229 lines
7.8 KiB
Python
229 lines
7.8 KiB
Python
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from sympy.core import S, oo, diff
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from sympy.core.function import Function, ArgumentIndexError
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from sympy.core.logic import fuzzy_not
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from sympy.core.relational import Eq
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from sympy.functions.elementary.complexes import im
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from sympy.functions.elementary.piecewise import Piecewise
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from sympy.functions.special.delta_functions import Heaviside
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###############################################################################
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############################# SINGULARITY FUNCTION ############################
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###############################################################################
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class SingularityFunction(Function):
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r"""
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Singularity functions are a class of discontinuous functions.
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Explanation
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===========
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Singularity functions take a variable, an offset, and an exponent as
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arguments. These functions are represented using Macaulay brackets as:
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SingularityFunction(x, a, n) := <x - a>^n
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The singularity function will automatically evaluate to
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``Derivative(DiracDelta(x - a), x, -n - 1)`` if ``n < 0``
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and ``(x - a)**n*Heaviside(x - a)`` if ``n >= 0``.
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Examples
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========
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>>> from sympy import SingularityFunction, diff, Piecewise, DiracDelta, Heaviside, Symbol
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>>> from sympy.abc import x, a, n
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>>> SingularityFunction(x, a, n)
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SingularityFunction(x, a, n)
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>>> y = Symbol('y', positive=True)
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>>> n = Symbol('n', nonnegative=True)
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>>> SingularityFunction(y, -10, n)
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(y + 10)**n
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>>> y = Symbol('y', negative=True)
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>>> SingularityFunction(y, 10, n)
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0
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>>> SingularityFunction(x, 4, -1).subs(x, 4)
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oo
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>>> SingularityFunction(x, 10, -2).subs(x, 10)
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oo
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>>> SingularityFunction(4, 1, 5)
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243
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>>> diff(SingularityFunction(x, 1, 5) + SingularityFunction(x, 1, 4), x)
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4*SingularityFunction(x, 1, 3) + 5*SingularityFunction(x, 1, 4)
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>>> diff(SingularityFunction(x, 4, 0), x, 2)
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SingularityFunction(x, 4, -2)
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>>> SingularityFunction(x, 4, 5).rewrite(Piecewise)
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Piecewise(((x - 4)**5, x > 4), (0, True))
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>>> expr = SingularityFunction(x, a, n)
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>>> y = Symbol('y', positive=True)
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>>> n = Symbol('n', nonnegative=True)
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>>> expr.subs({x: y, a: -10, n: n})
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(y + 10)**n
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The methods ``rewrite(DiracDelta)``, ``rewrite(Heaviside)``, and
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``rewrite('HeavisideDiracDelta')`` returns the same output. One can use any
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of these methods according to their choice.
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>>> expr = SingularityFunction(x, 4, 5) + SingularityFunction(x, -3, -1) - SingularityFunction(x, 0, -2)
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>>> expr.rewrite(Heaviside)
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(x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1)
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>>> expr.rewrite(DiracDelta)
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(x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1)
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>>> expr.rewrite('HeavisideDiracDelta')
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(x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1)
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See Also
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========
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DiracDelta, Heaviside
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Singularity_function
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"""
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is_real = True
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def fdiff(self, argindex=1):
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"""
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Returns the first derivative of a DiracDelta Function.
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Explanation
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===========
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The difference between ``diff()`` and ``fdiff()`` is: ``diff()`` is the
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user-level function and ``fdiff()`` is an object method. ``fdiff()`` is
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a convenience method available in the ``Function`` class. It returns
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the derivative of the function without considering the chain rule.
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``diff(function, x)`` calls ``Function._eval_derivative`` which in turn
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calls ``fdiff()`` internally to compute the derivative of the function.
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"""
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if argindex == 1:
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x, a, n = self.args
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if n in (S.Zero, S.NegativeOne):
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return self.func(x, a, n-1)
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elif n.is_positive:
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return n*self.func(x, a, n-1)
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else:
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raise ArgumentIndexError(self, argindex)
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@classmethod
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def eval(cls, variable, offset, exponent):
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"""
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Returns a simplified form or a value of Singularity Function depending
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on the argument passed by the object.
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Explanation
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===========
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The ``eval()`` method is automatically called when the
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``SingularityFunction`` class is about to be instantiated and it
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returns either some simplified instance or the unevaluated instance
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depending on the argument passed. In other words, ``eval()`` method is
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not needed to be called explicitly, it is being called and evaluated
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once the object is called.
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Examples
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========
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>>> from sympy import SingularityFunction, Symbol, nan
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>>> from sympy.abc import x, a, n
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>>> SingularityFunction(x, a, n)
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SingularityFunction(x, a, n)
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>>> SingularityFunction(5, 3, 2)
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4
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>>> SingularityFunction(x, a, nan)
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nan
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>>> SingularityFunction(x, 3, 0).subs(x, 3)
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1
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>>> SingularityFunction(4, 1, 5)
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243
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>>> x = Symbol('x', positive = True)
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>>> a = Symbol('a', negative = True)
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>>> n = Symbol('n', nonnegative = True)
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>>> SingularityFunction(x, a, n)
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(-a + x)**n
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>>> x = Symbol('x', negative = True)
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>>> a = Symbol('a', positive = True)
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>>> SingularityFunction(x, a, n)
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0
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"""
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x = variable
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a = offset
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n = exponent
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shift = (x - a)
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if fuzzy_not(im(shift).is_zero):
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raise ValueError("Singularity Functions are defined only for Real Numbers.")
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if fuzzy_not(im(n).is_zero):
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raise ValueError("Singularity Functions are not defined for imaginary exponents.")
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if shift is S.NaN or n is S.NaN:
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return S.NaN
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if (n + 2).is_negative:
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raise ValueError("Singularity Functions are not defined for exponents less than -2.")
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if shift.is_extended_negative:
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return S.Zero
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if n.is_nonnegative and shift.is_extended_nonnegative:
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return (x - a)**n
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if n in (S.NegativeOne, -2):
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if shift.is_negative or shift.is_extended_positive:
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return S.Zero
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if shift.is_zero:
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return oo
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def _eval_rewrite_as_Piecewise(self, *args, **kwargs):
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'''
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Converts a Singularity Function expression into its Piecewise form.
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'''
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x, a, n = self.args
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if n in (S.NegativeOne, S(-2)):
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return Piecewise((oo, Eq((x - a), 0)), (0, True))
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elif n.is_nonnegative:
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return Piecewise(((x - a)**n, (x - a) > 0), (0, True))
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def _eval_rewrite_as_Heaviside(self, *args, **kwargs):
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'''
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Rewrites a Singularity Function expression using Heavisides and DiracDeltas.
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'''
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x, a, n = self.args
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if n == -2:
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return diff(Heaviside(x - a), x.free_symbols.pop(), 2)
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if n == -1:
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return diff(Heaviside(x - a), x.free_symbols.pop(), 1)
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if n.is_nonnegative:
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return (x - a)**n*Heaviside(x - a)
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def _eval_as_leading_term(self, x, logx=None, cdir=0):
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z, a, n = self.args
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shift = (z - a).subs(x, 0)
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if n < 0:
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return S.Zero
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elif n.is_zero and shift.is_zero:
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return S.Zero if cdir == -1 else S.One
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elif shift.is_positive:
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return shift**n
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return S.Zero
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def _eval_nseries(self, x, n, logx=None, cdir=0):
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z, a, n = self.args
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shift = (z - a).subs(x, 0)
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if n < 0:
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return S.Zero
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elif n.is_zero and shift.is_zero:
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return S.Zero if cdir == -1 else S.One
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elif shift.is_positive:
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return ((z - a)**n)._eval_nseries(x, n, logx=logx, cdir=cdir)
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return S.Zero
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_eval_rewrite_as_DiracDelta = _eval_rewrite_as_Heaviside
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_eval_rewrite_as_HeavisideDiracDelta = _eval_rewrite_as_Heaviside
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