a RG5d<ã@stddlmZmZmZddlmZmZddlmZddl m Z ddlmZddl mZddlmZGdd „d eƒZd S)é)ÚSÚooÚdiff)ÚFunctionÚArgumentIndexError)Ú fuzzy_not)ÚEq)Úim)Ú Piecewise)Ú Heavisidec@sVeZdZdZdZddd„Zedd„ƒZdd „Zd d„Z ddd„Z ddd„Ze Ze Z dS)ÚSingularityFunctionaH Singularity functions are a class of discontinuous functions. Explanation =========== Singularity functions take a variable, an offset, and an exponent as arguments. These functions are represented using Macaulay brackets as: SingularityFunction(x, a, n) := ^n The singularity function will automatically evaluate to ``Derivative(DiracDelta(x - a), x, -n - 1)`` if ``n < 0`` and ``(x - a)**n*Heaviside(x - a)`` if ``n >= 0``. Examples ======== >>> from sympy import SingularityFunction, diff, Piecewise, DiracDelta, Heaviside, Symbol >>> from sympy.abc import x, a, n >>> SingularityFunction(x, a, n) SingularityFunction(x, a, n) >>> y = Symbol('y', positive=True) >>> n = Symbol('n', nonnegative=True) >>> SingularityFunction(y, -10, n) (y + 10)**n >>> y = Symbol('y', negative=True) >>> SingularityFunction(y, 10, n) 0 >>> SingularityFunction(x, 4, -1).subs(x, 4) oo >>> SingularityFunction(x, 10, -2).subs(x, 10) oo >>> SingularityFunction(4, 1, 5) 243 >>> diff(SingularityFunction(x, 1, 5) + SingularityFunction(x, 1, 4), x) 4*SingularityFunction(x, 1, 3) + 5*SingularityFunction(x, 1, 4) >>> diff(SingularityFunction(x, 4, 0), x, 2) SingularityFunction(x, 4, -2) >>> SingularityFunction(x, 4, 5).rewrite(Piecewise) Piecewise(((x - 4)**5, x > 4), (0, True)) >>> expr = SingularityFunction(x, a, n) >>> y = Symbol('y', positive=True) >>> n = Symbol('n', nonnegative=True) >>> expr.subs({x: y, a: -10, n: n}) (y + 10)**n The methods ``rewrite(DiracDelta)``, ``rewrite(Heaviside)``, and ``rewrite('HeavisideDiracDelta')`` returns the same output. One can use any of these methods according to their choice. >>> expr = SingularityFunction(x, 4, 5) + SingularityFunction(x, -3, -1) - SingularityFunction(x, 0, -2) >>> expr.rewrite(Heaviside) (x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1) >>> expr.rewrite(DiracDelta) (x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1) >>> expr.rewrite('HeavisideDiracDelta') (x - 4)**5*Heaviside(x - 4) + DiracDelta(x + 3) - DiracDelta(x, 1) See Also ======== DiracDelta, Heaviside References ========== .. [1] https://en.wikipedia.org/wiki/Singularity_function TécCsb|dkrT|j\}}}|tjtjfvr6| |||d¡S|jr^|| |||d¡Sn t||ƒ‚dS)aK Returns the first derivative of a DiracDelta Function. Explanation =========== The difference between ``diff()`` and ``fdiff()`` is: ``diff()`` is the user-level function and ``fdiff()`` is an object method. ``fdiff()`` is a convenience method available in the ``Function`` class. It returns the derivative of the function without considering the chain rule. ``diff(function, x)`` calls ``Function._eval_derivative`` which in turn calls ``fdiff()`` internally to compute the derivative of the function. r N)ÚargsrÚZeroÚNegativeOneÚfuncÚis_positiver)ÚselfÚargindexÚxÚaÚn©rúi/var/www/html/django/DPS/env/lib/python3.9/site-packages/sympy/functions/special/singularity_functions.pyÚfdiffXszSingularityFunction.fdiffcCsÀ|}|}|}||}tt|ƒjƒr*tdƒ‚tt|ƒjƒr@tdƒ‚|tjusT|tjurZtjS|djrltdƒ‚|jrxtjS|j r|j r|||S|tjdfvr¼|jsª|jr°tjS|jr¼tj SdS)aP Returns a simplified form or a value of Singularity Function depending on the argument passed by the object. Explanation =========== The ``eval()`` method is automatically called when the ``SingularityFunction`` class is about to be instantiated and it returns either some simplified instance or the unevaluated instance depending on the argument passed. In other words, ``eval()`` method is not needed to be called explicitly, it is being called and evaluated once the object is called. Examples ======== >>> from sympy import SingularityFunction, Symbol, nan >>> from sympy.abc import x, a, n >>> SingularityFunction(x, a, n) SingularityFunction(x, a, n) >>> SingularityFunction(5, 3, 2) 4 >>> SingularityFunction(x, a, nan) nan >>> SingularityFunction(x, 3, 0).subs(x, 3) 1 >>> SingularityFunction(4, 1, 5) 243 >>> x = Symbol('x', positive = True) >>> a = Symbol('a', negative = True) >>> n = Symbol('n', nonnegative = True) >>> SingularityFunction(x, a, n) (-a + x)**n >>> x = Symbol('x', negative = True) >>> a = Symbol('a', positive = True) >>> SingularityFunction(x, a, n) 0 z8Singularity Functions are defined only for Real Numbers.z>Singularity Functions are not defined for imaginary exponents.ézASingularity Functions are not defined for exponents less than -2.éþÿÿÿN)rr Úis_zeroÚ ValueErrorrÚNaNÚis_negativeÚis_extended_negativerÚis_nonnegativeÚis_extended_nonnegativerÚis_extended_positiveÚInfinity)ÚclsÚvariableÚoffsetÚexponentrrrÚshiftrrrÚevalqs*+ zSingularityFunction.evalcOs^|j\}}}|tjtdƒfvr6ttt||dƒfdƒS|jrZt|||||dkfdƒSdS)zV Converts a Singularity Function expression into its Piecewise form. rr)rTN)rrrr rrr"©rrÚkwargsrrrrrrÚ_eval_rewrite_as_Piecewise³s z.SingularityFunction._eval_rewrite_as_PiecewisecOsr|j\}}}|dkr.tt||ƒ|j ¡dƒS|dkrPtt||ƒ|j ¡dƒS|jrn|||t||ƒSdS)z_ Rewrites a Singularity Function expression using Heavisides and DiracDeltas. rréÿÿÿÿr N)rrrÚfree_symbolsÚpopr"r,rrrÚ_eval_rewrite_as_Heaviside¿sz.SingularityFunction._eval_rewrite_as_HeavisideNrcCs^|j\}}}|| |d¡}|dkr*tjS|jrJ|jrJ|dkrDtjStjS|jrX||StjS)Nrr/)rÚsubsrrrÚOner)rrÚlogxÚcdirÚzrrr*rrrÚ_eval_as_leading_termÍsz)SingularityFunction._eval_as_leading_termcCsp|j\}}}|| |d¡}|dkr*tjS|jrJ|jrJ|dkrDtjStjS|jrj|||j||||dStjS)Nrr/)r5r6)rr3rrrr4rÚ _eval_nseries)rrrr5r6r7rr*rrrr9Øsz!SingularityFunction._eval_nseries)r )Nr)Nr)Ú__name__Ú __module__Ú__qualname__Ú__doc__Úis_realrÚclassmethodr+r.r2r8r9Z_eval_rewrite_as_DiracDeltaZ$_eval_rewrite_as_HeavisideDiracDeltarrrrrsG A rN)Ú sympy.corerrrÚsympy.core.functionrrÚsympy.core.logicrÚsympy.core.relationalrÚ$sympy.functions.elementary.complexesr Ú$sympy.functions.elementary.piecewiser Ú'sympy.functions.special.delta_functionsrrrrrrÚs