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Mini Shell
Mini Shell
from sympy import (
Symbol, Dummy, diff, Derivative, Rational, roots, S, sqrt, hyper,
cos, gamma, conjugate, factorial, pi, oo, zoo, binomial, RisingFactorial,
legendre, assoc_legendre, chebyshevu, chebyshevt, chebyshevt_root,
chebyshevu_root, laguerre, assoc_laguerre, laguerre_poly, hermite,
gegenbauer, jacobi, jacobi_normalized, Sum, floor, exp)
from sympy.core.expr import unchanged
from sympy.core.function import ArgumentIndexError
from sympy.testing.pytest import raises
x = Symbol('x')
def test_jacobi():
n = Symbol("n")
a = Symbol("a")
b = Symbol("b")
assert jacobi(0, a, b, x) == 1
assert jacobi(1, a, b, x) == a/2 - b/2 + x*(a/2 + b/2 + 1)
assert jacobi(n, a, a, x) == RisingFactorial(
a + 1, n)*gegenbauer(n, a + S.Half, x)/RisingFactorial(2*a + 1, n)
assert jacobi(n, a, -a, x) == ((-1)**a*(-x + 1)**(-a/2)*(x + 1)**(a/2)*assoc_legendre(n, a, x)*
factorial(-a + n)*gamma(a + n + 1)/(factorial(a + n)*gamma(n + 1)))
assert jacobi(n, -b, b, x) == ((-x + 1)**(b/2)*(x + 1)**(-b/2)*assoc_legendre(n, b, x)*
gamma(-b + n + 1)/gamma(n + 1))
assert jacobi(n, 0, 0, x) == legendre(n, x)
assert jacobi(n, S.Half, S.Half, x) == RisingFactorial(
Rational(3, 2), n)*chebyshevu(n, x)/factorial(n + 1)
assert jacobi(n, Rational(-1, 2), Rational(-1, 2), x) == RisingFactorial(
S.Half, n)*chebyshevt(n, x)/factorial(n)
X = jacobi(n, a, b, x)
assert isinstance(X, jacobi)
assert jacobi(n, a, b, -x) == (-1)**n*jacobi(n, b, a, x)
assert jacobi(n, a, b, 0) == 2**(-n)*gamma(a + n + 1)*hyper(
(-b - n, -n), (a + 1,), -1)/(factorial(n)*gamma(a + 1))
assert jacobi(n, a, b, 1) == RisingFactorial(a + 1, n)/factorial(n)
m = Symbol("m", positive=True)
assert jacobi(m, a, b, oo) == oo*RisingFactorial(a + b + m + 1, m)
assert unchanged(jacobi, n, a, b, oo)
assert conjugate(jacobi(m, a, b, x)) == \
jacobi(m, conjugate(a), conjugate(b), conjugate(x))
_k = Dummy('k')
assert diff(jacobi(n, a, b, x), n) == Derivative(jacobi(n, a, b, x), n)
assert diff(jacobi(n, a, b, x), a).dummy_eq(Sum((jacobi(n, a, b, x) +
(2*_k + a + b + 1)*RisingFactorial(_k + b + 1, -_k + n)*jacobi(_k, a,
b, x)/((-_k + n)*RisingFactorial(_k + a + b + 1, -_k + n)))/(_k + a
+ b + n + 1), (_k, 0, n - 1)))
assert diff(jacobi(n, a, b, x), b).dummy_eq(Sum(((-1)**(-_k + n)*(2*_k +
a + b + 1)*RisingFactorial(_k + a + 1, -_k + n)*jacobi(_k, a, b, x)/
((-_k + n)*RisingFactorial(_k + a + b + 1, -_k + n)) + jacobi(n, a,
b, x))/(_k + a + b + n + 1), (_k, 0, n - 1)))
assert diff(jacobi(n, a, b, x), x) == \
(a/2 + b/2 + n/2 + S.Half)*jacobi(n - 1, a + 1, b + 1, x)
assert jacobi_normalized(n, a, b, x) == \
(jacobi(n, a, b, x)/sqrt(2**(a + b + 1)*gamma(a + n + 1)*gamma(b + n + 1)
/((a + b + 2*n + 1)*factorial(n)*gamma(a + b + n + 1))))
raises(ValueError, lambda: jacobi(-2.1, a, b, x))
raises(ValueError, lambda: jacobi(Dummy(positive=True, integer=True), 1, 2, oo))
assert jacobi(n, a, b, x).rewrite("polynomial").dummy_eq(Sum((S.Half - x/2)
**_k*RisingFactorial(-n, _k)*RisingFactorial(_k + a + 1, -_k + n)*
RisingFactorial(a + b + n + 1, _k)/factorial(_k), (_k, 0, n))/factorial(n))
raises(ArgumentIndexError, lambda: jacobi(n, a, b, x).fdiff(5))
def test_gegenbauer():
n = Symbol("n")
a = Symbol("a")
assert gegenbauer(0, a, x) == 1
assert gegenbauer(1, a, x) == 2*a*x
assert gegenbauer(2, a, x) == -a + x**2*(2*a**2 + 2*a)
assert gegenbauer(3, a, x) == \
x**3*(4*a**3/3 + 4*a**2 + a*Rational(8, 3)) + x*(-2*a**2 - 2*a)
assert gegenbauer(-1, a, x) == 0
assert gegenbauer(n, S.Half, x) == legendre(n, x)
assert gegenbauer(n, 1, x) == chebyshevu(n, x)
assert gegenbauer(n, -1, x) == 0
X = gegenbauer(n, a, x)
assert isinstance(X, gegenbauer)
assert gegenbauer(n, a, -x) == (-1)**n*gegenbauer(n, a, x)
assert gegenbauer(n, a, 0) == 2**n*sqrt(pi) * \
gamma(a + n/2)/(gamma(a)*gamma(-n/2 + S.Half)*gamma(n + 1))
assert gegenbauer(n, a, 1) == gamma(2*a + n)/(gamma(2*a)*gamma(n + 1))
assert gegenbauer(n, Rational(3, 4), -1) is zoo
assert gegenbauer(n, Rational(1, 4), -1) == (sqrt(2)*cos(pi*(n + S.One/4))*
gamma(n + S.Half)/(sqrt(pi)*gamma(n + 1)))
m = Symbol("m", positive=True)
assert gegenbauer(m, a, oo) == oo*RisingFactorial(a, m)
assert unchanged(gegenbauer, n, a, oo)
assert conjugate(gegenbauer(n, a, x)) == gegenbauer(n, conjugate(a), conjugate(x))
_k = Dummy('k')
assert diff(gegenbauer(n, a, x), n) == Derivative(gegenbauer(n, a, x), n)
assert diff(gegenbauer(n, a, x), a).dummy_eq(Sum((2*(-1)**(-_k + n) + 2)*
(_k + a)*gegenbauer(_k, a, x)/((-_k + n)*(_k + 2*a + n)) + ((2*_k +
2)/((_k + 2*a)*(2*_k + 2*a + 1)) + 2/(_k + 2*a + n))*gegenbauer(n, a
, x), (_k, 0, n - 1)))
assert diff(gegenbauer(n, a, x), x) == 2*a*gegenbauer(n - 1, a + 1, x)
assert gegenbauer(n, a, x).rewrite('polynomial').dummy_eq(
Sum((-1)**_k*(2*x)**(-2*_k + n)*RisingFactorial(a, -_k + n)
/(factorial(_k)*factorial(-2*_k + n)), (_k, 0, floor(n/2))))
raises(ArgumentIndexError, lambda: gegenbauer(n, a, x).fdiff(4))
def test_legendre():
assert legendre(0, x) == 1
assert legendre(1, x) == x
assert legendre(2, x) == ((3*x**2 - 1)/2).expand()
assert legendre(3, x) == ((5*x**3 - 3*x)/2).expand()
assert legendre(4, x) == ((35*x**4 - 30*x**2 + 3)/8).expand()
assert legendre(5, x) == ((63*x**5 - 70*x**3 + 15*x)/8).expand()
assert legendre(6, x) == ((231*x**6 - 315*x**4 + 105*x**2 - 5)/16).expand()
assert legendre(10, -1) == 1
assert legendre(11, -1) == -1
assert legendre(10, 1) == 1
assert legendre(11, 1) == 1
assert legendre(10, 0) != 0
assert legendre(11, 0) == 0
assert legendre(-1, x) == 1
k = Symbol('k')
assert legendre(5 - k, x).subs(k, 2) == ((5*x**3 - 3*x)/2).expand()
assert roots(legendre(4, x), x) == {
sqrt(Rational(3, 7) - Rational(2, 35)*sqrt(30)): 1,
-sqrt(Rational(3, 7) - Rational(2, 35)*sqrt(30)): 1,
sqrt(Rational(3, 7) + Rational(2, 35)*sqrt(30)): 1,
-sqrt(Rational(3, 7) + Rational(2, 35)*sqrt(30)): 1,
}
n = Symbol("n")
X = legendre(n, x)
assert isinstance(X, legendre)
assert unchanged(legendre, n, x)
assert legendre(n, 0) == sqrt(pi)/(gamma(S.Half - n/2)*gamma(n/2 + 1))
assert legendre(n, 1) == 1
assert legendre(n, oo) is oo
assert legendre(-n, x) == legendre(n - 1, x)
assert legendre(n, -x) == (-1)**n*legendre(n, x)
assert unchanged(legendre, -n + k, x)
assert conjugate(legendre(n, x)) == legendre(n, conjugate(x))
assert diff(legendre(n, x), x) == \
n*(x*legendre(n, x) - legendre(n - 1, x))/(x**2 - 1)
assert diff(legendre(n, x), n) == Derivative(legendre(n, x), n)
_k = Dummy('k')
assert legendre(n, x).rewrite("polynomial").dummy_eq(Sum((-1)**_k*(S.Half -
x/2)**_k*(x/2 + S.Half)**(-_k + n)*binomial(n, _k)**2, (_k, 0, n)))
raises(ArgumentIndexError, lambda: legendre(n, x).fdiff(1))
raises(ArgumentIndexError, lambda: legendre(n, x).fdiff(3))
def test_assoc_legendre():
Plm = assoc_legendre
Q = sqrt(1 - x**2)
assert Plm(0, 0, x) == 1
assert Plm(1, 0, x) == x
assert Plm(1, 1, x) == -Q
assert Plm(2, 0, x) == (3*x**2 - 1)/2
assert Plm(2, 1, x) == -3*x*Q
assert Plm(2, 2, x) == 3*Q**2
assert Plm(3, 0, x) == (5*x**3 - 3*x)/2
assert Plm(3, 1, x).expand() == (( 3*(1 - 5*x**2)/2 ).expand() * Q).expand()
assert Plm(3, 2, x) == 15*x * Q**2
assert Plm(3, 3, x) == -15 * Q**3
# negative m
assert Plm(1, -1, x) == -Plm(1, 1, x)/2
assert Plm(2, -2, x) == Plm(2, 2, x)/24
assert Plm(2, -1, x) == -Plm(2, 1, x)/6
assert Plm(3, -3, x) == -Plm(3, 3, x)/720
assert Plm(3, -2, x) == Plm(3, 2, x)/120
assert Plm(3, -1, x) == -Plm(3, 1, x)/12
n = Symbol("n")
m = Symbol("m")
X = Plm(n, m, x)
assert isinstance(X, assoc_legendre)
assert Plm(n, 0, x) == legendre(n, x)
assert Plm(n, m, 0) == 2**m*sqrt(pi)/(gamma(-m/2 - n/2 +
S.Half)*gamma(-m/2 + n/2 + 1))
assert diff(Plm(m, n, x), x) == (m*x*assoc_legendre(m, n, x) -
(m + n)*assoc_legendre(m - 1, n, x))/(x**2 - 1)
_k = Dummy('k')
assert Plm(m, n, x).rewrite("polynomial").dummy_eq(
(1 - x**2)**(n/2)*Sum((-1)**_k*2**(-m)*x**(-2*_k + m - n)*factorial
(-2*_k + 2*m)/(factorial(_k)*factorial(-_k + m)*factorial(-2*_k + m
- n)), (_k, 0, floor(m/2 - n/2))))
assert conjugate(assoc_legendre(n, m, x)) == \
assoc_legendre(n, conjugate(m), conjugate(x))
raises(ValueError, lambda: Plm(0, 1, x))
raises(ValueError, lambda: Plm(-1, 1, x))
raises(ArgumentIndexError, lambda: Plm(n, m, x).fdiff(1))
raises(ArgumentIndexError, lambda: Plm(n, m, x).fdiff(2))
raises(ArgumentIndexError, lambda: Plm(n, m, x).fdiff(4))
def test_chebyshev():
assert chebyshevt(0, x) == 1
assert chebyshevt(1, x) == x
assert chebyshevt(2, x) == 2*x**2 - 1
assert chebyshevt(3, x) == 4*x**3 - 3*x
for n in range(1, 4):
for k in range(n):
z = chebyshevt_root(n, k)
assert chebyshevt(n, z) == 0
raises(ValueError, lambda: chebyshevt_root(n, n))
for n in range(1, 4):
for k in range(n):
z = chebyshevu_root(n, k)
assert chebyshevu(n, z) == 0
raises(ValueError, lambda: chebyshevu_root(n, n))
n = Symbol("n")
X = chebyshevt(n, x)
assert isinstance(X, chebyshevt)
assert unchanged(chebyshevt, n, x)
assert chebyshevt(n, -x) == (-1)**n*chebyshevt(n, x)
assert chebyshevt(-n, x) == chebyshevt(n, x)
assert chebyshevt(n, 0) == cos(pi*n/2)
assert chebyshevt(n, 1) == 1
assert chebyshevt(n, oo) is oo
assert conjugate(chebyshevt(n, x)) == chebyshevt(n, conjugate(x))
assert diff(chebyshevt(n, x), x) == n*chebyshevu(n - 1, x)
X = chebyshevu(n, x)
assert isinstance(X, chebyshevu)
y = Symbol('y')
assert chebyshevu(n, -x) == (-1)**n*chebyshevu(n, x)
assert chebyshevu(-n, x) == -chebyshevu(n - 2, x)
assert unchanged(chebyshevu, -n + y, x)
assert chebyshevu(n, 0) == cos(pi*n/2)
assert chebyshevu(n, 1) == n + 1
assert chebyshevu(n, oo) is oo
assert conjugate(chebyshevu(n, x)) == chebyshevu(n, conjugate(x))
assert diff(chebyshevu(n, x), x) == \
(-x*chebyshevu(n, x) + (n + 1)*chebyshevt(n + 1, x))/(x**2 - 1)
_k = Dummy('k')
assert chebyshevt(n, x).rewrite("polynomial").dummy_eq(Sum(x**(-2*_k + n)
*(x**2 - 1)**_k*binomial(n, 2*_k), (_k, 0, floor(n/2))))
assert chebyshevu(n, x).rewrite("polynomial").dummy_eq(Sum((-1)**_k*(2*x)
**(-2*_k + n)*factorial(-_k + n)/(factorial(_k)*
factorial(-2*_k + n)), (_k, 0, floor(n/2))))
raises(ArgumentIndexError, lambda: chebyshevt(n, x).fdiff(1))
raises(ArgumentIndexError, lambda: chebyshevt(n, x).fdiff(3))
raises(ArgumentIndexError, lambda: chebyshevu(n, x).fdiff(1))
raises(ArgumentIndexError, lambda: chebyshevu(n, x).fdiff(3))
def test_hermite():
assert hermite(0, x) == 1
assert hermite(1, x) == 2*x
assert hermite(2, x) == 4*x**2 - 2
assert hermite(3, x) == 8*x**3 - 12*x
assert hermite(4, x) == 16*x**4 - 48*x**2 + 12
assert hermite(6, x) == 64*x**6 - 480*x**4 + 720*x**2 - 120
n = Symbol("n")
assert unchanged(hermite, n, x)
assert hermite(n, -x) == (-1)**n*hermite(n, x)
assert unchanged(hermite, -n, x)
assert hermite(n, 0) == 2**n*sqrt(pi)/gamma(S.Half - n/2)
assert hermite(n, oo) is oo
assert conjugate(hermite(n, x)) == hermite(n, conjugate(x))
_k = Dummy('k')
assert hermite(n, x).rewrite("polynomial").dummy_eq(factorial(n)*Sum((-1)
**_k*(2*x)**(-2*_k + n)/(factorial(_k)*factorial(-2*_k + n)), (_k,
0, floor(n/2))))
assert diff(hermite(n, x), x) == 2*n*hermite(n - 1, x)
assert diff(hermite(n, x), n) == Derivative(hermite(n, x), n)
raises(ArgumentIndexError, lambda: hermite(n, x).fdiff(3))
def test_laguerre():
n = Symbol("n")
m = Symbol("m", negative=True)
# Laguerre polynomials:
assert laguerre(0, x) == 1
assert laguerre(1, x) == -x + 1
assert laguerre(2, x) == x**2/2 - 2*x + 1
assert laguerre(3, x) == -x**3/6 + 3*x**2/2 - 3*x + 1
assert laguerre(-2, x) == (x + 1)*exp(x)
X = laguerre(n, x)
assert isinstance(X, laguerre)
assert laguerre(n, 0) == 1
assert laguerre(n, oo) == (-1)**n*oo
assert laguerre(n, -oo) is oo
assert conjugate(laguerre(n, x)) == laguerre(n, conjugate(x))
_k = Dummy('k')
assert laguerre(n, x).rewrite("polynomial").dummy_eq(
Sum(x**_k*RisingFactorial(-n, _k)/factorial(_k)**2, (_k, 0, n)))
assert laguerre(m, x).rewrite("polynomial").dummy_eq(
exp(x)*Sum((-x)**_k*RisingFactorial(m + 1, _k)/factorial(_k)**2,
(_k, 0, -m - 1)))
assert diff(laguerre(n, x), x) == -assoc_laguerre(n - 1, 1, x)
k = Symbol('k')
assert laguerre(-n, x) == exp(x)*laguerre(n - 1, -x)
assert laguerre(-3, x) == exp(x)*laguerre(2, -x)
assert unchanged(laguerre, -n + k, x)
raises(ValueError, lambda: laguerre(-2.1, x))
raises(ValueError, lambda: laguerre(Rational(5, 2), x))
raises(ArgumentIndexError, lambda: laguerre(n, x).fdiff(1))
raises(ArgumentIndexError, lambda: laguerre(n, x).fdiff(3))
def test_assoc_laguerre():
n = Symbol("n")
m = Symbol("m")
alpha = Symbol("alpha")
# generalized Laguerre polynomials:
assert assoc_laguerre(0, alpha, x) == 1
assert assoc_laguerre(1, alpha, x) == -x + alpha + 1
assert assoc_laguerre(2, alpha, x).expand() == \
(x**2/2 - (alpha + 2)*x + (alpha + 2)*(alpha + 1)/2).expand()
assert assoc_laguerre(3, alpha, x).expand() == \
(-x**3/6 + (alpha + 3)*x**2/2 - (alpha + 2)*(alpha + 3)*x/2 +
(alpha + 1)*(alpha + 2)*(alpha + 3)/6).expand()
# Test the lowest 10 polynomials with laguerre_poly, to make sure it works:
for i in range(10):
assert assoc_laguerre(i, 0, x).expand() == laguerre_poly(i, x)
X = assoc_laguerre(n, m, x)
assert isinstance(X, assoc_laguerre)
assert assoc_laguerre(n, 0, x) == laguerre(n, x)
assert assoc_laguerre(n, alpha, 0) == binomial(alpha + n, alpha)
p = Symbol("p", positive=True)
assert assoc_laguerre(p, alpha, oo) == (-1)**p*oo
assert assoc_laguerre(p, alpha, -oo) is oo
assert diff(assoc_laguerre(n, alpha, x), x) == \
-assoc_laguerre(n - 1, alpha + 1, x)
_k = Dummy('k')
assert diff(assoc_laguerre(n, alpha, x), alpha).dummy_eq(
Sum(assoc_laguerre(_k, alpha, x)/(-alpha + n), (_k, 0, n - 1)))
assert conjugate(assoc_laguerre(n, alpha, x)) == \
assoc_laguerre(n, conjugate(alpha), conjugate(x))
assert assoc_laguerre(n, alpha, x).rewrite('polynomial').dummy_eq(
gamma(alpha + n + 1)*Sum(x**_k*RisingFactorial(-n, _k)/
(factorial(_k)*gamma(_k + alpha + 1)), (_k, 0, n))/factorial(n))
raises(ValueError, lambda: assoc_laguerre(-2.1, alpha, x))
raises(ArgumentIndexError, lambda: assoc_laguerre(n, alpha, x).fdiff(1))
raises(ArgumentIndexError, lambda: assoc_laguerre(n, alpha, x).fdiff(4))
Zerion Mini Shell 1.0