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from .functions import defun, defun_wrapped | |
def qp(ctx, a, q=None, n=None, **kwargs): | |
r""" | |
Evaluates the q-Pochhammer symbol (or q-rising factorial) | |
.. math :: | |
(a; q)_n = \prod_{k=0}^{n-1} (1-a q^k) | |
where `n = \infty` is permitted if `|q| < 1`. Called with two arguments, | |
``qp(a,q)`` computes `(a;q)_{\infty}`; with a single argument, ``qp(q)`` | |
computes `(q;q)_{\infty}`. The special case | |
.. math :: | |
\phi(q) = (q; q)_{\infty} = \prod_{k=1}^{\infty} (1-q^k) = | |
\sum_{k=-\infty}^{\infty} (-1)^k q^{(3k^2-k)/2} | |
is also known as the Euler function, or (up to a factor `q^{-1/24}`) | |
the Dedekind eta function. | |
**Examples** | |
If `n` is a positive integer, the function amounts to a finite product:: | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> qp(2,3,5) | |
-725305.0 | |
>>> fprod(1-2*3**k for k in range(5)) | |
-725305.0 | |
>>> qp(2,3,0) | |
1.0 | |
Complex arguments are allowed:: | |
>>> qp(2-1j, 0.75j) | |
(0.4628842231660149089976379 + 4.481821753552703090628793j) | |
The regular Pochhammer symbol `(a)_n` is obtained in the | |
following limit as `q \to 1`:: | |
>>> a, n = 4, 7 | |
>>> limit(lambda q: qp(q**a,q,n) / (1-q)**n, 1) | |
604800.0 | |
>>> rf(a,n) | |
604800.0 | |
The Taylor series of the reciprocal Euler function gives | |
the partition function `P(n)`, i.e. the number of ways of writing | |
`n` as a sum of positive integers:: | |
>>> taylor(lambda q: 1/qp(q), 0, 10) | |
[1.0, 1.0, 2.0, 3.0, 5.0, 7.0, 11.0, 15.0, 22.0, 30.0, 42.0] | |
Special values include:: | |
>>> qp(0) | |
1.0 | |
>>> findroot(diffun(qp), -0.4) # location of maximum | |
-0.4112484791779547734440257 | |
>>> qp(_) | |
1.228348867038575112586878 | |
The q-Pochhammer symbol is related to the Jacobi theta functions. | |
For example, the following identity holds:: | |
>>> q = mpf(0.5) # arbitrary | |
>>> qp(q) | |
0.2887880950866024212788997 | |
>>> root(3,-2)*root(q,-24)*jtheta(2,pi/6,root(q,6)) | |
0.2887880950866024212788997 | |
""" | |
a = ctx.convert(a) | |
if n is None: | |
n = ctx.inf | |
else: | |
n = ctx.convert(n) | |
if n < 0: | |
raise ValueError("n cannot be negative") | |
if q is None: | |
q = a | |
else: | |
q = ctx.convert(q) | |
if n == 0: | |
return ctx.one + 0*(a+q) | |
infinite = (n == ctx.inf) | |
same = (a == q) | |
if infinite: | |
if abs(q) >= 1: | |
if same and (q == -1 or q == 1): | |
return ctx.zero * q | |
raise ValueError("q-function only defined for |q| < 1") | |
elif q == 0: | |
return ctx.one - a | |
maxterms = kwargs.get('maxterms', 50*ctx.prec) | |
if infinite and same: | |
# Euler's pentagonal theorem | |
def terms(): | |
t = 1 | |
yield t | |
k = 1 | |
x1 = q | |
x2 = q**2 | |
while 1: | |
yield (-1)**k * x1 | |
yield (-1)**k * x2 | |
x1 *= q**(3*k+1) | |
x2 *= q**(3*k+2) | |
k += 1 | |
if k > maxterms: | |
raise ctx.NoConvergence | |
return ctx.sum_accurately(terms) | |
# return ctx.nprod(lambda k: 1-a*q**k, [0,n-1]) | |
def factors(): | |
k = 0 | |
r = ctx.one | |
while 1: | |
yield 1 - a*r | |
r *= q | |
k += 1 | |
if k >= n: | |
return | |
if k > maxterms: | |
raise ctx.NoConvergence | |
return ctx.mul_accurately(factors) | |
def qgamma(ctx, z, q, **kwargs): | |
r""" | |
Evaluates the q-gamma function | |
.. math :: | |
\Gamma_q(z) = \frac{(q; q)_{\infty}}{(q^z; q)_{\infty}} (1-q)^{1-z}. | |
**Examples** | |
Evaluation for real and complex arguments:: | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> qgamma(4,0.75) | |
4.046875 | |
>>> qgamma(6,6) | |
121226245.0 | |
>>> qgamma(3+4j, 0.5j) | |
(0.1663082382255199834630088 + 0.01952474576025952984418217j) | |
The q-gamma function satisfies a functional equation similar | |
to that of the ordinary gamma function:: | |
>>> q = mpf(0.25) | |
>>> z = mpf(2.5) | |
>>> qgamma(z+1,q) | |
1.428277424823760954685912 | |
>>> (1-q**z)/(1-q)*qgamma(z,q) | |
1.428277424823760954685912 | |
""" | |
if abs(q) > 1: | |
return ctx.qgamma(z,1/q)*q**((z-2)*(z-1)*0.5) | |
return ctx.qp(q, q, None, **kwargs) / \ | |
ctx.qp(q**z, q, None, **kwargs) * (1-q)**(1-z) | |
def qfac(ctx, z, q, **kwargs): | |
r""" | |
Evaluates the q-factorial, | |
.. math :: | |
[n]_q! = (1+q)(1+q+q^2)\cdots(1+q+\cdots+q^{n-1}) | |
or more generally | |
.. math :: | |
[z]_q! = \frac{(q;q)_z}{(1-q)^z}. | |
**Examples** | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> qfac(0,0) | |
1.0 | |
>>> qfac(4,3) | |
2080.0 | |
>>> qfac(5,6) | |
121226245.0 | |
>>> qfac(1+1j, 2+1j) | |
(0.4370556551322672478613695 + 0.2609739839216039203708921j) | |
""" | |
if ctx.isint(z) and ctx._re(z) > 0: | |
n = int(ctx._re(z)) | |
return ctx.qp(q, q, n, **kwargs) / (1-q)**n | |
return ctx.qgamma(z+1, q, **kwargs) | |
def qhyper(ctx, a_s, b_s, q, z, **kwargs): | |
r""" | |
Evaluates the basic hypergeometric series or hypergeometric q-series | |
.. math :: | |
\,_r\phi_s \left[\begin{matrix} | |
a_1 & a_2 & \ldots & a_r \\ | |
b_1 & b_2 & \ldots & b_s | |
\end{matrix} ; q,z \right] = | |
\sum_{n=0}^\infty | |
\frac{(a_1;q)_n, \ldots, (a_r;q)_n} | |
{(b_1;q)_n, \ldots, (b_s;q)_n} | |
\left((-1)^n q^{n\choose 2}\right)^{1+s-r} | |
\frac{z^n}{(q;q)_n} | |
where `(a;q)_n` denotes the q-Pochhammer symbol (see :func:`~mpmath.qp`). | |
**Examples** | |
Evaluation works for real and complex arguments:: | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> qhyper([0.5], [2.25], 0.25, 4) | |
-0.1975849091263356009534385 | |
>>> qhyper([0.5], [2.25], 0.25-0.25j, 4) | |
(2.806330244925716649839237 + 3.568997623337943121769938j) | |
>>> qhyper([1+j], [2,3+0.5j], 0.25, 3+4j) | |
(9.112885171773400017270226 - 1.272756997166375050700388j) | |
Comparing with a summation of the defining series, using | |
:func:`~mpmath.nsum`:: | |
>>> b, q, z = 3, 0.25, 0.5 | |
>>> qhyper([], [b], q, z) | |
0.6221136748254495583228324 | |
>>> nsum(lambda n: z**n / qp(q,q,n)/qp(b,q,n) * q**(n*(n-1)), [0,inf]) | |
0.6221136748254495583228324 | |
""" | |
#a_s = [ctx._convert_param(a)[0] for a in a_s] | |
#b_s = [ctx._convert_param(b)[0] for b in b_s] | |
#q = ctx._convert_param(q)[0] | |
a_s = [ctx.convert(a) for a in a_s] | |
b_s = [ctx.convert(b) for b in b_s] | |
q = ctx.convert(q) | |
z = ctx.convert(z) | |
r = len(a_s) | |
s = len(b_s) | |
d = 1+s-r | |
maxterms = kwargs.get('maxterms', 50*ctx.prec) | |
def terms(): | |
t = ctx.one | |
yield t | |
qk = 1 | |
k = 0 | |
x = 1 | |
while 1: | |
for a in a_s: | |
p = 1 - a*qk | |
t *= p | |
for b in b_s: | |
p = 1 - b*qk | |
if not p: | |
raise ValueError | |
t /= p | |
t *= z | |
x *= (-1)**d * qk ** d | |
qk *= q | |
t /= (1 - qk) | |
k += 1 | |
yield t * x | |
if k > maxterms: | |
raise ctx.NoConvergence | |
return ctx.sum_accurately(terms) | |