,m')
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>>> b = Bra(n,m) - I*Bra(m,n)
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>>> b
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-I*<mn| + <nm|
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Symbols in a Bra can be substituted using ``.subs``::
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>>> b.subs(n,m)
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<mm| - I*<mm|
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Bra-ket_notation
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"""
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@classmethod
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def dual_class(self):
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return Ket
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#-----------------------------------------------------------------------------
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# Time dependent states, bras and kets.
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#-----------------------------------------------------------------------------
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class TimeDepState(StateBase):
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"""Base class for a general time-dependent quantum state.
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This class is used as a base class for any time-dependent state. The main
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difference between this class and the time-independent state is that this
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class takes a second argument that is the time in addition to the usual
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label argument.
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Parameters
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==========
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args : tuple
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The list of numbers or parameters that uniquely specify the ket. This
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will usually be its symbol or its quantum numbers. For time-dependent
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state, this will include the time as the final argument.
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"""
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#-------------------------------------------------------------------------
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# Initialization
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#-------------------------------------------------------------------------
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@classmethod
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def default_args(self):
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return ("psi", "t")
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#-------------------------------------------------------------------------
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# Properties
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#-------------------------------------------------------------------------
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@property
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def label(self):
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"""The label of the state."""
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return self.args[:-1]
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@property
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def time(self):
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"""The time of the state."""
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return self.args[-1]
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#-------------------------------------------------------------------------
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# Printing
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#-------------------------------------------------------------------------
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def _print_time(self, printer, *args):
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return printer._print(self.time, *args)
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_print_time_repr = _print_time
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_print_time_latex = _print_time
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def _print_time_pretty(self, printer, *args):
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pform = printer._print(self.time, *args)
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return pform
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def _print_contents(self, printer, *args):
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label = self._print_label(printer, *args)
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time = self._print_time(printer, *args)
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return '%s;%s' % (label, time)
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def _print_label_repr(self, printer, *args):
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label = self._print_sequence(self.label, ',', printer, *args)
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time = self._print_time_repr(printer, *args)
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return '%s,%s' % (label, time)
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def _print_contents_pretty(self, printer, *args):
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label = self._print_label_pretty(printer, *args)
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time = self._print_time_pretty(printer, *args)
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return printer._print_seq((label, time), delimiter=';')
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def _print_contents_latex(self, printer, *args):
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label = self._print_sequence(
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self.label, self._label_separator, printer, *args)
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time = self._print_time_latex(printer, *args)
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return '%s;%s' % (label, time)
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|
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class TimeDepKet(TimeDepState, KetBase):
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"""General time-dependent Ket in quantum mechanics.
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This inherits from ``TimeDepState`` and ``KetBase`` and is the main class
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that should be used for Kets that vary with time. Its dual is a
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``TimeDepBra``.
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Parameters
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==========
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args : tuple
|
|
The list of numbers or parameters that uniquely specify the ket. This
|
|
will usually be its symbol or its quantum numbers. For time-dependent
|
|
state, this will include the time as the final argument.
|
|
|
|
Examples
|
|
========
|
|
|
|
Create a TimeDepKet and look at its attributes::
|
|
|
|
>>> from sympy.physics.quantum import TimeDepKet
|
|
>>> k = TimeDepKet('psi', 't')
|
|
>>> k
|
|
|psi;t>
|
|
>>> k.time
|
|
t
|
|
>>> k.label
|
|
(psi,)
|
|
>>> k.hilbert_space
|
|
H
|
|
|
|
TimeDepKets know about their dual bra::
|
|
|
|
>>> k.dual
|
|
<psi;t|
|
|
>>> k.dual_class()
|
|
<class 'sympy.physics.quantum.state.TimeDepBra'>
|
|
"""
|
|
|
|
@classmethod
|
|
def dual_class(self):
|
|
return TimeDepBra
|
|
|
|
|
|
class TimeDepBra(TimeDepState, BraBase):
|
|
"""General time-dependent Bra in quantum mechanics.
|
|
|
|
This inherits from TimeDepState and BraBase and is the main class that
|
|
should be used for Bras that vary with time. Its dual is a TimeDepBra.
|
|
|
|
Parameters
|
|
==========
|
|
|
|
args : tuple
|
|
The list of numbers or parameters that uniquely specify the ket. This
|
|
will usually be its symbol or its quantum numbers. For time-dependent
|
|
state, this will include the time as the final argument.
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy.physics.quantum import TimeDepBra
|
|
>>> b = TimeDepBra('psi', 't')
|
|
>>> b
|
|
<psi;t|
|
|
>>> b.time
|
|
t
|
|
>>> b.label
|
|
(psi,)
|
|
>>> b.hilbert_space
|
|
H
|
|
>>> b.dual
|
|
|psi;t>
|
|
"""
|
|
|
|
@classmethod
|
|
def dual_class(self):
|
|
return TimeDepKet
|
|
|
|
|
|
class OrthogonalState(State, StateBase):
|
|
"""General abstract quantum state used as a base class for Ket and Bra."""
|
|
pass
|
|
|
|
class OrthogonalKet(OrthogonalState, KetBase):
|
|
"""Orthogonal Ket in quantum mechanics.
|
|
|
|
The inner product of two states with different labels will give zero,
|
|
states with the same label will give one.
|
|
|
|
>>> from sympy.physics.quantum import OrthogonalBra, OrthogonalKet
|
|
>>> from sympy.abc import m, n
|
|
>>> (OrthogonalBra(n)*OrthogonalKet(n)).doit()
|
|
1
|
|
>>> (OrthogonalBra(n)*OrthogonalKet(n+1)).doit()
|
|
0
|
|
>>> (OrthogonalBra(n)*OrthogonalKet(m)).doit()
|
|
<n|m>
|
|
"""
|
|
|
|
@classmethod
|
|
def dual_class(self):
|
|
return OrthogonalBra
|
|
|
|
def _eval_innerproduct(self, bra, **hints):
|
|
|
|
if len(self.args) != len(bra.args):
|
|
raise ValueError('Cannot multiply a ket that has a different number of labels.')
|
|
|
|
for arg, bra_arg in zip(self.args, bra.args):
|
|
diff = arg - bra_arg
|
|
diff = diff.expand()
|
|
|
|
is_zero = diff.is_zero
|
|
|
|
if is_zero is False:
|
|
return S.Zero # i.e. Integer(0)
|
|
|
|
if is_zero is None:
|
|
return None
|
|
|
|
return S.One # i.e. Integer(1)
|
|
|
|
|
|
class OrthogonalBra(OrthogonalState, BraBase):
|
|
"""Orthogonal Bra in quantum mechanics.
|
|
"""
|
|
|
|
@classmethod
|
|
def dual_class(self):
|
|
return OrthogonalKet
|
|
|
|
|
|
class Wavefunction(Function):
|
|
"""Class for representations in continuous bases
|
|
|
|
This class takes an expression and coordinates in its constructor. It can
|
|
be used to easily calculate normalizations and probabilities.
|
|
|
|
Parameters
|
|
==========
|
|
|
|
expr : Expr
|
|
The expression representing the functional form of the w.f.
|
|
|
|
coords : Symbol or tuple
|
|
The coordinates to be integrated over, and their bounds
|
|
|
|
Examples
|
|
========
|
|
|
|
Particle in a box, specifying bounds in the more primitive way of using
|
|
Piecewise:
|
|
|
|
>>> from sympy import Symbol, Piecewise, pi, N
|
|
>>> from sympy.functions import sqrt, sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x = Symbol('x', real=True)
|
|
>>> n = 1
|
|
>>> L = 1
|
|
>>> g = Piecewise((0, x < 0), (0, x > L), (sqrt(2//L)*sin(n*pi*x/L), True))
|
|
>>> f = Wavefunction(g, x)
|
|
>>> f.norm
|
|
1
|
|
>>> f.is_normalized
|
|
True
|
|
>>> p = f.prob()
|
|
>>> p(0)
|
|
0
|
|
>>> p(L)
|
|
0
|
|
>>> p(0.5)
|
|
2
|
|
>>> p(0.85*L)
|
|
2*sin(0.85*pi)**2
|
|
>>> N(p(0.85*L))
|
|
0.412214747707527
|
|
|
|
Additionally, you can specify the bounds of the function and the indices in
|
|
a more compact way:
|
|
|
|
>>> from sympy import symbols, pi, diff
|
|
>>> from sympy.functions import sqrt, sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x, L = symbols('x,L', positive=True)
|
|
>>> n = symbols('n', integer=True, positive=True)
|
|
>>> g = sqrt(2/L)*sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.norm
|
|
1
|
|
>>> f(L+1)
|
|
0
|
|
>>> f(L-1)
|
|
sqrt(2)*sin(pi*n*(L - 1)/L)/sqrt(L)
|
|
>>> f(-1)
|
|
0
|
|
>>> f(0.85)
|
|
sqrt(2)*sin(0.85*pi*n/L)/sqrt(L)
|
|
>>> f(0.85, n=1, L=1)
|
|
sqrt(2)*sin(0.85*pi)
|
|
>>> f.is_commutative
|
|
False
|
|
|
|
All arguments are automatically sympified, so you can define the variables
|
|
as strings rather than symbols:
|
|
|
|
>>> expr = x**2
|
|
>>> f = Wavefunction(expr, 'x')
|
|
>>> type(f.variables[0])
|
|
<class 'sympy.core.symbol.Symbol'>
|
|
|
|
Derivatives of Wavefunctions will return Wavefunctions:
|
|
|
|
>>> diff(f, x)
|
|
Wavefunction(2*x, x)
|
|
|
|
"""
|
|
|
|
#Any passed tuples for coordinates and their bounds need to be
|
|
#converted to Tuples before Function's constructor is called, to
|
|
#avoid errors from calling is_Float in the constructor
|
|
def __new__(cls, *args, **options):
|
|
new_args = [None for i in args]
|
|
ct = 0
|
|
for arg in args:
|
|
if isinstance(arg, tuple):
|
|
new_args[ct] = Tuple(*arg)
|
|
else:
|
|
new_args[ct] = arg
|
|
ct += 1
|
|
|
|
return super().__new__(cls, *new_args, **options)
|
|
|
|
def __call__(self, *args, **options):
|
|
var = self.variables
|
|
|
|
if len(args) != len(var):
|
|
raise NotImplementedError(
|
|
"Incorrect number of arguments to function!")
|
|
|
|
ct = 0
|
|
#If the passed value is outside the specified bounds, return 0
|
|
for v in var:
|
|
lower, upper = self.limits[v]
|
|
|
|
#Do the comparison to limits only if the passed symbol is actually
|
|
#a symbol present in the limits;
|
|
#Had problems with a comparison of x > L
|
|
if isinstance(args[ct], Expr) and \
|
|
not (lower in args[ct].free_symbols
|
|
or upper in args[ct].free_symbols):
|
|
continue
|
|
|
|
if (args[ct] < lower) == True or (args[ct] > upper) == True:
|
|
return S.Zero
|
|
|
|
ct += 1
|
|
|
|
expr = self.expr
|
|
|
|
#Allows user to make a call like f(2, 4, m=1, n=1)
|
|
for symbol in list(expr.free_symbols):
|
|
if str(symbol) in options.keys():
|
|
val = options[str(symbol)]
|
|
expr = expr.subs(symbol, val)
|
|
|
|
return expr.subs(zip(var, args))
|
|
|
|
def _eval_derivative(self, symbol):
|
|
expr = self.expr
|
|
deriv = expr._eval_derivative(symbol)
|
|
|
|
return Wavefunction(deriv, *self.args[1:])
|
|
|
|
def _eval_conjugate(self):
|
|
return Wavefunction(conjugate(self.expr), *self.args[1:])
|
|
|
|
def _eval_transpose(self):
|
|
return self
|
|
|
|
@property
|
|
def free_symbols(self):
|
|
return self.expr.free_symbols
|
|
|
|
@property
|
|
def is_commutative(self):
|
|
"""
|
|
Override Function's is_commutative so that order is preserved in
|
|
represented expressions
|
|
"""
|
|
return False
|
|
|
|
@classmethod
|
|
def eval(self, *args):
|
|
return None
|
|
|
|
@property
|
|
def variables(self):
|
|
"""
|
|
Return the coordinates which the wavefunction depends on
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> from sympy import symbols
|
|
>>> x,y = symbols('x,y')
|
|
>>> f = Wavefunction(x*y, x, y)
|
|
>>> f.variables
|
|
(x, y)
|
|
>>> g = Wavefunction(x*y, x)
|
|
>>> g.variables
|
|
(x,)
|
|
|
|
"""
|
|
var = [g[0] if isinstance(g, Tuple) else g for g in self._args[1:]]
|
|
return tuple(var)
|
|
|
|
@property
|
|
def limits(self):
|
|
"""
|
|
Return the limits of the coordinates which the w.f. depends on If no
|
|
limits are specified, defaults to ``(-oo, oo)``.
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> from sympy import symbols
|
|
>>> x, y = symbols('x, y')
|
|
>>> f = Wavefunction(x**2, (x, 0, 1))
|
|
>>> f.limits
|
|
{x: (0, 1)}
|
|
>>> f = Wavefunction(x**2, x)
|
|
>>> f.limits
|
|
{x: (-oo, oo)}
|
|
>>> f = Wavefunction(x**2 + y**2, x, (y, -1, 2))
|
|
>>> f.limits
|
|
{x: (-oo, oo), y: (-1, 2)}
|
|
|
|
"""
|
|
limits = [(g[1], g[2]) if isinstance(g, Tuple) else (-oo, oo)
|
|
for g in self._args[1:]]
|
|
return dict(zip(self.variables, tuple(limits)))
|
|
|
|
@property
|
|
def expr(self):
|
|
"""
|
|
Return the expression which is the functional form of the Wavefunction
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> from sympy import symbols
|
|
>>> x, y = symbols('x, y')
|
|
>>> f = Wavefunction(x**2, x)
|
|
>>> f.expr
|
|
x**2
|
|
|
|
"""
|
|
return self._args[0]
|
|
|
|
@property
|
|
def is_normalized(self):
|
|
"""
|
|
Returns true if the Wavefunction is properly normalized
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy import symbols, pi
|
|
>>> from sympy.functions import sqrt, sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x, L = symbols('x,L', positive=True)
|
|
>>> n = symbols('n', integer=True, positive=True)
|
|
>>> g = sqrt(2/L)*sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.is_normalized
|
|
True
|
|
|
|
"""
|
|
|
|
return equal_valued(self.norm, 1)
|
|
|
|
@property # type: ignore
|
|
@cacheit
|
|
def norm(self):
|
|
"""
|
|
Return the normalization of the specified functional form.
|
|
|
|
This function integrates over the coordinates of the Wavefunction, with
|
|
the bounds specified.
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy import symbols, pi
|
|
>>> from sympy.functions import sqrt, sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x, L = symbols('x,L', positive=True)
|
|
>>> n = symbols('n', integer=True, positive=True)
|
|
>>> g = sqrt(2/L)*sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.norm
|
|
1
|
|
>>> g = sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.norm
|
|
sqrt(2)*sqrt(L)/2
|
|
|
|
"""
|
|
|
|
exp = self.expr*conjugate(self.expr)
|
|
var = self.variables
|
|
limits = self.limits
|
|
|
|
for v in var:
|
|
curr_limits = limits[v]
|
|
exp = integrate(exp, (v, curr_limits[0], curr_limits[1]))
|
|
|
|
return sqrt(exp)
|
|
|
|
def normalize(self):
|
|
"""
|
|
Return a normalized version of the Wavefunction
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy import symbols, pi
|
|
>>> from sympy.functions import sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x = symbols('x', real=True)
|
|
>>> L = symbols('L', positive=True)
|
|
>>> n = symbols('n', integer=True, positive=True)
|
|
>>> g = sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.normalize()
|
|
Wavefunction(sqrt(2)*sin(pi*n*x/L)/sqrt(L), (x, 0, L))
|
|
|
|
"""
|
|
const = self.norm
|
|
|
|
if const is oo:
|
|
raise NotImplementedError("The function is not normalizable!")
|
|
else:
|
|
return Wavefunction((const)**(-1)*self.expr, *self.args[1:])
|
|
|
|
def prob(self):
|
|
r"""
|
|
Return the absolute magnitude of the w.f., `|\psi(x)|^2`
|
|
|
|
Examples
|
|
========
|
|
|
|
>>> from sympy import symbols, pi
|
|
>>> from sympy.functions import sin
|
|
>>> from sympy.physics.quantum.state import Wavefunction
|
|
>>> x, L = symbols('x,L', real=True)
|
|
>>> n = symbols('n', integer=True)
|
|
>>> g = sin(n*pi*x/L)
|
|
>>> f = Wavefunction(g, (x, 0, L))
|
|
>>> f.prob()
|
|
Wavefunction(sin(pi*n*x/L)**2, x)
|
|
|
|
"""
|
|
|
|
return Wavefunction(self.expr*conjugate(self.expr), *self.variables)
|