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"""This module implements tools for integrating rational functions. """
from sympy.core.function import Lambda
from sympy.core.numbers import I
from sympy.core.singleton import S
from sympy.core.symbol import (Dummy, Symbol, symbols)
from sympy.functions.elementary.exponential import log
from sympy.functions.elementary.trigonometric import atan
from sympy.polys.polyroots import roots
from sympy.polys.polytools import cancel
from sympy.polys.rootoftools import RootSum
from sympy.polys import Poly, resultant, ZZ
def ratint(f, x, **flags):
"""
Performs indefinite integration of rational functions.
Explanation
===========
Given a field :math:`K` and a rational function :math:`f = p/q`,
where :math:`p` and :math:`q` are polynomials in :math:`K[x]`,
returns a function :math:`g` such that :math:`f = g'`.
Examples
========
>>> from sympy.integrals.rationaltools import ratint
>>> from sympy.abc import x
>>> ratint(36/(x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2), x)
(12*x + 6)/(x**2 - 1) + 4*log(x - 2) - 4*log(x + 1)
References
==========
.. [1] M. Bronstein, Symbolic Integration I: Transcendental
Functions, Second Edition, Springer-Verlag, 2005, pp. 35-70
See Also
========
sympy.integrals.integrals.Integral.doit
sympy.integrals.rationaltools.ratint_logpart
sympy.integrals.rationaltools.ratint_ratpart
"""
if isinstance(f, tuple):
p, q = f
else:
p, q = f.as_numer_denom()
p, q = Poly(p, x, composite=False, field=True), Poly(q, x, composite=False, field=True)
coeff, p, q = p.cancel(q)
poly, p = p.div(q)
result = poly.integrate(x).as_expr()
if p.is_zero:
return coeff*result
g, h = ratint_ratpart(p, q, x)
P, Q = h.as_numer_denom()
P = Poly(P, x)
Q = Poly(Q, x)
q, r = P.div(Q)
result += g + q.integrate(x).as_expr()
if not r.is_zero:
symbol = flags.get('symbol', 't')
if not isinstance(symbol, Symbol):
t = Dummy(symbol)
else:
t = symbol.as_dummy()
L = ratint_logpart(r, Q, x, t)
real = flags.get('real')
if real is None:
if isinstance(f, tuple):
p, q = f
atoms = p.atoms() | q.atoms()
else:
atoms = f.atoms()
for elt in atoms - {x}:
if not elt.is_extended_real:
real = False
break
else:
real = True
eps = S.Zero
if not real:
for h, q in L:
_, h = h.primitive()
eps += RootSum(
q, Lambda(t, t*log(h.as_expr())), quadratic=True)
else:
for h, q in L:
_, h = h.primitive()
R = log_to_real(h, q, x, t)
if R is not None:
eps += R
else:
eps += RootSum(
q, Lambda(t, t*log(h.as_expr())), quadratic=True)
result += eps
return coeff*result
def ratint_ratpart(f, g, x):
"""
Horowitz-Ostrogradsky algorithm.
Explanation
===========
Given a field K and polynomials f and g in K[x], such that f and g
are coprime and deg(f) < deg(g), returns fractions A and B in K(x),
such that f/g = A' + B and B has square-free denominator.
Examples
========
>>> from sympy.integrals.rationaltools import ratint_ratpart
>>> from sympy.abc import x, y
>>> from sympy import Poly
>>> ratint_ratpart(Poly(1, x, domain='ZZ'),
... Poly(x + 1, x, domain='ZZ'), x)
(0, 1/(x + 1))
>>> ratint_ratpart(Poly(1, x, domain='EX'),
... Poly(x**2 + y**2, x, domain='EX'), x)
(0, 1/(x**2 + y**2))
>>> ratint_ratpart(Poly(36, x, domain='ZZ'),
... Poly(x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2, x, domain='ZZ'), x)
((12*x + 6)/(x**2 - 1), 12/(x**2 - x - 2))
See Also
========
ratint, ratint_logpart
"""
from sympy.solvers.solvers import solve
f = Poly(f, x)
g = Poly(g, x)
u, v, _ = g.cofactors(g.diff())
n = u.degree()
m = v.degree()
A_coeffs = [ Dummy('a' + str(n - i)) for i in range(0, n) ]
B_coeffs = [ Dummy('b' + str(m - i)) for i in range(0, m) ]
C_coeffs = A_coeffs + B_coeffs
A = Poly(A_coeffs, x, domain=ZZ[C_coeffs])
B = Poly(B_coeffs, x, domain=ZZ[C_coeffs])
H = f - A.diff()*v + A*(u.diff()*v).quo(u) - B*u
result = solve(H.coeffs(), C_coeffs)
A = A.as_expr().subs(result)
B = B.as_expr().subs(result)
rat_part = cancel(A/u.as_expr(), x)
log_part = cancel(B/v.as_expr(), x)
return rat_part, log_part
def ratint_logpart(f, g, x, t=None):
r"""
Lazard-Rioboo-Trager algorithm.
Explanation
===========
Given a field K and polynomials f and g in K[x], such that f and g
are coprime, deg(f) < deg(g) and g is square-free, returns a list
of tuples (s_i, q_i) of polynomials, for i = 1..n, such that s_i
in K[t, x] and q_i in K[t], and::
___ ___
d f d \ ` \ `
-- - = -- ) ) a log(s_i(a, x))
dx g dx /__, /__,
i=1..n a | q_i(a) = 0
Examples
========
>>> from sympy.integrals.rationaltools import ratint_logpart
>>> from sympy.abc import x
>>> from sympy import Poly
>>> ratint_logpart(Poly(1, x, domain='ZZ'),
... Poly(x**2 + x + 1, x, domain='ZZ'), x)
[(Poly(x + 3*_t/2 + 1/2, x, domain='QQ[_t]'),
...Poly(3*_t**2 + 1, _t, domain='ZZ'))]
>>> ratint_logpart(Poly(12, x, domain='ZZ'),
... Poly(x**2 - x - 2, x, domain='ZZ'), x)
[(Poly(x - 3*_t/8 - 1/2, x, domain='QQ[_t]'),
...Poly(-_t**2 + 16, _t, domain='ZZ'))]
See Also
========
ratint, ratint_ratpart
"""
f, g = Poly(f, x), Poly(g, x)
t = t or Dummy('t')
a, b = g, f - g.diff()*Poly(t, x)
res, R = resultant(a, b, includePRS=True)
res = Poly(res, t, composite=False)
assert res, "BUG: resultant(%s, %s) cannot be zero" % (a, b)
R_map, H = {}, []
for r in R:
R_map[r.degree()] = r
def _include_sign(c, sqf):
if c.is_extended_real and (c < 0) == True:
h, k = sqf[0]
c_poly = c.as_poly(h.gens)
sqf[0] = h*c_poly, k
C, res_sqf = res.sqf_list()
_include_sign(C, res_sqf)
for q, i in res_sqf:
_, q = q.primitive()
if g.degree() == i:
H.append((g, q))
else:
h = R_map[i]
h_lc = Poly(h.LC(), t, field=True)
c, h_lc_sqf = h_lc.sqf_list(all=True)
_include_sign(c, h_lc_sqf)
for a, j in h_lc_sqf:
h = h.quo(Poly(a.gcd(q)**j, x))
inv, coeffs = h_lc.invert(q), [S.One]
for coeff in h.coeffs()[1:]:
coeff = coeff.as_poly(inv.gens)
T = (inv*coeff).rem(q)
coeffs.append(T.as_expr())
h = Poly(dict(list(zip(h.monoms(), coeffs))), x)
H.append((h, q))
return H
def log_to_atan(f, g):
"""
Convert complex logarithms to real arctangents.
Explanation
===========
Given a real field K and polynomials f and g in K[x], with g != 0,
returns a sum h of arctangents of polynomials in K[x], such that:
dh d f + I g
-- = -- I log( ------- )
dx dx f - I g
Examples
========
>>> from sympy.integrals.rationaltools import log_to_atan
>>> from sympy.abc import x
>>> from sympy import Poly, sqrt, S
>>> log_to_atan(Poly(x, x, domain='ZZ'), Poly(1, x, domain='ZZ'))
2*atan(x)
>>> log_to_atan(Poly(x + S(1)/2, x, domain='QQ'),
... Poly(sqrt(3)/2, x, domain='EX'))
2*atan(2*sqrt(3)*x/3 + sqrt(3)/3)
See Also
========
log_to_real
"""
if f.degree() < g.degree():
f, g = -g, f
f = f.to_field()
g = g.to_field()
p, q = f.div(g)
if q.is_zero:
return 2*atan(p.as_expr())
else:
s, t, h = g.gcdex(-f)
u = (f*s + g*t).quo(h)
A = 2*atan(u.as_expr())
return A + log_to_atan(s, t)
def log_to_real(h, q, x, t):
r"""
Convert complex logarithms to real functions.
Explanation
===========
Given real field K and polynomials h in K[t,x] and q in K[t],
returns real function f such that:
___
df d \ `
-- = -- ) a log(h(a, x))
dx dx /__,
a | q(a) = 0
Examples
========
>>> from sympy.integrals.rationaltools import log_to_real
>>> from sympy.abc import x, y
>>> from sympy import Poly, S
>>> log_to_real(Poly(x + 3*y/2 + S(1)/2, x, domain='QQ[y]'),
... Poly(3*y**2 + 1, y, domain='ZZ'), x, y)
2*sqrt(3)*atan(2*sqrt(3)*x/3 + sqrt(3)/3)/3
>>> log_to_real(Poly(x**2 - 1, x, domain='ZZ'),
... Poly(-2*y + 1, y, domain='ZZ'), x, y)
log(x**2 - 1)/2
See Also
========
log_to_atan
"""
from sympy.simplify.radsimp import collect
u, v = symbols('u,v', cls=Dummy)
H = h.as_expr().subs({t: u + I*v}).expand()
Q = q.as_expr().subs({t: u + I*v}).expand()
H_map = collect(H, I, evaluate=False)
Q_map = collect(Q, I, evaluate=False)
a, b = H_map.get(S.One, S.Zero), H_map.get(I, S.Zero)
c, d = Q_map.get(S.One, S.Zero), Q_map.get(I, S.Zero)
R = Poly(resultant(c, d, v), u)
R_u = roots(R, filter='R')
if len(R_u) != R.count_roots():
return None
result = S.Zero
for r_u in R_u.keys():
C = Poly(c.subs({u: r_u}), v)
R_v = roots(C, filter='R')
if len(R_v) != C.count_roots():
return None
R_v_paired = [] # take one from each pair of conjugate roots
for r_v in R_v:
if r_v not in R_v_paired and -r_v not in R_v_paired:
if r_v.is_negative or r_v.could_extract_minus_sign():
R_v_paired.append(-r_v)
elif not r_v.is_zero:
R_v_paired.append(r_v)
for r_v in R_v_paired:
D = d.subs({u: r_u, v: r_v})
if D.evalf(chop=True) != 0:
continue
A = Poly(a.subs({u: r_u, v: r_v}), x)
B = Poly(b.subs({u: r_u, v: r_v}), x)
AB = (A**2 + B**2).as_expr()
result += r_u*log(AB) + r_v*log_to_atan(A, B)
R_q = roots(q, filter='R')
if len(R_q) != q.count_roots():
return None
for r in R_q.keys():
result += r*log(h.as_expr().subs(t, r))
return result