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474 lines
17 KiB
474 lines
17 KiB
5 months ago
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"""Various algorithms for helping identifying numbers and sequences."""
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from sympy.concrete.products import (Product, product)
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from sympy.core import Function, S
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from sympy.core.add import Add
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from sympy.core.numbers import Integer, Rational
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from sympy.core.symbol import Symbol, symbols
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from sympy.core.sympify import sympify
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from sympy.functions.elementary.exponential import exp
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from sympy.functions.elementary.integers import floor
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from sympy.integrals.integrals import integrate
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from sympy.polys.polyfuncs import rational_interpolate as rinterp
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from sympy.polys.polytools import lcm
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from sympy.simplify.radsimp import denom
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from sympy.utilities import public
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@public
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def find_simple_recurrence_vector(l):
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"""
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This function is used internally by other functions from the
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sympy.concrete.guess module. While most users may want to rather use the
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function find_simple_recurrence when looking for recurrence relations
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among rational numbers, the current function may still be useful when
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some post-processing has to be done.
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Explanation
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===========
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The function returns a vector of length n when a recurrence relation of
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order n is detected in the sequence of rational numbers v.
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If the returned vector has a length 1, then the returned value is always
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the list [0], which means that no relation has been found.
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While the functions is intended to be used with rational numbers, it should
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work for other kinds of real numbers except for some cases involving
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quadratic numbers; for that reason it should be used with some caution when
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the argument is not a list of rational numbers.
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Examples
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========
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>>> from sympy.concrete.guess import find_simple_recurrence_vector
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>>> from sympy import fibonacci
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>>> find_simple_recurrence_vector([fibonacci(k) for k in range(12)])
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[1, -1, -1]
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See Also
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========
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See the function sympy.concrete.guess.find_simple_recurrence which is more
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user-friendly.
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"""
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q1 = [0]
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q2 = [1]
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b, z = 0, len(l) >> 1
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while len(q2) <= z:
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while l[b]==0:
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b += 1
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if b == len(l):
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c = 1
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for x in q2:
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c = lcm(c, denom(x))
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if q2[0]*c < 0: c = -c
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for k in range(len(q2)):
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q2[k] = int(q2[k]*c)
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return q2
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a = S.One/l[b]
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m = [a]
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for k in range(b+1, len(l)):
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m.append(-sum(l[j+1]*m[b-j-1] for j in range(b, k))*a)
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l, m = m, [0] * max(len(q2), b+len(q1))
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for k, q in enumerate(q2):
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m[k] = a*q
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for k, q in enumerate(q1):
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m[k+b] += q
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while m[-1]==0: m.pop() # because trailing zeros can occur
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q1, q2, b = q2, m, 1
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return [0]
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@public
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def find_simple_recurrence(v, A=Function('a'), N=Symbol('n')):
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"""
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Detects and returns a recurrence relation from a sequence of several integer
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(or rational) terms. The name of the function in the returned expression is
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'a' by default; the main variable is 'n' by default. The smallest index in
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the returned expression is always n (and never n-1, n-2, etc.).
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Examples
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========
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>>> from sympy.concrete.guess import find_simple_recurrence
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>>> from sympy import fibonacci
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>>> find_simple_recurrence([fibonacci(k) for k in range(12)])
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-a(n) - a(n + 1) + a(n + 2)
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>>> from sympy import Function, Symbol
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>>> a = [1, 1, 1]
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>>> for k in range(15): a.append(5*a[-1]-3*a[-2]+8*a[-3])
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>>> find_simple_recurrence(a, A=Function('f'), N=Symbol('i'))
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-8*f(i) + 3*f(i + 1) - 5*f(i + 2) + f(i + 3)
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"""
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p = find_simple_recurrence_vector(v)
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n = len(p)
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if n <= 1: return S.Zero
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return Add(*[A(N+n-1-k)*p[k] for k in range(n)])
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@public
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def rationalize(x, maxcoeff=10000):
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"""
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Helps identifying a rational number from a float (or mpmath.mpf) value by
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using a continued fraction. The algorithm stops as soon as a large partial
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quotient is detected (greater than 10000 by default).
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Examples
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========
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>>> from sympy.concrete.guess import rationalize
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>>> from mpmath import cos, pi
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>>> rationalize(cos(pi/3))
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1/2
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>>> from mpmath import mpf
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>>> rationalize(mpf("0.333333333333333"))
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1/3
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While the function is rather intended to help 'identifying' rational
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values, it may be used in some cases for approximating real numbers.
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(Though other functions may be more relevant in that case.)
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>>> rationalize(pi, maxcoeff = 250)
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355/113
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See Also
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========
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Several other methods can approximate a real number as a rational, like:
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* fractions.Fraction.from_decimal
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* fractions.Fraction.from_float
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* mpmath.identify
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* mpmath.pslq by using the following syntax: mpmath.pslq([x, 1])
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* mpmath.findpoly by using the following syntax: mpmath.findpoly(x, 1)
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* sympy.simplify.nsimplify (which is a more general function)
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The main difference between the current function and all these variants is
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that control focuses on magnitude of partial quotients here rather than on
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global precision of the approximation. If the real is "known to be" a
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rational number, the current function should be able to detect it correctly
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with the default settings even when denominator is great (unless its
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expansion contains unusually big partial quotients) which may occur
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when studying sequences of increasing numbers. If the user cares more
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on getting simple fractions, other methods may be more convenient.
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"""
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p0, p1 = 0, 1
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q0, q1 = 1, 0
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a = floor(x)
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while a < maxcoeff or q1==0:
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p = a*p1 + p0
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q = a*q1 + q0
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p0, p1 = p1, p
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q0, q1 = q1, q
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if x==a: break
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x = 1/(x-a)
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a = floor(x)
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return sympify(p) / q
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@public
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def guess_generating_function_rational(v, X=Symbol('x')):
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"""
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Tries to "guess" a rational generating function for a sequence of rational
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numbers v.
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Examples
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========
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>>> from sympy.concrete.guess import guess_generating_function_rational
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>>> from sympy import fibonacci
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>>> l = [fibonacci(k) for k in range(5,15)]
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>>> guess_generating_function_rational(l)
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(3*x + 5)/(-x**2 - x + 1)
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See Also
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========
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sympy.series.approximants
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mpmath.pade
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"""
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# a) compute the denominator as q
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q = find_simple_recurrence_vector(v)
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n = len(q)
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if n <= 1: return None
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# b) compute the numerator as p
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p = [sum(v[i-k]*q[k] for k in range(min(i+1, n)))
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for i in range(len(v)>>1)]
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return (sum(p[k]*X**k for k in range(len(p)))
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/ sum(q[k]*X**k for k in range(n)))
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@public
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def guess_generating_function(v, X=Symbol('x'), types=['all'], maxsqrtn=2):
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"""
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Tries to "guess" a generating function for a sequence of rational numbers v.
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Only a few patterns are implemented yet.
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Explanation
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===========
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The function returns a dictionary where keys are the name of a given type of
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generating function. Six types are currently implemented:
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type | formal definition
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-------+----------------------------------------------------------------
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ogf | f(x) = Sum( a_k * x^k , k: 0..infinity )
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egf | f(x) = Sum( a_k * x^k / k! , k: 0..infinity )
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lgf | f(x) = Sum( (-1)^(k+1) a_k * x^k / k , k: 1..infinity )
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| (with initial index being hold as 1 rather than 0)
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hlgf | f(x) = Sum( a_k * x^k / k , k: 1..infinity )
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| (with initial index being hold as 1 rather than 0)
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lgdogf | f(x) = derivate( log(Sum( a_k * x^k, k: 0..infinity )), x)
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lgdegf | f(x) = derivate( log(Sum( a_k * x^k / k!, k: 0..infinity )), x)
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In order to spare time, the user can select only some types of generating
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functions (default being ['all']). While forgetting to use a list in the
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case of a single type may seem to work most of the time as in: types='ogf'
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this (convenient) syntax may lead to unexpected extra results in some cases.
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Discarding a type when calling the function does not mean that the type will
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not be present in the returned dictionary; it only means that no extra
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computation will be performed for that type, but the function may still add
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it in the result when it can be easily converted from another type.
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Two generating functions (lgdogf and lgdegf) are not even computed if the
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initial term of the sequence is 0; it may be useful in that case to try
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again after having removed the leading zeros.
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Examples
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========
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>>> from sympy.concrete.guess import guess_generating_function as ggf
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>>> ggf([k+1 for k in range(12)], types=['ogf', 'lgf', 'hlgf'])
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{'hlgf': 1/(1 - x), 'lgf': 1/(x + 1), 'ogf': 1/(x**2 - 2*x + 1)}
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>>> from sympy import sympify
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>>> l = sympify("[3/2, 11/2, 0, -121/2, -363/2, 121]")
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>>> ggf(l)
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{'ogf': (x + 3/2)/(11*x**2 - 3*x + 1)}
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>>> from sympy import fibonacci
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>>> ggf([fibonacci(k) for k in range(5, 15)], types=['ogf'])
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{'ogf': (3*x + 5)/(-x**2 - x + 1)}
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>>> from sympy import factorial
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>>> ggf([factorial(k) for k in range(12)], types=['ogf', 'egf', 'lgf'])
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{'egf': 1/(1 - x)}
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>>> ggf([k+1 for k in range(12)], types=['egf'])
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{'egf': (x + 1)*exp(x), 'lgdegf': (x + 2)/(x + 1)}
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N-th root of a rational function can also be detected (below is an example
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coming from the sequence A108626 from https://oeis.org).
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The greatest n-th root to be tested is specified as maxsqrtn (default 2).
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>>> ggf([1, 2, 5, 14, 41, 124, 383, 1200, 3799, 12122, 38919])['ogf']
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sqrt(1/(x**4 + 2*x**2 - 4*x + 1))
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References
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==========
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.. [1] "Concrete Mathematics", R.L. Graham, D.E. Knuth, O. Patashnik
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.. [2] https://oeis.org/wiki/Generating_functions
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"""
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# List of all types of all g.f. known by the algorithm
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if 'all' in types:
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types = ('ogf', 'egf', 'lgf', 'hlgf', 'lgdogf', 'lgdegf')
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result = {}
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# Ordinary Generating Function (ogf)
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if 'ogf' in types:
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(v) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*v[i] for i in range(n+1)) for n in range(len(v))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['ogf'] = g**Rational(1, d+1)
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break
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# Exponential Generating Function (egf)
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if 'egf' in types:
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# Transform sequence (division by factorial)
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w, f = [], S.One
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for i, k in enumerate(v):
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f *= i if i else 1
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w.append(k/f)
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(w) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*w[i] for i in range(n+1)) for n in range(len(w))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['egf'] = g**Rational(1, d+1)
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break
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# Logarithmic Generating Function (lgf)
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if 'lgf' in types:
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# Transform sequence (multiplication by (-1)^(n+1) / n)
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w, f = [], S.NegativeOne
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for i, k in enumerate(v):
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f = -f
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w.append(f*k/Integer(i+1))
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(w) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*w[i] for i in range(n+1)) for n in range(len(w))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['lgf'] = g**Rational(1, d+1)
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break
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# Hyperbolic logarithmic Generating Function (hlgf)
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if 'hlgf' in types:
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# Transform sequence (division by n+1)
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w = []
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for i, k in enumerate(v):
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w.append(k/Integer(i+1))
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(w) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*w[i] for i in range(n+1)) for n in range(len(w))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['hlgf'] = g**Rational(1, d+1)
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break
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# Logarithmic derivative of ordinary generating Function (lgdogf)
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if v[0] != 0 and ('lgdogf' in types
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or ('ogf' in types and 'ogf' not in result)):
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# Transform sequence by computing f'(x)/f(x)
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# because log(f(x)) = integrate( f'(x)/f(x) )
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a, w = sympify(v[0]), []
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for n in range(len(v)-1):
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w.append(
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(v[n+1]*(n+1) - sum(w[-i-1]*v[i+1] for i in range(n)))/a)
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(w) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*w[i] for i in range(n+1)) for n in range(len(w))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['lgdogf'] = g**Rational(1, d+1)
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if 'ogf' not in result:
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result['ogf'] = exp(integrate(result['lgdogf'], X))
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break
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# Logarithmic derivative of exponential generating Function (lgdegf)
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if v[0] != 0 and ('lgdegf' in types
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or ('egf' in types and 'egf' not in result)):
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# Transform sequence / step 1 (division by factorial)
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z, f = [], S.One
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for i, k in enumerate(v):
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f *= i if i else 1
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z.append(k/f)
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# Transform sequence / step 2 by computing f'(x)/f(x)
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# because log(f(x)) = integrate( f'(x)/f(x) )
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a, w = z[0], []
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for n in range(len(z)-1):
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w.append(
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(z[n+1]*(n+1) - sum(w[-i-1]*z[i+1] for i in range(n)))/a)
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# Perform some convolutions of the sequence with itself
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t = [1] + [0]*(len(w) - 1)
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for d in range(max(1, maxsqrtn)):
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t = [sum(t[n-i]*w[i] for i in range(n+1)) for n in range(len(w))]
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g = guess_generating_function_rational(t, X=X)
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if g:
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result['lgdegf'] = g**Rational(1, d+1)
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if 'egf' not in result:
|
||
|
result['egf'] = exp(integrate(result['lgdegf'], X))
|
||
|
break
|
||
|
|
||
|
return result
|
||
|
|
||
|
|
||
|
@public
|
||
|
def guess(l, all=False, evaluate=True, niter=2, variables=None):
|
||
|
"""
|
||
|
This function is adapted from the Rate.m package for Mathematica
|
||
|
written by Christian Krattenthaler.
|
||
|
It tries to guess a formula from a given sequence of rational numbers.
|
||
|
|
||
|
Explanation
|
||
|
===========
|
||
|
|
||
|
In order to speed up the process, the 'all' variable is set to False by
|
||
|
default, stopping the computation as some results are returned during an
|
||
|
iteration; the variable can be set to True if more iterations are needed
|
||
|
(other formulas may be found; however they may be equivalent to the first
|
||
|
ones).
|
||
|
|
||
|
Another option is the 'evaluate' variable (default is True); setting it
|
||
|
to False will leave the involved products unevaluated.
|
||
|
|
||
|
By default, the number of iterations is set to 2 but a greater value (up
|
||
|
to len(l)-1) can be specified with the optional 'niter' variable.
|
||
|
More and more convoluted results are found when the order of the
|
||
|
iteration gets higher:
|
||
|
|
||
|
* first iteration returns polynomial or rational functions;
|
||
|
* second iteration returns products of rising factorials and their
|
||
|
inverses;
|
||
|
* third iteration returns products of products of rising factorials
|
||
|
and their inverses;
|
||
|
* etc.
|
||
|
|
||
|
The returned formulas contain symbols i0, i1, i2, ... where the main
|
||
|
variables is i0 (and auxiliary variables are i1, i2, ...). A list of
|
||
|
other symbols can be provided in the 'variables' option; the length of
|
||
|
the least should be the value of 'niter' (more is acceptable but only
|
||
|
the first symbols will be used); in this case, the main variable will be
|
||
|
the first symbol in the list.
|
||
|
|
||
|
Examples
|
||
|
========
|
||
|
|
||
|
>>> from sympy.concrete.guess import guess
|
||
|
>>> guess([1,2,6,24,120], evaluate=False)
|
||
|
[Product(i1 + 1, (i1, 1, i0 - 1))]
|
||
|
|
||
|
>>> from sympy import symbols
|
||
|
>>> r = guess([1,2,7,42,429,7436,218348,10850216], niter=4)
|
||
|
>>> i0 = symbols("i0")
|
||
|
>>> [r[0].subs(i0,n).doit() for n in range(1,10)]
|
||
|
[1, 2, 7, 42, 429, 7436, 218348, 10850216, 911835460]
|
||
|
"""
|
||
|
if any(a==0 for a in l[:-1]):
|
||
|
return []
|
||
|
N = len(l)
|
||
|
niter = min(N-1, niter)
|
||
|
myprod = product if evaluate else Product
|
||
|
g = []
|
||
|
res = []
|
||
|
if variables is None:
|
||
|
symb = symbols('i:'+str(niter))
|
||
|
else:
|
||
|
symb = variables
|
||
|
for k, s in enumerate(symb):
|
||
|
g.append(l)
|
||
|
n, r = len(l), []
|
||
|
for i in range(n-2-1, -1, -1):
|
||
|
ri = rinterp(enumerate(g[k][:-1], start=1), i, X=s)
|
||
|
if ((denom(ri).subs({s:n}) != 0)
|
||
|
and (ri.subs({s:n}) - g[k][-1] == 0)
|
||
|
and ri not in r):
|
||
|
r.append(ri)
|
||
|
if r:
|
||
|
for i in range(k-1, -1, -1):
|
||
|
r = [g[i][0]
|
||
|
* myprod(v, (symb[i+1], 1, symb[i]-1)) for v in r]
|
||
|
if not all: return r
|
||
|
res += r
|
||
|
l = [Rational(l[i+1], l[i]) for i in range(N-k-1)]
|
||
|
return res
|