This module implements manipulation of infinite hypergeometric series
represented in standard parametric form (as functions).
AUTHORS:
EXAMPLES:
Examples from trac ticket #9908:
sage: maxima('integrate(bessel_j(2, x), x)').sage()
1/24*x^3*hypergeometric((3/2,), (5/2, 3), -1/4*x^2)
sage: sum(((2*I)^x/(x^3 + 1)*(1/4)^x), x, 0, oo)
hypergeometric((1, 1, -1/2*I*sqrt(3) - 1/2, 1/2*I*sqrt(3) - 1/2),...
(2, -1/2*I*sqrt(3) + 1/2, 1/2*I*sqrt(3) + 1/2), 1/2*I)
sage: sum((-1)^x/((2*x + 1)*factorial(2*x + 1)), x, 0, oo)
hypergeometric((1/2,), (3/2, 3/2), -1/4)
Simplification (note that simplify_full does not yet call simplify_hypergeometric):
sage: hypergeometric([-2], [], x).simplify_hypergeometric()
x^2 - 2*x + 1
sage: hypergeometric([], [], x).simplify_hypergeometric()
e^x
sage: a = hypergeometric((hypergeometric((), (), x),), (),
....: hypergeometric((), (), x))
sage: a.simplify_hypergeometric()
1/((-e^x + 1)^e^x)
sage: a.simplify_hypergeometric(algorithm='sage')
(-e^x + 1)^(-e^x)
Equality testing:
sage: bool(hypergeometric([], [], x).derivative(x) ==
....: hypergeometric([], [], x)) # diff(e^x, x) == e^x
True
sage: bool(hypergeometric([], [], x) == hypergeometric([], [1], x))
False
Computing terms and series:
sage: z = var('z')
sage: hypergeometric([], [], z).series(z, 0)
Order(1)
sage: hypergeometric([], [], z).series(z, 1)
1 + Order(z)
sage: hypergeometric([], [], z).series(z, 2)
1 + 1*z + Order(z^2)
sage: hypergeometric([], [], z).series(z, 3)
1 + 1*z + 1/2*z^2 + Order(z^3)
sage: hypergeometric([-2], [], z).series(z, 3)
1 + (-2)*z + 1*z^2
sage: hypergeometric([-2], [], z).series(z, 6)
1 + (-2)*z + 1*z^2
sage: hypergeometric([-2], [], z).series(z, 6).is_terminating_series()
True
sage: hypergeometric([-2], [], z).series(z, 2)
1 + (-2)*z + Order(z^2)
sage: hypergeometric([-2], [], z).series(z, 2).is_terminating_series()
False
sage: hypergeometric([1], [], z).series(z, 6)
1 + 1*z + 1*z^2 + 1*z^3 + 1*z^4 + 1*z^5 + Order(z^6)
sage: hypergeometric([], [1/2], -z^2/4).series(z, 11)
1 + (-1/2)*z^2 + 1/24*z^4 + (-1/720)*z^6 + 1/40320*z^8 +...
(-1/3628800)*z^10 + Order(z^11)
sage: hypergeometric([1], [5], x).series(x, 5)
1 + 1/5*x + 1/30*x^2 + 1/210*x^3 + 1/1680*x^4 + Order(x^5)
sage: sum(hypergeometric([1, 2], [3], 1/3).terms(6)).n()
1.29788359788360
sage: hypergeometric([1, 2], [3], 1/3).n()
1.29837194594696
sage: hypergeometric([], [], x).series(x, 20)(x=1).n() == e.n()
True
Plotting:
sage: plot(hypergeometric([1, 1], [3, 3, 3], x), x, -30, 30)
Graphics object consisting of 1 graphics primitive
sage: complex_plot(hypergeometric([x], [], 2), (-1, 1), (-1, 1))
Graphics object consisting of 1 graphics primitive
Numeric evaluation:
sage: hypergeometric([1], [], 1/10).n() # geometric series
1.11111111111111
sage: hypergeometric([], [], 1).n() # e
2.71828182845905
sage: hypergeometric([], [], 3., hold=True)
hypergeometric((), (), 3.00000000000000)
sage: hypergeometric([1, 2, 3], [4, 5, 6], 1/2).n()
1.02573619590134
sage: hypergeometric([1, 2, 3], [4, 5, 6], 1/2).n(digits=30)
1.02573619590133865036584139535
sage: hypergeometric([5 - 3*I], [3/2, 2 + I, sqrt(2)], 4 + I).n()
5.52605111678805 - 7.86331357527544*I
sage: hypergeometric((10, 10), (50,), 2.)
-1705.75733163554 - 356.749986056024*I
Conversions:
sage: maxima(hypergeometric([1, 1, 1], [3, 3, 3], x))
hypergeometric([1,1,1],[3,3,3],_SAGE_VAR_x)
sage: hypergeometric((5, 4), (4, 4), 3)._sympy_()
hyper((5, 4), (4, 4), 3)
sage: hypergeometric((5, 4), (4, 4), 3)._mathematica_init_()
'HypergeometricPFQ[{5,4},{4,4},3]'
Arbitrary level of nesting for conversions:
sage: maxima(nest(lambda y: hypergeometric([y], [], x), 3, 1))
1/(1-_SAGE_VAR_x)^(1/(1-_SAGE_VAR_x)^(1/(1-_SAGE_VAR_x)))
sage: maxima(nest(lambda y: hypergeometric([y], [3], x), 3, 1))._sage_()
hypergeometric((hypergeometric((hypergeometric((1,), (3,), x),), (3,),...
x),), (3,), x)
sage: nest(lambda y: hypergeometric([y], [], x), 3, 1)._mathematica_init_()
'HypergeometricPFQ[{HypergeometricPFQ[{HypergeometricPFQ[{1},{},x]},...
Bases: sage.symbolic.function.BuiltinFunction
Represents a (formal) generalized infinite hypergeometric series. It is defined as
where is the rising factorial.
Rewrite as a linear combination of functions of strictly lower degree by eliminating all parameters a[i] and b[j] such that a[i] = b[i] + m for nonnegative integer m.
EXAMPLES:
sage: x = hypergeometric([6, 1], [3, 4, 5], 10)
sage: y = x.deflated()
sage: y
1/252*hypergeometric((4,), (7, 8), 10)
+ 1/12*hypergeometric((3,), (6, 7), 10)
+ 1/2*hypergeometric((2,), (5, 6), 10)
+ hypergeometric((1,), (4, 5), 10)
sage: x.n(); y.n()
2.87893612686782
2.87893612686782
sage: x = hypergeometric([6, 7], [3, 4, 5], 10)
sage: y = x.deflated()
sage: y
25/27216*hypergeometric((), (11,), 10)
+ 25/648*hypergeometric((), (10,), 10)
+ 265/504*hypergeometric((), (9,), 10)
+ 181/63*hypergeometric((), (8,), 10)
+ 19/3*hypergeometric((), (7,), 10)
+ 5*hypergeometric((), (6,), 10)
+ hypergeometric((), (5,), 10)
sage: x.n(); y.n()
63.0734110716969
63.0734110716969
Eliminate repeated parameters by pairwise cancellation of identical terms in a and b.
EXAMPLES:
sage: hypergeometric([1, 1, 2, 5], [5, 1, 4],
....: 1/2).eliminate_parameters()
hypergeometric((1, 2), (4,), 1/2)
sage: hypergeometric([x], [x], x).eliminate_parameters()
hypergeometric((), (), x)
sage: hypergeometric((5, 4), (4, 4), 3).eliminate_parameters()
hypergeometric((5,), (4,), 3)
Determine whether self converges absolutely as an infinite series. False is returned if not all terms are finite.
EXAMPLES:
Degree giving infinite radius of convergence:
sage: hypergeometric([2, 3], [4, 5],
....: 6).is_absolutely_convergent()
True
sage: hypergeometric([2, 3], [-4, 5],
....: 6).is_absolutely_convergent() # undefined
False
sage: (hypergeometric([2, 3], [-4, 5], Infinity)
....: .is_absolutely_convergent()) # undefined
False
Ordinary geometric series (unit radius of convergence):
sage: hypergeometric([1], [], 1/2).is_absolutely_convergent()
True
sage: hypergeometric([1], [], 2).is_absolutely_convergent()
False
sage: hypergeometric([1], [], 1).is_absolutely_convergent()
False
sage: hypergeometric([1], [], -1).is_absolutely_convergent()
False
sage: hypergeometric([1], [], -1).n() # Sum still exists
0.500000000000000
Degree (unit radius of convergence):
sage: hypergeometric([2, 3], [4], 6).is_absolutely_convergent()
False
sage: hypergeometric([2, 3], [4], 1).is_absolutely_convergent()
False
sage: hypergeometric([2, 3], [5], 1).is_absolutely_convergent()
False
sage: hypergeometric([2, 3], [6], 1).is_absolutely_convergent()
True
sage: hypergeometric([-2, 3], [4],
....: 5).is_absolutely_convergent()
True
sage: hypergeometric([2, -3], [4],
....: 5).is_absolutely_convergent()
True
sage: hypergeometric([2, -3], [-4],
....: 5).is_absolutely_convergent()
True
sage: hypergeometric([2, -3], [-1],
....: 5).is_absolutely_convergent()
False
Degree giving zero radius of convergence:
sage: hypergeometric([1, 2, 3], [4],
....: 2).is_absolutely_convergent()
False
sage: hypergeometric([1, 2, 3], [4],
....: 1/2).is_absolutely_convergent()
False
sage: (hypergeometric([1, 2, -3], [4], 1/2)
....: .is_absolutely_convergent()) # polynomial
True
Determine whether the series represented by self terminates
after a finite number of terms, i.e. whether any of the
numerator parameters are nonnegative integers (with no
preceding nonnegative denominator parameters), or .
If terminating, the series represents a polynomial of .
EXAMPLES:
sage: hypergeometric([1, 2], [3, 4], x).is_terminating()
False
sage: hypergeometric([1, -2], [3, 4], x).is_terminating()
True
sage: hypergeometric([1, -2], [], x).is_terminating()
True
Determine whether all terms of self are finite. Any infinite terms or ambiguous terms beyond the first zero, if one exists, are ignored.
Ambiguous cases (where a term is the product of both zero and an infinity) are not considered finite.
EXAMPLES:
sage: hypergeometric([2], [3, 4], 5).is_termwise_finite()
True
sage: hypergeometric([2], [-3, 4], 5).is_termwise_finite()
False
sage: hypergeometric([-2], [-3, 4], 5).is_termwise_finite()
True
sage: hypergeometric([-3], [-3, 4],
....: 5).is_termwise_finite() # ambiguous
False
sage: hypergeometric([0], [-1], 5).is_termwise_finite()
True
sage: hypergeometric([0], [0],
....: 5).is_termwise_finite() # ambiguous
False
sage: hypergeometric([1], [2], Infinity).is_termwise_finite()
False
sage: (hypergeometric([0], [0], Infinity)
....: .is_termwise_finite()) # ambiguous
False
sage: (hypergeometric([0], [], Infinity)
....: .is_termwise_finite()) # ambiguous
False
Return with parameters sorted in a canonical order.
EXAMPLES:
sage: hypergeometric([2, 1, 3], [5, 4],
....: 1/2).sorted_parameters()
hypergeometric((1, 2, 3), (4, 5), 1/2)
Generate the terms of self (optionally only n terms).
EXAMPLES:
sage: list(hypergeometric([-2, 1], [3, 4], x).terms())
[1, -1/6*x, 1/120*x^2]
sage: list(hypergeometric([-2, 1], [3, 4], x).terms(2))
[1, -1/6*x]
sage: list(hypergeometric([-2, 1], [3, 4], x).terms(0))
[]
Try to evaluate hyp in closed form using elementary (and other simple) functions.
It may be necessary to call Hypergeometric.deflated() first to find some closed forms.
EXAMPLES:
sage: from sage.functions.hypergeometric import closed_form
sage: var('a b c z')
(a, b, c, z)
sage: closed_form(hypergeometric([1], [], 1 + z))
-1/z
sage: closed_form(hypergeometric([], [], 1 + z))
e^(z + 1)
sage: closed_form(hypergeometric([], [1/2], 4))
cosh(4)
sage: closed_form(hypergeometric([], [3/2], 4))
1/4*sinh(4)
sage: closed_form(hypergeometric([], [5/2], 4))
3/16*cosh(4) - 3/64*sinh(4)
sage: closed_form(hypergeometric([], [-3/2], 4))
19/3*cosh(4) - 4*sinh(4)
sage: closed_form(hypergeometric([-3, 1], [var('a')], z))
-3*z/a + 6*z^2/((a + 1)*a) - 6*z^3/((a + 2)*(a + 1)*a) + 1
sage: closed_form(hypergeometric([-3, 1/3], [-4], z))
7/162*z^3 + 1/9*z^2 + 1/4*z + 1
sage: closed_form(hypergeometric([], [], z))
e^z
sage: closed_form(hypergeometric([a], [], z))
(-z + 1)^(-a)
sage: closed_form(hypergeometric([1, 1, 2], [1, 1], z))
(z - 1)^(-2)
sage: closed_form(hypergeometric([2, 3], [1], x))
-1/(x - 1)^3 + 3*x/(x - 1)^4
sage: closed_form(hypergeometric([1/2], [3/2], -5))
1/10*sqrt(5)*sqrt(pi)*erf(sqrt(5))
sage: closed_form(hypergeometric([2], [5], 3))
4
sage: closed_form(hypergeometric([2], [5], 5))
48/625*e^5 + 612/625
sage: closed_form(hypergeometric([1/2, 7/2], [3/2], z))
1/5*z^2/(-z + 1)^(5/2) + 2/3*z/(-z + 1)^(3/2) + 1/sqrt(-z + 1)
sage: closed_form(hypergeometric([1/2, 1], [2], z))
-2*(sqrt(-z + 1) - 1)/z
sage: closed_form(hypergeometric([1, 1], [2], z))
-log(-z + 1)/z
sage: closed_form(hypergeometric([1, 1], [3], z))
-2*((z - 1)*log(-z + 1)/z - 1)/z
sage: closed_form(hypergeometric([1, 1, 1], [2, 2], x))
hypergeometric((1, 1, 1), (2, 2), x)
Utility function for converting rational parameters to
tuples (which mpmath handles more efficiently).
EXAMPLES:
sage: from sage.functions.hypergeometric import rational_param_as_tuple
sage: rational_param_as_tuple(1/2)
(1, 2)
sage: rational_param_as_tuple(3)
3
sage: rational_param_as_tuple(pi)
pi