""" Extended docstrings for functions.py """ pi = r""" `\pi`, roughly equal to 3.141592654, represents the area of the unit circle, the half-period of trigonometric functions, and many other things in mathematics. Mpmath can evaluate `\pi` to arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +pi 3.1415926535897932384626433832795028841971693993751 This shows digits 99991-100000 of `\pi` (the last digit is actually a 4 when the decimal expansion is truncated, but here the nearest rounding is used):: >>> mp.dps = 100000 >>> str(pi)[-10:] '5549362465' **Possible issues** :data:`pi` always rounds to the nearest floating-point number when used. This means that exact mathematical identities involving `\pi` will generally not be preserved in floating-point arithmetic. In particular, multiples of :data:`pi` (except for the trivial case ``0*pi``) are *not* the exact roots of :func:`~mpmath.sin`, but differ roughly by the current epsilon:: >>> mp.dps = 15 >>> sin(pi) 1.22464679914735e-16 One solution is to use the :func:`~mpmath.sinpi` function instead:: >>> sinpi(1) 0.0 See the documentation of trigonometric functions for additional details. """ degree = r""" Represents one degree of angle, `1^{\circ} = \pi/180`, or about 0.01745329. This constant may be evaluated to arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +degree 0.017453292519943295769236907684886127134428718885417 The :data:`degree` object is convenient for conversion to radians:: >>> sin(30 * degree) 0.5 >>> asin(0.5) / degree 30.0 """ e = r""" The transcendental number `e` = 2.718281828... is the base of the natural logarithm (:func:`~mpmath.ln`) and of the exponential function (:func:`~mpmath.exp`). Mpmath can be evaluate `e` to arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +e 2.7182818284590452353602874713526624977572470937 This shows digits 99991-100000 of `e` (the last digit is actually a 5 when the decimal expansion is truncated, but here the nearest rounding is used):: >>> mp.dps = 100000 >>> str(e)[-10:] '2100427166' **Possible issues** :data:`e` always rounds to the nearest floating-point number when used, and mathematical identities involving `e` may not hold in floating-point arithmetic. For example, ``ln(e)`` might not evaluate exactly to 1. In particular, don't use ``e**x`` to compute the exponential function. Use ``exp(x)`` instead; this is both faster and more accurate. """ phi = r""" Represents the golden ratio `\phi = (1+\sqrt 5)/2`, approximately equal to 1.6180339887. To high precision, its value is:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +phi 1.6180339887498948482045868343656381177203091798058 Formulas for the golden ratio include the following:: >>> (1+sqrt(5))/2 1.6180339887498948482045868343656381177203091798058 >>> findroot(lambda x: x**2-x-1, 1) 1.6180339887498948482045868343656381177203091798058 >>> limit(lambda n: fib(n+1)/fib(n), inf) 1.6180339887498948482045868343656381177203091798058 """ euler = r""" Euler's constant or the Euler-Mascheroni constant `\gamma` = 0.57721566... is a number of central importance to number theory and special functions. It is defined as the limit .. math :: \gamma = \lim_{n\to\infty} H_n - \log n where `H_n = 1 + \frac{1}{2} + \ldots + \frac{1}{n}` is a harmonic number (see :func:`~mpmath.harmonic`). Evaluation of `\gamma` is supported at arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +euler 0.57721566490153286060651209008240243104215933593992 We can also compute `\gamma` directly from the definition, although this is less efficient:: >>> limit(lambda n: harmonic(n)-log(n), inf) 0.57721566490153286060651209008240243104215933593992 This shows digits 9991-10000 of `\gamma` (the last digit is actually a 5 when the decimal expansion is truncated, but here the nearest rounding is used):: >>> mp.dps = 10000 >>> str(euler)[-10:] '4679858166' Integrals, series, and representations for `\gamma` in terms of special functions include the following (there are many others):: >>> mp.dps = 25 >>> -quad(lambda x: exp(-x)*log(x), [0,inf]) 0.5772156649015328606065121 >>> quad(lambda x,y: (x-1)/(1-x*y)/log(x*y), [0,1], [0,1]) 0.5772156649015328606065121 >>> nsum(lambda k: 1/k-log(1+1/k), [1,inf]) 0.5772156649015328606065121 >>> nsum(lambda k: (-1)**k*zeta(k)/k, [2,inf]) 0.5772156649015328606065121 >>> -diff(gamma, 1) 0.5772156649015328606065121 >>> limit(lambda x: 1/x-gamma(x), 0) 0.5772156649015328606065121 >>> limit(lambda x: zeta(x)-1/(x-1), 1) 0.5772156649015328606065121 >>> (log(2*pi*nprod(lambda n: ... exp(-2+2/n)*(1+2/n)**n, [1,inf]))-3)/2 0.5772156649015328606065121 For generalizations of the identities `\gamma = -\Gamma'(1)` and `\gamma = \lim_{x\to1} \zeta(x)-1/(x-1)`, see :func:`~mpmath.psi` and :func:`~mpmath.stieltjes` respectively. """ catalan = r""" Catalan's constant `K` = 0.91596559... is given by the infinite series .. math :: K = \sum_{k=0}^{\infty} \frac{(-1)^k}{(2k+1)^2}. Mpmath can evaluate it to arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +catalan 0.91596559417721901505460351493238411077414937428167 One can also compute `K` directly from the definition, although this is significantly less efficient:: >>> nsum(lambda k: (-1)**k/(2*k+1)**2, [0, inf]) 0.91596559417721901505460351493238411077414937428167 This shows digits 9991-10000 of `K` (the last digit is actually a 3 when the decimal expansion is truncated, but here the nearest rounding is used):: >>> mp.dps = 10000 >>> str(catalan)[-10:] '9537871504' Catalan's constant has numerous integral representations:: >>> mp.dps = 50 >>> quad(lambda x: -log(x)/(1+x**2), [0, 1]) 0.91596559417721901505460351493238411077414937428167 >>> quad(lambda x: atan(x)/x, [0, 1]) 0.91596559417721901505460351493238411077414937428167 >>> quad(lambda x: ellipk(x**2)/2, [0, 1]) 0.91596559417721901505460351493238411077414937428167 >>> quad(lambda x,y: 1/(1+(x*y)**2), [0, 1], [0, 1]) 0.91596559417721901505460351493238411077414937428167 As well as series representations:: >>> pi*log(sqrt(3)+2)/8 + 3*nsum(lambda n: ... (fac(n)/(2*n+1))**2/fac(2*n), [0, inf])/8 0.91596559417721901505460351493238411077414937428167 >>> 1-nsum(lambda n: n*zeta(2*n+1)/16**n, [1,inf]) 0.91596559417721901505460351493238411077414937428167 """ khinchin = r""" Khinchin's constant `K` = 2.68542... is a number that appears in the theory of continued fractions. Mpmath can evaluate it to arbitrary precision:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +khinchin 2.6854520010653064453097148354817956938203822939945 An integral representation is:: >>> I = quad(lambda x: log((1-x**2)/sincpi(x))/x/(1+x), [0, 1]) >>> 2*exp(1/log(2)*I) 2.6854520010653064453097148354817956938203822939945 The computation of ``khinchin`` is based on an efficient implementation of the following series:: >>> f = lambda n: (zeta(2*n)-1)/n*sum((-1)**(k+1)/mpf(k) ... for k in range(1,2*int(n))) >>> exp(nsum(f, [1,inf])/log(2)) 2.6854520010653064453097148354817956938203822939945 """ glaisher = r""" Glaisher's constant `A`, also known as the Glaisher-Kinkelin constant, is a number approximately equal to 1.282427129 that sometimes appears in formulas related to gamma and zeta functions. It is also related to the Barnes G-function (see :func:`~mpmath.barnesg`). The constant is defined as `A = \exp(1/12-\zeta'(-1))` where `\zeta'(s)` denotes the derivative of the Riemann zeta function (see :func:`~mpmath.zeta`). Mpmath can evaluate Glaisher's constant to arbitrary precision: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +glaisher 1.282427129100622636875342568869791727767688927325 We can verify that the value computed by :data:`glaisher` is correct using mpmath's facilities for numerical differentiation and arbitrary evaluation of the zeta function: >>> exp(mpf(1)/12 - diff(zeta, -1)) 1.282427129100622636875342568869791727767688927325 Here is an example of an integral that can be evaluated in terms of Glaisher's constant: >>> mp.dps = 15 >>> quad(lambda x: log(gamma(x)), [1, 1.5]) -0.0428537406502909 >>> -0.5 - 7*log(2)/24 + log(pi)/4 + 3*log(glaisher)/2 -0.042853740650291 Mpmath computes Glaisher's constant by applying Euler-Maclaurin summation to a slowly convergent series. The implementation is reasonably efficient up to about 10,000 digits. See the source code for additional details. References: http://mathworld.wolfram.com/Glaisher-KinkelinConstant.html """ apery = r""" Represents Apery's constant, which is the irrational number approximately equal to 1.2020569 given by .. math :: \zeta(3) = \sum_{k=1}^\infty\frac{1}{k^3}. The calculation is based on an efficient hypergeometric series. To 50 decimal places, the value is given by:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +apery 1.2020569031595942853997381615114499907649862923405 Other ways to evaluate Apery's constant using mpmath include:: >>> zeta(3) 1.2020569031595942853997381615114499907649862923405 >>> -psi(2,1)/2 1.2020569031595942853997381615114499907649862923405 >>> 8*nsum(lambda k: 1/(2*k+1)**3, [0,inf])/7 1.2020569031595942853997381615114499907649862923405 >>> f = lambda k: 2/k**3/(exp(2*pi*k)-1) >>> 7*pi**3/180 - nsum(f, [1,inf]) 1.2020569031595942853997381615114499907649862923405 This shows digits 9991-10000 of Apery's constant:: >>> mp.dps = 10000 >>> str(apery)[-10:] '3189504235' """ mertens = r""" Represents the Mertens or Meissel-Mertens constant, which is the prime number analog of Euler's constant: .. math :: B_1 = \lim_{N\to\infty} \left(\sum_{p_k \le N} \frac{1}{p_k} - \log \log N \right) Here `p_k` denotes the `k`-th prime number. Other names for this constant include the Hadamard-de la Vallee-Poussin constant or the prime reciprocal constant. The following gives the Mertens constant to 50 digits:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +mertens 0.2614972128476427837554268386086958590515666482612 References: http://mathworld.wolfram.com/MertensConstant.html """ twinprime = r""" Represents the twin prime constant, which is the factor `C_2` featuring in the Hardy-Littlewood conjecture for the growth of the twin prime counting function, .. math :: \pi_2(n) \sim 2 C_2 \frac{n}{\log^2 n}. It is given by the product over primes .. math :: C_2 = \prod_{p\ge3} \frac{p(p-2)}{(p-1)^2} \approx 0.66016 Computing `C_2` to 50 digits:: >>> from mpmath import * >>> mp.dps = 50; mp.pretty = True >>> +twinprime 0.66016181584686957392781211001455577843262336028473 References: http://mathworld.wolfram.com/TwinPrimesConstant.html """ ln = r""" Computes the natural logarithm of `x`, `\ln x`. See :func:`~mpmath.log` for additional documentation.""" sqrt = r""" ``sqrt(x)`` gives the principal square root of `x`, `\sqrt x`. For positive real numbers, the principal root is simply the positive square root. For arbitrary complex numbers, the principal square root is defined to satisfy `\sqrt x = \exp(\log(x)/2)`. The function thus has a branch cut along the negative half real axis. For all mpmath numbers ``x``, calling ``sqrt(x)`` is equivalent to performing ``x**0.5``. **Examples** Basic examples and limits:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> sqrt(10) 3.16227766016838 >>> sqrt(100) 10.0 >>> sqrt(-4) (0.0 + 2.0j) >>> sqrt(1+1j) (1.09868411346781 + 0.455089860562227j) >>> sqrt(inf) +inf Square root evaluation is fast at huge precision:: >>> mp.dps = 50000 >>> a = sqrt(3) >>> str(a)[-10:] '9329332815' :func:`mpmath.iv.sqrt` supports interval arguments:: >>> iv.dps = 15; iv.pretty = True >>> iv.sqrt([16,100]) [4.0, 10.0] >>> iv.sqrt(2) [1.4142135623730949234, 1.4142135623730951455] >>> iv.sqrt(2) ** 2 [1.9999999999999995559, 2.0000000000000004441] """ cbrt = r""" ``cbrt(x)`` computes the cube root of `x`, `x^{1/3}`. This function is faster and more accurate than raising to a floating-point fraction:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> 125**(mpf(1)/3) mpf('4.9999999999999991') >>> cbrt(125) mpf('5.0') Every nonzero complex number has three cube roots. This function returns the cube root defined by `\exp(\log(x)/3)` where the principal branch of the natural logarithm is used. Note that this does not give a real cube root for negative real numbers:: >>> mp.pretty = True >>> cbrt(-1) (0.5 + 0.866025403784439j) """ exp = r""" Computes the exponential function, .. math :: \exp(x) = e^x = \sum_{k=0}^{\infty} \frac{x^k}{k!}. For complex numbers, the exponential function also satisfies .. math :: \exp(x+yi) = e^x (\cos y + i \sin y). **Basic examples** Some values of the exponential function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> exp(0) 1.0 >>> exp(1) 2.718281828459045235360287 >>> exp(-1) 0.3678794411714423215955238 >>> exp(inf) +inf >>> exp(-inf) 0.0 Arguments can be arbitrarily large:: >>> exp(10000) 8.806818225662921587261496e+4342 >>> exp(-10000) 1.135483865314736098540939e-4343 Evaluation is supported for interval arguments via :func:`mpmath.iv.exp`:: >>> iv.dps = 25; iv.pretty = True >>> iv.exp([-inf,0]) [0.0, 1.0] >>> iv.exp([0,1]) [1.0, 2.71828182845904523536028749558] The exponential function can be evaluated efficiently to arbitrary precision:: >>> mp.dps = 10000 >>> exp(pi) #doctest: +ELLIPSIS 23.140692632779269005729...8984304016040616 **Functional properties** Numerical verification of Euler's identity for the complex exponential function:: >>> mp.dps = 15 >>> exp(j*pi)+1 (0.0 + 1.22464679914735e-16j) >>> chop(exp(j*pi)+1) 0.0 This recovers the coefficients (reciprocal factorials) in the Maclaurin series expansion of exp:: >>> nprint(taylor(exp, 0, 5)) [1.0, 1.0, 0.5, 0.166667, 0.0416667, 0.00833333] The exponential function is its own derivative and antiderivative:: >>> exp(pi) 23.1406926327793 >>> diff(exp, pi) 23.1406926327793 >>> quad(exp, [-inf, pi]) 23.1406926327793 The exponential function can be evaluated using various methods, including direct summation of the series, limits, and solving the defining differential equation:: >>> nsum(lambda k: pi**k/fac(k), [0,inf]) 23.1406926327793 >>> limit(lambda k: (1+pi/k)**k, inf) 23.1406926327793 >>> odefun(lambda t, x: x, 0, 1)(pi) 23.1406926327793 """ cosh = r""" Computes the hyperbolic cosine of `x`, `\cosh(x) = (e^x + e^{-x})/2`. Values and limits include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> cosh(0) 1.0 >>> cosh(1) 1.543080634815243778477906 >>> cosh(-inf), cosh(+inf) (+inf, +inf) The hyperbolic cosine is an even, convex function with a global minimum at `x = 0`, having a Maclaurin series that starts:: >>> nprint(chop(taylor(cosh, 0, 5))) [1.0, 0.0, 0.5, 0.0, 0.0416667, 0.0] Generalized to complex numbers, the hyperbolic cosine is equivalent to a cosine with the argument rotated in the imaginary direction, or `\cosh x = \cos ix`:: >>> cosh(2+3j) (-3.724545504915322565473971 + 0.5118225699873846088344638j) >>> cos(3-2j) (-3.724545504915322565473971 + 0.5118225699873846088344638j) """ sinh = r""" Computes the hyperbolic sine of `x`, `\sinh(x) = (e^x - e^{-x})/2`. Values and limits include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> sinh(0) 0.0 >>> sinh(1) 1.175201193643801456882382 >>> sinh(-inf), sinh(+inf) (-inf, +inf) The hyperbolic sine is an odd function, with a Maclaurin series that starts:: >>> nprint(chop(taylor(sinh, 0, 5))) [0.0, 1.0, 0.0, 0.166667, 0.0, 0.00833333] Generalized to complex numbers, the hyperbolic sine is essentially a sine with a rotation `i` applied to the argument; more precisely, `\sinh x = -i \sin ix`:: >>> sinh(2+3j) (-3.590564589985779952012565 + 0.5309210862485198052670401j) >>> j*sin(3-2j) (-3.590564589985779952012565 + 0.5309210862485198052670401j) """ tanh = r""" Computes the hyperbolic tangent of `x`, `\tanh(x) = \sinh(x)/\cosh(x)`. Values and limits include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> tanh(0) 0.0 >>> tanh(1) 0.7615941559557648881194583 >>> tanh(-inf), tanh(inf) (-1.0, 1.0) The hyperbolic tangent is an odd, sigmoidal function, similar to the inverse tangent and error function. Its Maclaurin series is:: >>> nprint(chop(taylor(tanh, 0, 5))) [0.0, 1.0, 0.0, -0.333333, 0.0, 0.133333] Generalized to complex numbers, the hyperbolic tangent is essentially a tangent with a rotation `i` applied to the argument; more precisely, `\tanh x = -i \tan ix`:: >>> tanh(2+3j) (0.9653858790221331242784803 - 0.009884375038322493720314034j) >>> j*tan(3-2j) (0.9653858790221331242784803 - 0.009884375038322493720314034j) """ cos = r""" Computes the cosine of `x`, `\cos(x)`. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> cos(pi/3) 0.5 >>> cos(100000001) -0.9802850113244713353133243 >>> cos(2+3j) (-4.189625690968807230132555 - 9.109227893755336597979197j) >>> cos(inf) nan >>> nprint(chop(taylor(cos, 0, 6))) [1.0, 0.0, -0.5, 0.0, 0.0416667, 0.0, -0.00138889] Intervals are supported via :func:`mpmath.iv.cos`:: >>> iv.dps = 25; iv.pretty = True >>> iv.cos([0,1]) [0.540302305868139717400936602301, 1.0] >>> iv.cos([0,2]) [-0.41614683654714238699756823214, 1.0] """ sin = r""" Computes the sine of `x`, `\sin(x)`. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> sin(pi/3) 0.8660254037844386467637232 >>> sin(100000001) 0.1975887055794968911438743 >>> sin(2+3j) (9.1544991469114295734673 - 4.168906959966564350754813j) >>> sin(inf) nan >>> nprint(chop(taylor(sin, 0, 6))) [0.0, 1.0, 0.0, -0.166667, 0.0, 0.00833333, 0.0] Intervals are supported via :func:`mpmath.iv.sin`:: >>> iv.dps = 25; iv.pretty = True >>> iv.sin([0,1]) [0.0, 0.841470984807896506652502331201] >>> iv.sin([0,2]) [0.0, 1.0] """ tan = r""" Computes the tangent of `x`, `\tan(x) = \frac{\sin(x)}{\cos(x)}`. The tangent function is singular at `x = (n+1/2)\pi`, but ``tan(x)`` always returns a finite result since `(n+1/2)\pi` cannot be represented exactly using floating-point arithmetic. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> tan(pi/3) 1.732050807568877293527446 >>> tan(100000001) -0.2015625081449864533091058 >>> tan(2+3j) (-0.003764025641504248292751221 + 1.003238627353609801446359j) >>> tan(inf) nan >>> nprint(chop(taylor(tan, 0, 6))) [0.0, 1.0, 0.0, 0.333333, 0.0, 0.133333, 0.0] Intervals are supported via :func:`mpmath.iv.tan`:: >>> iv.dps = 25; iv.pretty = True >>> iv.tan([0,1]) [0.0, 1.55740772465490223050697482944] >>> iv.tan([0,2]) # Interval includes a singularity [-inf, +inf] """ sec = r""" Computes the secant of `x`, `\mathrm{sec}(x) = \frac{1}{\cos(x)}`. The secant function is singular at `x = (n+1/2)\pi`, but ``sec(x)`` always returns a finite result since `(n+1/2)\pi` cannot be represented exactly using floating-point arithmetic. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> sec(pi/3) 2.0 >>> sec(10000001) -1.184723164360392819100265 >>> sec(2+3j) (-0.04167496441114427004834991 + 0.0906111371962375965296612j) >>> sec(inf) nan >>> nprint(chop(taylor(sec, 0, 6))) [1.0, 0.0, 0.5, 0.0, 0.208333, 0.0, 0.0847222] Intervals are supported via :func:`mpmath.iv.sec`:: >>> iv.dps = 25; iv.pretty = True >>> iv.sec([0,1]) [1.0, 1.85081571768092561791175326276] >>> iv.sec([0,2]) # Interval includes a singularity [-inf, +inf] """ csc = r""" Computes the cosecant of `x`, `\mathrm{csc}(x) = \frac{1}{\sin(x)}`. This cosecant function is singular at `x = n \pi`, but with the exception of the point `x = 0`, ``csc(x)`` returns a finite result since `n \pi` cannot be represented exactly using floating-point arithmetic. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> csc(pi/3) 1.154700538379251529018298 >>> csc(10000001) -1.864910497503629858938891 >>> csc(2+3j) (0.09047320975320743980579048 + 0.04120098628857412646300981j) >>> csc(inf) nan Intervals are supported via :func:`mpmath.iv.csc`:: >>> iv.dps = 25; iv.pretty = True >>> iv.csc([0,1]) # Interval includes a singularity [1.18839510577812121626159943988, +inf] >>> iv.csc([0,2]) [1.0, +inf] """ cot = r""" Computes the cotangent of `x`, `\mathrm{cot}(x) = \frac{1}{\tan(x)} = \frac{\cos(x)}{\sin(x)}`. This cotangent function is singular at `x = n \pi`, but with the exception of the point `x = 0`, ``cot(x)`` returns a finite result since `n \pi` cannot be represented exactly using floating-point arithmetic. >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> cot(pi/3) 0.5773502691896257645091488 >>> cot(10000001) 1.574131876209625656003562 >>> cot(2+3j) (-0.003739710376336956660117409 - 0.9967577965693583104609688j) >>> cot(inf) nan Intervals are supported via :func:`mpmath.iv.cot`:: >>> iv.dps = 25; iv.pretty = True >>> iv.cot([0,1]) # Interval includes a singularity [0.642092615934330703006419974862, +inf] >>> iv.cot([1,2]) [-inf, +inf] """ acos = r""" Computes the inverse cosine or arccosine of `x`, `\cos^{-1}(x)`. Since `-1 \le \cos(x) \le 1` for real `x`, the inverse cosine is real-valued only for `-1 \le x \le 1`. On this interval, :func:`~mpmath.acos` is defined to be a monotonically decreasing function assuming values between `+\pi` and `0`. Basic values are:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> acos(-1) 3.141592653589793238462643 >>> acos(0) 1.570796326794896619231322 >>> acos(1) 0.0 >>> nprint(chop(taylor(acos, 0, 6))) [1.5708, -1.0, 0.0, -0.166667, 0.0, -0.075, 0.0] :func:`~mpmath.acos` is defined so as to be a proper inverse function of `\cos(\theta)` for `0 \le \theta < \pi`. We have `\cos(\cos^{-1}(x)) = x` for all `x`, but `\cos^{-1}(\cos(x)) = x` only for `0 \le \Re[x] < \pi`:: >>> for x in [1, 10, -1, 2+3j, 10+3j]: ... print("%s %s" % (cos(acos(x)), acos(cos(x)))) ... 1.0 1.0 (10.0 + 0.0j) 2.566370614359172953850574 -1.0 1.0 (2.0 + 3.0j) (2.0 + 3.0j) (10.0 + 3.0j) (2.566370614359172953850574 - 3.0j) The inverse cosine has two branch points: `x = \pm 1`. :func:`~mpmath.acos` places the branch cuts along the line segments `(-\infty, -1)` and `(+1, +\infty)`. In general, .. math :: \cos^{-1}(x) = \frac{\pi}{2} + i \log\left(ix + \sqrt{1-x^2} \right) where the principal-branch log and square root are implied. """ asin = r""" Computes the inverse sine or arcsine of `x`, `\sin^{-1}(x)`. Since `-1 \le \sin(x) \le 1` for real `x`, the inverse sine is real-valued only for `-1 \le x \le 1`. On this interval, it is defined to be a monotonically increasing function assuming values between `-\pi/2` and `\pi/2`. Basic values are:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> asin(-1) -1.570796326794896619231322 >>> asin(0) 0.0 >>> asin(1) 1.570796326794896619231322 >>> nprint(chop(taylor(asin, 0, 6))) [0.0, 1.0, 0.0, 0.166667, 0.0, 0.075, 0.0] :func:`~mpmath.asin` is defined so as to be a proper inverse function of `\sin(\theta)` for `-\pi/2 < \theta < \pi/2`. We have `\sin(\sin^{-1}(x)) = x` for all `x`, but `\sin^{-1}(\sin(x)) = x` only for `-\pi/2 < \Re[x] < \pi/2`:: >>> for x in [1, 10, -1, 1+3j, -2+3j]: ... print("%s %s" % (chop(sin(asin(x))), asin(sin(x)))) ... 1.0 1.0 10.0 -0.5752220392306202846120698 -1.0 -1.0 (1.0 + 3.0j) (1.0 + 3.0j) (-2.0 + 3.0j) (-1.141592653589793238462643 - 3.0j) The inverse sine has two branch points: `x = \pm 1`. :func:`~mpmath.asin` places the branch cuts along the line segments `(-\infty, -1)` and `(+1, +\infty)`. In general, .. math :: \sin^{-1}(x) = -i \log\left(ix + \sqrt{1-x^2} \right) where the principal-branch log and square root are implied. """ atan = r""" Computes the inverse tangent or arctangent of `x`, `\tan^{-1}(x)`. This is a real-valued function for all real `x`, with range `(-\pi/2, \pi/2)`. Basic values are:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> atan(-inf) -1.570796326794896619231322 >>> atan(-1) -0.7853981633974483096156609 >>> atan(0) 0.0 >>> atan(1) 0.7853981633974483096156609 >>> atan(inf) 1.570796326794896619231322 >>> nprint(chop(taylor(atan, 0, 6))) [0.0, 1.0, 0.0, -0.333333, 0.0, 0.2, 0.0] The inverse tangent is often used to compute angles. However, the atan2 function is often better for this as it preserves sign (see :func:`~mpmath.atan2`). :func:`~mpmath.atan` is defined so as to be a proper inverse function of `\tan(\theta)` for `-\pi/2 < \theta < \pi/2`. We have `\tan(\tan^{-1}(x)) = x` for all `x`, but `\tan^{-1}(\tan(x)) = x` only for `-\pi/2 < \Re[x] < \pi/2`:: >>> mp.dps = 25 >>> for x in [1, 10, -1, 1+3j, -2+3j]: ... print("%s %s" % (tan(atan(x)), atan(tan(x)))) ... 1.0 1.0 10.0 0.5752220392306202846120698 -1.0 -1.0 (1.0 + 3.0j) (1.000000000000000000000001 + 3.0j) (-2.0 + 3.0j) (1.141592653589793238462644 + 3.0j) The inverse tangent has two branch points: `x = \pm i`. :func:`~mpmath.atan` places the branch cuts along the line segments `(-i \infty, -i)` and `(+i, +i \infty)`. In general, .. math :: \tan^{-1}(x) = \frac{i}{2}\left(\log(1-ix)-\log(1+ix)\right) where the principal-branch log is implied. """ acot = r"""Computes the inverse cotangent of `x`, `\mathrm{cot}^{-1}(x) = \tan^{-1}(1/x)`.""" asec = r"""Computes the inverse secant of `x`, `\mathrm{sec}^{-1}(x) = \cos^{-1}(1/x)`.""" acsc = r"""Computes the inverse cosecant of `x`, `\mathrm{csc}^{-1}(x) = \sin^{-1}(1/x)`.""" coth = r"""Computes the hyperbolic cotangent of `x`, `\mathrm{coth}(x) = \frac{\cosh(x)}{\sinh(x)}`. """ sech = r"""Computes the hyperbolic secant of `x`, `\mathrm{sech}(x) = \frac{1}{\cosh(x)}`. """ csch = r"""Computes the hyperbolic cosecant of `x`, `\mathrm{csch}(x) = \frac{1}{\sinh(x)}`. """ acosh = r"""Computes the inverse hyperbolic cosine of `x`, `\mathrm{cosh}^{-1}(x) = \log(x+\sqrt{x+1}\sqrt{x-1})`. """ asinh = r"""Computes the inverse hyperbolic sine of `x`, `\mathrm{sinh}^{-1}(x) = \log(x+\sqrt{1+x^2})`. """ atanh = r"""Computes the inverse hyperbolic tangent of `x`, `\mathrm{tanh}^{-1}(x) = \frac{1}{2}\left(\log(1+x)-\log(1-x)\right)`. """ acoth = r"""Computes the inverse hyperbolic cotangent of `x`, `\mathrm{coth}^{-1}(x) = \tanh^{-1}(1/x)`.""" asech = r"""Computes the inverse hyperbolic secant of `x`, `\mathrm{sech}^{-1}(x) = \cosh^{-1}(1/x)`.""" acsch = r"""Computes the inverse hyperbolic cosecant of `x`, `\mathrm{csch}^{-1}(x) = \sinh^{-1}(1/x)`.""" sinpi = r""" Computes `\sin(\pi x)`, more accurately than the expression ``sin(pi*x)``:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> sinpi(10**10), sin(pi*(10**10)) (0.0, -2.23936276195592e-6) >>> sinpi(10**10+0.5), sin(pi*(10**10+0.5)) (1.0, 0.999999999998721) """ cospi = r""" Computes `\cos(\pi x)`, more accurately than the expression ``cos(pi*x)``:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> cospi(10**10), cos(pi*(10**10)) (1.0, 0.999999999997493) >>> cospi(10**10+0.5), cos(pi*(10**10+0.5)) (0.0, 1.59960492420134e-6) """ sinc = r""" ``sinc(x)`` computes the unnormalized sinc function, defined as .. math :: \mathrm{sinc}(x) = \begin{cases} \sin(x)/x, & \mbox{if } x \ne 0 \\ 1, & \mbox{if } x = 0. \end{cases} See :func:`~mpmath.sincpi` for the normalized sinc function. Simple values and limits include:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> sinc(0) 1.0 >>> sinc(1) 0.841470984807897 >>> sinc(inf) 0.0 The integral of the sinc function is the sine integral Si:: >>> quad(sinc, [0, 1]) 0.946083070367183 >>> si(1) 0.946083070367183 """ sincpi = r""" ``sincpi(x)`` computes the normalized sinc function, defined as .. math :: \mathrm{sinc}_{\pi}(x) = \begin{cases} \sin(\pi x)/(\pi x), & \mbox{if } x \ne 0 \\ 1, & \mbox{if } x = 0. \end{cases} Equivalently, we have `\mathrm{sinc}_{\pi}(x) = \mathrm{sinc}(\pi x)`. The normalization entails that the function integrates to unity over the entire real line:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> quadosc(sincpi, [-inf, inf], period=2.0) 1.0 Like, :func:`~mpmath.sinpi`, :func:`~mpmath.sincpi` is evaluated accurately at its roots:: >>> sincpi(10) 0.0 """ expj = r""" Convenience function for computing `e^{ix}`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> expj(0) (1.0 + 0.0j) >>> expj(-1) (0.5403023058681397174009366 - 0.8414709848078965066525023j) >>> expj(j) (0.3678794411714423215955238 + 0.0j) >>> expj(1+j) (0.1987661103464129406288032 + 0.3095598756531121984439128j) """ expjpi = r""" Convenience function for computing `e^{i \pi x}`. Evaluation is accurate near zeros (see also :func:`~mpmath.cospi`, :func:`~mpmath.sinpi`):: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> expjpi(0) (1.0 + 0.0j) >>> expjpi(1) (-1.0 + 0.0j) >>> expjpi(0.5) (0.0 + 1.0j) >>> expjpi(-1) (-1.0 + 0.0j) >>> expjpi(j) (0.04321391826377224977441774 + 0.0j) >>> expjpi(1+j) (-0.04321391826377224977441774 + 0.0j) """ floor = r""" Computes the floor of `x`, `\lfloor x \rfloor`, defined as the largest integer less than or equal to `x`:: >>> from mpmath import * >>> mp.pretty = False >>> floor(3.5) mpf('3.0') .. note :: :func:`~mpmath.floor`, :func:`~mpmath.ceil` and :func:`~mpmath.nint` return a floating-point number, not a Python ``int``. If `\lfloor x \rfloor` is too large to be represented exactly at the present working precision, the result will be rounded, not necessarily in the direction implied by the mathematical definition of the function. To avoid rounding, use *prec=0*:: >>> mp.dps = 15 >>> print(int(floor(10**30+1))) 1000000000000000019884624838656 >>> print(int(floor(10**30+1, prec=0))) 1000000000000000000000000000001 The floor function is defined for complex numbers and acts on the real and imaginary parts separately:: >>> floor(3.25+4.75j) mpc(real='3.0', imag='4.0') """ ceil = r""" Computes the ceiling of `x`, `\lceil x \rceil`, defined as the smallest integer greater than or equal to `x`:: >>> from mpmath import * >>> mp.pretty = False >>> ceil(3.5) mpf('4.0') The ceiling function is defined for complex numbers and acts on the real and imaginary parts separately:: >>> ceil(3.25+4.75j) mpc(real='4.0', imag='5.0') See notes about rounding for :func:`~mpmath.floor`. """ nint = r""" Evaluates the nearest integer function, `\mathrm{nint}(x)`. This gives the nearest integer to `x`; on a tie, it gives the nearest even integer:: >>> from mpmath import * >>> mp.pretty = False >>> nint(3.2) mpf('3.0') >>> nint(3.8) mpf('4.0') >>> nint(3.5) mpf('4.0') >>> nint(4.5) mpf('4.0') The nearest integer function is defined for complex numbers and acts on the real and imaginary parts separately:: >>> nint(3.25+4.75j) mpc(real='3.0', imag='5.0') See notes about rounding for :func:`~mpmath.floor`. """ frac = r""" Gives the fractional part of `x`, defined as `\mathrm{frac}(x) = x - \lfloor x \rfloor` (see :func:`~mpmath.floor`). In effect, this computes `x` modulo 1, or `x+n` where `n \in \mathbb{Z}` is such that `x+n \in [0,1)`:: >>> from mpmath import * >>> mp.pretty = False >>> frac(1.25) mpf('0.25') >>> frac(3) mpf('0.0') >>> frac(-1.25) mpf('0.75') For a complex number, the fractional part function applies to the real and imaginary parts separately:: >>> frac(2.25+3.75j) mpc(real='0.25', imag='0.75') Plotted, the fractional part function gives a sawtooth wave. The Fourier series coefficients have a simple form:: >>> mp.dps = 15 >>> nprint(fourier(lambda x: frac(x)-0.5, [0,1], 4)) ([0.0, 0.0, 0.0, 0.0, 0.0], [0.0, -0.31831, -0.159155, -0.106103, -0.0795775]) >>> nprint([-1/(pi*k) for k in range(1,5)]) [-0.31831, -0.159155, -0.106103, -0.0795775] .. note:: The fractional part is sometimes defined as a symmetric function, i.e. returning `-\mathrm{frac}(-x)` if `x < 0`. This convention is used, for instance, by Mathematica's ``FractionalPart``. """ sign = r""" Returns the sign of `x`, defined as `\mathrm{sign}(x) = x / |x|` (with the special case `\mathrm{sign}(0) = 0`):: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> sign(10) mpf('1.0') >>> sign(-10) mpf('-1.0') >>> sign(0) mpf('0.0') Note that the sign function is also defined for complex numbers, for which it gives the projection onto the unit circle:: >>> mp.dps = 15; mp.pretty = True >>> sign(1+j) (0.707106781186547 + 0.707106781186547j) """ arg = r""" Computes the complex argument (phase) of `x`, defined as the signed angle between the positive real axis and `x` in the complex plane:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> arg(3) 0.0 >>> arg(3+3j) 0.785398163397448 >>> arg(3j) 1.5707963267949 >>> arg(-3) 3.14159265358979 >>> arg(-3j) -1.5707963267949 The angle is defined to satisfy `-\pi < \arg(x) \le \pi` and with the sign convention that a nonnegative imaginary part results in a nonnegative argument. The value returned by :func:`~mpmath.arg` is an ``mpf`` instance. """ fabs = r""" Returns the absolute value of `x`, `|x|`. Unlike :func:`abs`, :func:`~mpmath.fabs` converts non-mpmath numbers (such as ``int``) into mpmath numbers:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> fabs(3) mpf('3.0') >>> fabs(-3) mpf('3.0') >>> fabs(3+4j) mpf('5.0') """ re = r""" Returns the real part of `x`, `\Re(x)`. :func:`~mpmath.re` converts a non-mpmath number to an mpmath number:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> re(3) mpf('3.0') >>> re(-1+4j) mpf('-1.0') """ im = r""" Returns the imaginary part of `x`, `\Im(x)`. :func:`~mpmath.im` converts a non-mpmath number to an mpmath number:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> im(3) mpf('0.0') >>> im(-1+4j) mpf('4.0') """ conj = r""" Returns the complex conjugate of `x`, `\overline{x}`. Unlike ``x.conjugate()``, :func:`~mpmath.im` converts `x` to a mpmath number:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> conj(3) mpf('3.0') >>> conj(-1+4j) mpc(real='-1.0', imag='-4.0') """ polar = r""" Returns the polar representation of the complex number `z` as a pair `(r, \phi)` such that `z = r e^{i \phi}`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> polar(-2) (2.0, 3.14159265358979) >>> polar(3-4j) (5.0, -0.927295218001612) """ rect = r""" Returns the complex number represented by polar coordinates `(r, \phi)`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> chop(rect(2, pi)) -2.0 >>> rect(sqrt(2), -pi/4) (1.0 - 1.0j) """ expm1 = r""" Computes `e^x - 1`, accurately for small `x`. Unlike the expression ``exp(x) - 1``, ``expm1(x)`` does not suffer from potentially catastrophic cancellation:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> exp(1e-10)-1; print(expm1(1e-10)) 1.00000008274037e-10 1.00000000005e-10 >>> exp(1e-20)-1; print(expm1(1e-20)) 0.0 1.0e-20 >>> 1/(exp(1e-20)-1) Traceback (most recent call last): ... ZeroDivisionError >>> 1/expm1(1e-20) 1.0e+20 Evaluation works for extremely tiny values:: >>> expm1(0) 0.0 >>> expm1('1e-10000000') 1.0e-10000000 """ log1p = r""" Computes `\log(1+x)`, accurately for small `x`. >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> log(1+1e-10); print(mp.log1p(1e-10)) 1.00000008269037e-10 9.9999999995e-11 >>> mp.log1p(1e-100j) (5.0e-201 + 1.0e-100j) >>> mp.log1p(0) 0.0 """ powm1 = r""" Computes `x^y - 1`, accurately when `x^y` is very close to 1. This avoids potentially catastrophic cancellation:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> power(0.99999995, 1e-10) - 1 0.0 >>> powm1(0.99999995, 1e-10) -5.00000012791934e-18 Powers exactly equal to 1, and only those powers, yield 0 exactly:: >>> powm1(-j, 4) (0.0 + 0.0j) >>> powm1(3, 0) 0.0 >>> powm1(fadd(-1, 1e-100, exact=True), 4) -4.0e-100 Evaluation works for extremely tiny `y`:: >>> powm1(2, '1e-100000') 6.93147180559945e-100001 >>> powm1(j, '1e-1000') (-1.23370055013617e-2000 + 1.5707963267949e-1000j) """ root = r""" ``root(z, n, k=0)`` computes an `n`-th root of `z`, i.e. returns a number `r` that (up to possible approximation error) satisfies `r^n = z`. (``nthroot`` is available as an alias for ``root``.) Every complex number `z \ne 0` has `n` distinct `n`-th roots, which are equidistant points on a circle with radius `|z|^{1/n}`, centered around the origin. A specific root may be selected using the optional index `k`. The roots are indexed counterclockwise, starting with `k = 0` for the root closest to the positive real half-axis. The `k = 0` root is the so-called principal `n`-th root, often denoted by `\sqrt[n]{z}` or `z^{1/n}`, and also given by `\exp(\log(z) / n)`. If `z` is a positive real number, the principal root is just the unique positive `n`-th root of `z`. Under some circumstances, non-principal real roots exist: for positive real `z`, `n` even, there is a negative root given by `k = n/2`; for negative real `z`, `n` odd, there is a negative root given by `k = (n-1)/2`. To obtain all roots with a simple expression, use ``[root(z,n,k) for k in range(n)]``. An important special case, ``root(1, n, k)`` returns the `k`-th `n`-th root of unity, `\zeta_k = e^{2 \pi i k / n}`. Alternatively, :func:`~mpmath.unitroots` provides a slightly more convenient way to obtain the roots of unity, including the option to compute only the primitive roots of unity. Both `k` and `n` should be integers; `k` outside of ``range(n)`` will be reduced modulo `n`. If `n` is negative, `x^{-1/n} = 1/x^{1/n}` (or the equivalent reciprocal for a non-principal root with `k \ne 0`) is computed. :func:`~mpmath.root` is implemented to use Newton's method for small `n`. At high precision, this makes `x^{1/n}` not much more expensive than the regular exponentiation, `x^n`. For very large `n`, :func:`~mpmath.nthroot` falls back to use the exponential function. **Examples** :func:`~mpmath.nthroot`/:func:`~mpmath.root` is faster and more accurate than raising to a floating-point fraction:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = False >>> 16807 ** (mpf(1)/5) mpf('7.0000000000000009') >>> root(16807, 5) mpf('7.0') >>> nthroot(16807, 5) # Alias mpf('7.0') A high-precision root:: >>> mp.dps = 50; mp.pretty = True >>> nthroot(10, 5) 1.584893192461113485202101373391507013269442133825 >>> nthroot(10, 5) ** 5 10.0 Computing principal and non-principal square and cube roots:: >>> mp.dps = 15 >>> root(10, 2) 3.16227766016838 >>> root(10, 2, 1) -3.16227766016838 >>> root(-10, 3) (1.07721734501594 + 1.86579517236206j) >>> root(-10, 3, 1) -2.15443469003188 >>> root(-10, 3, 2) (1.07721734501594 - 1.86579517236206j) All the 7th roots of a complex number:: >>> for r in [root(3+4j, 7, k) for k in range(7)]: ... print("%s %s" % (r, r**7)) ... (1.24747270589553 + 0.166227124177353j) (3.0 + 4.0j) (0.647824911301003 + 1.07895435170559j) (3.0 + 4.0j) (-0.439648254723098 + 1.17920694574172j) (3.0 + 4.0j) (-1.19605731775069 + 0.391492658196305j) (3.0 + 4.0j) (-1.05181082538903 - 0.691023585965793j) (3.0 + 4.0j) (-0.115529328478668 - 1.25318497558335j) (3.0 + 4.0j) (0.907748109144957 - 0.871672518271819j) (3.0 + 4.0j) Cube roots of unity:: >>> for k in range(3): print(root(1, 3, k)) ... 1.0 (-0.5 + 0.866025403784439j) (-0.5 - 0.866025403784439j) Some exact high order roots:: >>> root(75**210, 105) 5625.0 >>> root(1, 128, 96) (0.0 - 1.0j) >>> root(4**128, 128, 96) (0.0 - 4.0j) """ unitroots = r""" ``unitroots(n)`` returns `\zeta_0, \zeta_1, \ldots, \zeta_{n-1}`, all the distinct `n`-th roots of unity, as a list. If the option *primitive=True* is passed, only the primitive roots are returned. Every `n`-th root of unity satisfies `(\zeta_k)^n = 1`. There are `n` distinct roots for each `n` (`\zeta_k` and `\zeta_j` are the same when `k = j \pmod n`), which form a regular polygon with vertices on the unit circle. They are ordered counterclockwise with increasing `k`, starting with `\zeta_0 = 1`. **Examples** The roots of unity up to `n = 4`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> nprint(unitroots(1)) [1.0] >>> nprint(unitroots(2)) [1.0, -1.0] >>> nprint(unitroots(3)) [1.0, (-0.5 + 0.866025j), (-0.5 - 0.866025j)] >>> nprint(unitroots(4)) [1.0, (0.0 + 1.0j), -1.0, (0.0 - 1.0j)] Roots of unity form a geometric series that sums to 0:: >>> mp.dps = 50 >>> chop(fsum(unitroots(25))) 0.0 Primitive roots up to `n = 4`:: >>> mp.dps = 15 >>> nprint(unitroots(1, primitive=True)) [1.0] >>> nprint(unitroots(2, primitive=True)) [-1.0] >>> nprint(unitroots(3, primitive=True)) [(-0.5 + 0.866025j), (-0.5 - 0.866025j)] >>> nprint(unitroots(4, primitive=True)) [(0.0 + 1.0j), (0.0 - 1.0j)] There are only four primitive 12th roots:: >>> nprint(unitroots(12, primitive=True)) [(0.866025 + 0.5j), (-0.866025 + 0.5j), (-0.866025 - 0.5j), (0.866025 - 0.5j)] The `n`-th roots of unity form a group, the cyclic group of order `n`. Any primitive root `r` is a generator for this group, meaning that `r^0, r^1, \ldots, r^{n-1}` gives the whole set of unit roots (in some permuted order):: >>> for r in unitroots(6): print(r) ... 1.0 (0.5 + 0.866025403784439j) (-0.5 + 0.866025403784439j) -1.0 (-0.5 - 0.866025403784439j) (0.5 - 0.866025403784439j) >>> r = unitroots(6, primitive=True)[1] >>> for k in range(6): print(chop(r**k)) ... 1.0 (0.5 - 0.866025403784439j) (-0.5 - 0.866025403784439j) -1.0 (-0.5 + 0.866025403784438j) (0.5 + 0.866025403784438j) The number of primitive roots equals the Euler totient function `\phi(n)`:: >>> [len(unitroots(n, primitive=True)) for n in range(1,20)] [1, 1, 2, 2, 4, 2, 6, 4, 6, 4, 10, 4, 12, 6, 8, 8, 16, 6, 18] """ log = r""" Computes the base-`b` logarithm of `x`, `\log_b(x)`. If `b` is unspecified, :func:`~mpmath.log` computes the natural (base `e`) logarithm and is equivalent to :func:`~mpmath.ln`. In general, the base `b` logarithm is defined in terms of the natural logarithm as `\log_b(x) = \ln(x)/\ln(b)`. By convention, we take `\log(0) = -\infty`. The natural logarithm is real if `x > 0` and complex if `x < 0` or if `x` is complex. The principal branch of the complex logarithm is used, meaning that `\Im(\ln(x)) = -\pi < \arg(x) \le \pi`. **Examples** Some basic values and limits:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> log(1) 0.0 >>> log(2) 0.693147180559945 >>> log(1000,10) 3.0 >>> log(4, 16) 0.5 >>> log(j) (0.0 + 1.5707963267949j) >>> log(-1) (0.0 + 3.14159265358979j) >>> log(0) -inf >>> log(inf) +inf The natural logarithm is the antiderivative of `1/x`:: >>> quad(lambda x: 1/x, [1, 5]) 1.6094379124341 >>> log(5) 1.6094379124341 >>> diff(log, 10) 0.1 The Taylor series expansion of the natural logarithm around `x = 1` has coefficients `(-1)^{n+1}/n`:: >>> nprint(taylor(log, 1, 7)) [0.0, 1.0, -0.5, 0.333333, -0.25, 0.2, -0.166667, 0.142857] :func:`~mpmath.log` supports arbitrary precision evaluation:: >>> mp.dps = 50 >>> log(pi) 1.1447298858494001741434273513530587116472948129153 >>> log(pi, pi**3) 0.33333333333333333333333333333333333333333333333333 >>> mp.dps = 25 >>> log(3+4j) (1.609437912434100374600759 + 0.9272952180016122324285125j) """ log10 = r""" Computes the base-10 logarithm of `x`, `\log_{10}(x)`. ``log10(x)`` is equivalent to ``log(x, 10)``. """ fmod = r""" Converts `x` and `y` to mpmath numbers and returns `x \mod y`. For mpmath numbers, this is equivalent to ``x % y``. >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> fmod(100, pi) 2.61062773871641 You can use :func:`~mpmath.fmod` to compute fractional parts of numbers:: >>> fmod(10.25, 1) 0.25 """ radians = r""" Converts the degree angle `x` to radians:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> radians(60) 1.0471975511966 """ degrees = r""" Converts the radian angle `x` to a degree angle:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> degrees(pi/3) 60.0 """ atan2 = r""" Computes the two-argument arctangent, `\mathrm{atan2}(y, x)`, giving the signed angle between the positive `x`-axis and the point `(x, y)` in the 2D plane. This function is defined for real `x` and `y` only. The two-argument arctangent essentially computes `\mathrm{atan}(y/x)`, but accounts for the signs of both `x` and `y` to give the angle for the correct quadrant. The following examples illustrate the difference:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> atan2(1,1), atan(1/1.) (0.785398163397448, 0.785398163397448) >>> atan2(1,-1), atan(1/-1.) (2.35619449019234, -0.785398163397448) >>> atan2(-1,1), atan(-1/1.) (-0.785398163397448, -0.785398163397448) >>> atan2(-1,-1), atan(-1/-1.) (-2.35619449019234, 0.785398163397448) The angle convention is the same as that used for the complex argument; see :func:`~mpmath.arg`. """ fibonacci = r""" ``fibonacci(n)`` computes the `n`-th Fibonacci number, `F(n)`. The Fibonacci numbers are defined by the recurrence `F(n) = F(n-1) + F(n-2)` with the initial values `F(0) = 0`, `F(1) = 1`. :func:`~mpmath.fibonacci` extends this definition to arbitrary real and complex arguments using the formula .. math :: F(z) = \frac{\phi^z - \cos(\pi z) \phi^{-z}}{\sqrt 5} where `\phi` is the golden ratio. :func:`~mpmath.fibonacci` also uses this continuous formula to compute `F(n)` for extremely large `n`, where calculating the exact integer would be wasteful. For convenience, :func:`~mpmath.fib` is available as an alias for :func:`~mpmath.fibonacci`. **Basic examples** Some small Fibonacci numbers are:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for i in range(10): ... print(fibonacci(i)) ... 0.0 1.0 1.0 2.0 3.0 5.0 8.0 13.0 21.0 34.0 >>> fibonacci(50) 12586269025.0 The recurrence for `F(n)` extends backwards to negative `n`:: >>> for i in range(10): ... print(fibonacci(-i)) ... 0.0 1.0 -1.0 2.0 -3.0 5.0 -8.0 13.0 -21.0 34.0 Large Fibonacci numbers will be computed approximately unless the precision is set high enough:: >>> fib(200) 2.8057117299251e+41 >>> mp.dps = 45 >>> fib(200) 280571172992510140037611932413038677189525.0 :func:`~mpmath.fibonacci` can compute approximate Fibonacci numbers of stupendous size:: >>> mp.dps = 15 >>> fibonacci(10**25) 3.49052338550226e+2089876402499787337692720 **Real and complex arguments** The extended Fibonacci function is an analytic function. The property `F(z) = F(z-1) + F(z-2)` holds for arbitrary `z`:: >>> mp.dps = 15 >>> fib(pi) 2.1170270579161 >>> fib(pi-1) + fib(pi-2) 2.1170270579161 >>> fib(3+4j) (-5248.51130728372 - 14195.962288353j) >>> fib(2+4j) + fib(1+4j) (-5248.51130728372 - 14195.962288353j) The Fibonacci function has infinitely many roots on the negative half-real axis. The first root is at 0, the second is close to -0.18, and then there are infinitely many roots that asymptotically approach `-n+1/2`:: >>> findroot(fib, -0.2) -0.183802359692956 >>> findroot(fib, -2) -1.57077646820395 >>> findroot(fib, -17) -16.4999999596115 >>> findroot(fib, -24) -23.5000000000479 **Mathematical relationships** For large `n`, `F(n+1)/F(n)` approaches the golden ratio:: >>> mp.dps = 50 >>> fibonacci(101)/fibonacci(100) 1.6180339887498948482045868343656381177203127439638 >>> +phi 1.6180339887498948482045868343656381177203091798058 The sum of reciprocal Fibonacci numbers converges to an irrational number for which no closed form expression is known:: >>> mp.dps = 15 >>> nsum(lambda n: 1/fib(n), [1, inf]) 3.35988566624318 Amazingly, however, the sum of odd-index reciprocal Fibonacci numbers can be expressed in terms of a Jacobi theta function:: >>> nsum(lambda n: 1/fib(2*n+1), [0, inf]) 1.82451515740692 >>> sqrt(5)*jtheta(2,0,(3-sqrt(5))/2)**2/4 1.82451515740692 Some related sums can be done in closed form:: >>> nsum(lambda k: 1/(1+fib(2*k+1)), [0, inf]) 1.11803398874989 >>> phi - 0.5 1.11803398874989 >>> f = lambda k:(-1)**(k+1) / sum(fib(n)**2 for n in range(1,int(k+1))) >>> nsum(f, [1, inf]) 0.618033988749895 >>> phi-1 0.618033988749895 **References** 1. http://mathworld.wolfram.com/FibonacciNumber.html """ altzeta = r""" Gives the Dirichlet eta function, `\eta(s)`, also known as the alternating zeta function. This function is defined in analogy with the Riemann zeta function as providing the sum of the alternating series .. math :: \eta(s) = \sum_{k=0}^{\infty} \frac{(-1)^k}{k^s} = 1-\frac{1}{2^s}+\frac{1}{3^s}-\frac{1}{4^s}+\ldots The eta function, unlike the Riemann zeta function, is an entire function, having a finite value for all complex `s`. The special case `\eta(1) = \log(2)` gives the value of the alternating harmonic series. The alternating zeta function may expressed using the Riemann zeta function as `\eta(s) = (1 - 2^{1-s}) \zeta(s)`. It can also be expressed in terms of the Hurwitz zeta function, for example using :func:`~mpmath.dirichlet` (see documentation for that function). **Examples** Some special values are:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> altzeta(1) 0.693147180559945 >>> altzeta(0) 0.5 >>> altzeta(-1) 0.25 >>> altzeta(-2) 0.0 An example of a sum that can be computed more accurately and efficiently via :func:`~mpmath.altzeta` than via numerical summation:: >>> sum(-(-1)**n / mpf(n)**2.5 for n in range(1, 100)) 0.867204951503984 >>> altzeta(2.5) 0.867199889012184 At positive even integers, the Dirichlet eta function evaluates to a rational multiple of a power of `\pi`:: >>> altzeta(2) 0.822467033424113 >>> pi**2/12 0.822467033424113 Like the Riemann zeta function, `\eta(s)`, approaches 1 as `s` approaches positive infinity, although it does so from below rather than from above:: >>> altzeta(30) 0.999999999068682 >>> altzeta(inf) 1.0 >>> mp.pretty = False >>> altzeta(1000, rounding='d') mpf('0.99999999999999989') >>> altzeta(1000, rounding='u') mpf('1.0') **References** 1. http://mathworld.wolfram.com/DirichletEtaFunction.html 2. http://en.wikipedia.org/wiki/Dirichlet_eta_function """ factorial = r""" Computes the factorial, `x!`. For integers `n \ge 0`, we have `n! = 1 \cdot 2 \cdots (n-1) \cdot n` and more generally the factorial is defined for real or complex `x` by `x! = \Gamma(x+1)`. **Examples** Basic values and limits:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for k in range(6): ... print("%s %s" % (k, fac(k))) ... 0 1.0 1 1.0 2 2.0 3 6.0 4 24.0 5 120.0 >>> fac(inf) +inf >>> fac(0.5), sqrt(pi)/2 (0.886226925452758, 0.886226925452758) For large positive `x`, `x!` can be approximated by Stirling's formula:: >>> x = 10**10 >>> fac(x) 2.32579620567308e+95657055186 >>> sqrt(2*pi*x)*(x/e)**x 2.32579597597705e+95657055186 :func:`~mpmath.fac` supports evaluation for astronomically large values:: >>> fac(10**30) 6.22311232304258e+29565705518096748172348871081098 Reciprocal factorials appear in the Taylor series of the exponential function (among many other contexts):: >>> nsum(lambda k: 1/fac(k), [0, inf]), exp(1) (2.71828182845905, 2.71828182845905) >>> nsum(lambda k: pi**k/fac(k), [0, inf]), exp(pi) (23.1406926327793, 23.1406926327793) """ gamma = r""" Computes the gamma function, `\Gamma(x)`. The gamma function is a shifted version of the ordinary factorial, satisfying `\Gamma(n) = (n-1)!` for integers `n > 0`. More generally, it is defined by .. math :: \Gamma(x) = \int_0^{\infty} t^{x-1} e^{-t}\, dt for any real or complex `x` with `\Re(x) > 0` and for `\Re(x) < 0` by analytic continuation. **Examples** Basic values and limits:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for k in range(1, 6): ... print("%s %s" % (k, gamma(k))) ... 1 1.0 2 1.0 3 2.0 4 6.0 5 24.0 >>> gamma(inf) +inf >>> gamma(0) Traceback (most recent call last): ... ValueError: gamma function pole The gamma function of a half-integer is a rational multiple of `\sqrt{\pi}`:: >>> gamma(0.5), sqrt(pi) (1.77245385090552, 1.77245385090552) >>> gamma(1.5), sqrt(pi)/2 (0.886226925452758, 0.886226925452758) We can check the integral definition:: >>> gamma(3.5) 3.32335097044784 >>> quad(lambda t: t**2.5*exp(-t), [0,inf]) 3.32335097044784 :func:`~mpmath.gamma` supports arbitrary-precision evaluation and complex arguments:: >>> mp.dps = 50 >>> gamma(sqrt(3)) 0.91510229697308632046045539308226554038315280564184 >>> mp.dps = 25 >>> gamma(2j) (0.009902440080927490985955066 - 0.07595200133501806872408048j) Arguments can also be large. Note that the gamma function grows very quickly:: >>> mp.dps = 15 >>> gamma(10**20) 1.9328495143101e+1956570551809674817225 """ psi = r""" Gives the polygamma function of order `m` of `z`, `\psi^{(m)}(z)`. Special cases are known as the *digamma function* (`\psi^{(0)}(z)`), the *trigamma function* (`\psi^{(1)}(z)`), etc. The polygamma functions are defined as the logarithmic derivatives of the gamma function: .. math :: \psi^{(m)}(z) = \left(\frac{d}{dz}\right)^{m+1} \log \Gamma(z) In particular, `\psi^{(0)}(z) = \Gamma'(z)/\Gamma(z)`. In the present implementation of :func:`~mpmath.psi`, the order `m` must be a nonnegative integer, while the argument `z` may be an arbitrary complex number (with exception for the polygamma function's poles at `z = 0, -1, -2, \ldots`). **Examples** For various rational arguments, the polygamma function reduces to a combination of standard mathematical constants:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> psi(0, 1), -euler (-0.5772156649015328606065121, -0.5772156649015328606065121) >>> psi(1, '1/4'), pi**2+8*catalan (17.19732915450711073927132, 17.19732915450711073927132) >>> psi(2, '1/2'), -14*apery (-16.82879664423431999559633, -16.82879664423431999559633) The polygamma functions are derivatives of each other:: >>> diff(lambda x: psi(3, x), pi), psi(4, pi) (-0.1105749312578862734526952, -0.1105749312578862734526952) >>> quad(lambda x: psi(4, x), [2, 3]), psi(3,3)-psi(3,2) (-0.375, -0.375) The digamma function diverges logarithmically as `z \to \infty`, while higher orders tend to zero:: >>> psi(0,inf), psi(1,inf), psi(2,inf) (+inf, 0.0, 0.0) Evaluation for a complex argument:: >>> psi(2, -1-2j) (0.03902435405364952654838445 + 0.1574325240413029954685366j) Evaluation is supported for large orders `m` and/or large arguments `z`:: >>> psi(3, 10**100) 2.0e-300 >>> psi(250, 10**30+10**20*j) (-1.293142504363642687204865e-7010 + 3.232856260909107391513108e-7018j) **Application to infinite series** Any infinite series where the summand is a rational function of the index `k` can be evaluated in closed form in terms of polygamma functions of the roots and poles of the summand:: >>> a = sqrt(2) >>> b = sqrt(3) >>> nsum(lambda k: 1/((k+a)**2*(k+b)), [0, inf]) 0.4049668927517857061917531 >>> (psi(0,a)-psi(0,b)-a*psi(1,a)+b*psi(1,a))/(a-b)**2 0.4049668927517857061917531 This follows from the series representation (`m > 0`) .. math :: \psi^{(m)}(z) = (-1)^{m+1} m! \sum_{k=0}^{\infty} \frac{1}{(z+k)^{m+1}}. Since the roots of a polynomial may be complex, it is sometimes necessary to use the complex polygamma function to evaluate an entirely real-valued sum:: >>> nsum(lambda k: 1/(k**2-2*k+3), [0, inf]) 1.694361433907061256154665 >>> nprint(polyroots([1,-2,3])) [(1.0 - 1.41421j), (1.0 + 1.41421j)] >>> r1 = 1-sqrt(2)*j >>> r2 = r1.conjugate() >>> (psi(0,-r2)-psi(0,-r1))/(r1-r2) (1.694361433907061256154665 + 0.0j) """ digamma = r""" Shortcut for ``psi(0,z)``. """ harmonic = r""" If `n` is an integer, ``harmonic(n)`` gives a floating-point approximation of the `n`-th harmonic number `H(n)`, defined as .. math :: H(n) = 1 + \frac{1}{2} + \frac{1}{3} + \ldots + \frac{1}{n} The first few harmonic numbers are:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(8): ... print("%s %s" % (n, harmonic(n))) ... 0 0.0 1 1.0 2 1.5 3 1.83333333333333 4 2.08333333333333 5 2.28333333333333 6 2.45 7 2.59285714285714 The infinite harmonic series `1 + 1/2 + 1/3 + \ldots` diverges:: >>> harmonic(inf) +inf :func:`~mpmath.harmonic` is evaluated using the digamma function rather than by summing the harmonic series term by term. It can therefore be computed quickly for arbitrarily large `n`, and even for nonintegral arguments:: >>> harmonic(10**100) 230.835724964306 >>> harmonic(0.5) 0.613705638880109 >>> harmonic(3+4j) (2.24757548223494 + 0.850502209186044j) :func:`~mpmath.harmonic` supports arbitrary precision evaluation:: >>> mp.dps = 50 >>> harmonic(11) 3.0198773448773448773448773448773448773448773448773 >>> harmonic(pi) 1.8727388590273302654363491032336134987519132374152 The harmonic series diverges, but at a glacial pace. It is possible to calculate the exact number of terms required before the sum exceeds a given amount, say 100:: >>> mp.dps = 50 >>> v = 10**findroot(lambda x: harmonic(10**x) - 100, 10) >>> v 15092688622113788323693563264538101449859496.864101 >>> v = int(ceil(v)) >>> print(v) 15092688622113788323693563264538101449859497 >>> harmonic(v-1) 99.999999999999999999999999999999999999999999942747 >>> harmonic(v) 100.000000000000000000000000000000000000000000009 """ bernoulli = r""" Computes the nth Bernoulli number, `B_n`, for any integer `n \ge 0`. The Bernoulli numbers are rational numbers, but this function returns a floating-point approximation. To obtain an exact fraction, use :func:`~mpmath.bernfrac` instead. **Examples** Numerical values of the first few Bernoulli numbers:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(15): ... print("%s %s" % (n, bernoulli(n))) ... 0 1.0 1 -0.5 2 0.166666666666667 3 0.0 4 -0.0333333333333333 5 0.0 6 0.0238095238095238 7 0.0 8 -0.0333333333333333 9 0.0 10 0.0757575757575758 11 0.0 12 -0.253113553113553 13 0.0 14 1.16666666666667 Bernoulli numbers can be approximated with arbitrary precision:: >>> mp.dps = 50 >>> bernoulli(100) -2.8382249570693706959264156336481764738284680928013e+78 Arbitrarily large `n` are supported:: >>> mp.dps = 15 >>> bernoulli(10**20 + 2) 3.09136296657021e+1876752564973863312327 The Bernoulli numbers are related to the Riemann zeta function at integer arguments:: >>> -bernoulli(8) * (2*pi)**8 / (2*fac(8)) 1.00407735619794 >>> zeta(8) 1.00407735619794 **Algorithm** For small `n` (`n < 3000`) :func:`~mpmath.bernoulli` uses a recurrence formula due to Ramanujan. All results in this range are cached, so sequential computation of small Bernoulli numbers is guaranteed to be fast. For larger `n`, `B_n` is evaluated in terms of the Riemann zeta function. """ stieltjes = r""" For a nonnegative integer `n`, ``stieltjes(n)`` computes the `n`-th Stieltjes constant `\gamma_n`, defined as the `n`-th coefficient in the Laurent series expansion of the Riemann zeta function around the pole at `s = 1`. That is, we have: .. math :: \zeta(s) = \frac{1}{s-1} \sum_{n=0}^{\infty} \frac{(-1)^n}{n!} \gamma_n (s-1)^n More generally, ``stieltjes(n, a)`` gives the corresponding coefficient `\gamma_n(a)` for the Hurwitz zeta function `\zeta(s,a)` (with `\gamma_n = \gamma_n(1)`). **Examples** The zeroth Stieltjes constant is just Euler's constant `\gamma`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> stieltjes(0) 0.577215664901533 Some more values are:: >>> stieltjes(1) -0.0728158454836767 >>> stieltjes(10) 0.000205332814909065 >>> stieltjes(30) 0.00355772885557316 >>> stieltjes(1000) -1.57095384420474e+486 >>> stieltjes(2000) 2.680424678918e+1109 >>> stieltjes(1, 2.5) -0.23747539175716 An alternative way to compute `\gamma_1`:: >>> diff(extradps(15)(lambda x: 1/(x-1) - zeta(x)), 1) -0.0728158454836767 :func:`~mpmath.stieltjes` supports arbitrary precision evaluation:: >>> mp.dps = 50 >>> stieltjes(2) -0.0096903631928723184845303860352125293590658061013408 **Algorithm** :func:`~mpmath.stieltjes` numerically evaluates the integral in the following representation due to Ainsworth, Howell and Coffey [1], [2]: .. math :: \gamma_n(a) = \frac{\log^n a}{2a} - \frac{\log^{n+1}(a)}{n+1} + \frac{2}{a} \Re \int_0^{\infty} \frac{(x/a-i)\log^n(a-ix)}{(1+x^2/a^2)(e^{2\pi x}-1)} dx. For some reference values with `a = 1`, see e.g. [4]. **References** 1. O. R. Ainsworth & L. W. Howell, "An integral representation of the generalized Euler-Mascheroni constants", NASA Technical Paper 2456 (1985), http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19850014994_1985014994.pdf 2. M. W. Coffey, "The Stieltjes constants, their relation to the `\eta_j` coefficients, and representation of the Hurwitz zeta function", arXiv:0706.0343v1 http://arxiv.org/abs/0706.0343 3. http://mathworld.wolfram.com/StieltjesConstants.html 4. http://pi.lacim.uqam.ca/piDATA/stieltjesgamma.txt """ gammaprod = r""" Given iterables `a` and `b`, ``gammaprod(a, b)`` computes the product / quotient of gamma functions: .. math :: \frac{\Gamma(a_0) \Gamma(a_1) \cdots \Gamma(a_p)} {\Gamma(b_0) \Gamma(b_1) \cdots \Gamma(b_q)} Unlike direct calls to :func:`~mpmath.gamma`, :func:`~mpmath.gammaprod` considers the entire product as a limit and evaluates this limit properly if any of the numerator or denominator arguments are nonpositive integers such that poles of the gamma function are encountered. That is, :func:`~mpmath.gammaprod` evaluates .. math :: \lim_{\epsilon \to 0} \frac{\Gamma(a_0+\epsilon) \Gamma(a_1+\epsilon) \cdots \Gamma(a_p+\epsilon)} {\Gamma(b_0+\epsilon) \Gamma(b_1+\epsilon) \cdots \Gamma(b_q+\epsilon)} In particular: * If there are equally many poles in the numerator and the denominator, the limit is a rational number times the remaining, regular part of the product. * If there are more poles in the numerator, :func:`~mpmath.gammaprod` returns ``+inf``. * If there are more poles in the denominator, :func:`~mpmath.gammaprod` returns 0. **Examples** The reciprocal gamma function `1/\Gamma(x)` evaluated at `x = 0`:: >>> from mpmath import * >>> mp.dps = 15 >>> gammaprod([], [0]) 0.0 A limit:: >>> gammaprod([-4], [-3]) -0.25 >>> limit(lambda x: gamma(x-1)/gamma(x), -3, direction=1) -0.25 >>> limit(lambda x: gamma(x-1)/gamma(x), -3, direction=-1) -0.25 """ beta = r""" Computes the beta function, `B(x,y) = \Gamma(x) \Gamma(y) / \Gamma(x+y)`. The beta function is also commonly defined by the integral representation .. math :: B(x,y) = \int_0^1 t^{x-1} (1-t)^{y-1} \, dt **Examples** For integer and half-integer arguments where all three gamma functions are finite, the beta function becomes either rational number or a rational multiple of `\pi`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> beta(5, 2) 0.0333333333333333 >>> beta(1.5, 2) 0.266666666666667 >>> 16*beta(2.5, 1.5) 3.14159265358979 Where appropriate, :func:`~mpmath.beta` evaluates limits. A pole of the beta function is taken to result in ``+inf``:: >>> beta(-0.5, 0.5) 0.0 >>> beta(-3, 3) -0.333333333333333 >>> beta(-2, 3) +inf >>> beta(inf, 1) 0.0 >>> beta(inf, 0) nan :func:`~mpmath.beta` supports complex numbers and arbitrary precision evaluation:: >>> beta(1, 2+j) (0.4 - 0.2j) >>> mp.dps = 25 >>> beta(j,0.5) (1.079424249270925780135675 - 1.410032405664160838288752j) >>> mp.dps = 50 >>> beta(pi, e) 0.037890298781212201348153837138927165984170287886464 Various integrals can be computed by means of the beta function:: >>> mp.dps = 15 >>> quad(lambda t: t**2.5*(1-t)**2, [0, 1]) 0.0230880230880231 >>> beta(3.5, 3) 0.0230880230880231 >>> quad(lambda t: sin(t)**4 * sqrt(cos(t)), [0, pi/2]) 0.319504062596158 >>> beta(2.5, 0.75)/2 0.319504062596158 """ betainc = r""" ``betainc(a, b, x1=0, x2=1, regularized=False)`` gives the generalized incomplete beta function, .. math :: I_{x_1}^{x_2}(a,b) = \int_{x_1}^{x_2} t^{a-1} (1-t)^{b-1} dt. When `x_1 = 0, x_2 = 1`, this reduces to the ordinary (complete) beta function `B(a,b)`; see :func:`~mpmath.beta`. With the keyword argument ``regularized=True``, :func:`~mpmath.betainc` computes the regularized incomplete beta function `I_{x_1}^{x_2}(a,b) / B(a,b)`. This is the cumulative distribution of the beta distribution with parameters `a`, `b`. .. note : Implementations of the incomplete beta function in some other software uses a different argument order. For example, Mathematica uses the reversed argument order ``Beta[x1,x2,a,b]``. For the equivalent of SciPy's three-argument incomplete beta integral (implicitly with `x1 = 0`), use ``betainc(a,b,0,x2,regularized=True)``. **Examples** Verifying that :func:`~mpmath.betainc` computes the integral in the definition:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> x,y,a,b = 3, 4, 0, 6 >>> betainc(x, y, a, b) -4010.4 >>> quad(lambda t: t**(x-1) * (1-t)**(y-1), [a, b]) -4010.4 The arguments may be arbitrary complex numbers:: >>> betainc(0.75, 1-4j, 0, 2+3j) (0.2241657956955709603655887 + 0.3619619242700451992411724j) With regularization:: >>> betainc(1, 2, 0, 0.25, regularized=True) 0.4375 >>> betainc(pi, e, 0, 1, regularized=True) # Complete 1.0 The beta integral satisfies some simple argument transformation symmetries:: >>> mp.dps = 15 >>> betainc(2,3,4,5), -betainc(2,3,5,4), betainc(3,2,1-5,1-4) (56.0833333333333, 56.0833333333333, 56.0833333333333) The beta integral can often be evaluated analytically. For integer and rational arguments, the incomplete beta function typically reduces to a simple algebraic-logarithmic expression:: >>> mp.dps = 25 >>> identify(chop(betainc(0, 0, 3, 4))) '-(log((9/8)))' >>> identify(betainc(2, 3, 4, 5)) '(673/12)' >>> identify(betainc(1.5, 1, 1, 2)) '((-12+sqrt(1152))/18)' """ binomial = r""" Computes the binomial coefficient .. math :: {n \choose k} = \frac{n!}{k!(n-k)!}. The binomial coefficient gives the number of ways that `k` items can be chosen from a set of `n` items. More generally, the binomial coefficient is a well-defined function of arbitrary real or complex `n` and `k`, via the gamma function. **Examples** Generate Pascal's triangle:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(5): ... nprint([binomial(n,k) for k in range(n+1)]) ... [1.0] [1.0, 1.0] [1.0, 2.0, 1.0] [1.0, 3.0, 3.0, 1.0] [1.0, 4.0, 6.0, 4.0, 1.0] There is 1 way to select 0 items from the empty set, and 0 ways to select 1 item from the empty set:: >>> binomial(0, 0) 1.0 >>> binomial(0, 1) 0.0 :func:`~mpmath.binomial` supports large arguments:: >>> binomial(10**20, 10**20-5) 8.33333333333333e+97 >>> binomial(10**20, 10**10) 2.60784095465201e+104342944813 Nonintegral binomial coefficients find use in series expansions:: >>> nprint(taylor(lambda x: (1+x)**0.25, 0, 4)) [1.0, 0.25, -0.09375, 0.0546875, -0.0375977] >>> nprint([binomial(0.25, k) for k in range(5)]) [1.0, 0.25, -0.09375, 0.0546875, -0.0375977] An integral representation:: >>> n, k = 5, 3 >>> f = lambda t: exp(-j*k*t)*(1+exp(j*t))**n >>> chop(quad(f, [-pi,pi])/(2*pi)) 10.0 >>> binomial(n,k) 10.0 """ rf = r""" Computes the rising factorial or Pochhammer symbol, .. math :: x^{(n)} = x (x+1) \cdots (x+n-1) = \frac{\Gamma(x+n)}{\Gamma(x)} where the rightmost expression is valid for nonintegral `n`. **Examples** For integral `n`, the rising factorial is a polynomial:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(5): ... nprint(taylor(lambda x: rf(x,n), 0, n)) ... [1.0] [0.0, 1.0] [0.0, 1.0, 1.0] [0.0, 2.0, 3.0, 1.0] [0.0, 6.0, 11.0, 6.0, 1.0] Evaluation is supported for arbitrary arguments:: >>> rf(2+3j, 5.5) (-7202.03920483347 - 3777.58810701527j) """ ff = r""" Computes the falling factorial, .. math :: (x)_n = x (x-1) \cdots (x-n+1) = \frac{\Gamma(x+1)}{\Gamma(x-n+1)} where the rightmost expression is valid for nonintegral `n`. **Examples** For integral `n`, the falling factorial is a polynomial:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(5): ... nprint(taylor(lambda x: ff(x,n), 0, n)) ... [1.0] [0.0, 1.0] [0.0, -1.0, 1.0] [0.0, 2.0, -3.0, 1.0] [0.0, -6.0, 11.0, -6.0, 1.0] Evaluation is supported for arbitrary arguments:: >>> ff(2+3j, 5.5) (-720.41085888203 + 316.101124983878j) """ fac2 = r""" Computes the double factorial `x!!`, defined for integers `x > 0` by .. math :: x!! = \begin{cases} 1 \cdot 3 \cdots (x-2) \cdot x & x \;\mathrm{odd} \\ 2 \cdot 4 \cdots (x-2) \cdot x & x \;\mathrm{even} \end{cases} and more generally by [1] .. math :: x!! = 2^{x/2} \left(\frac{\pi}{2}\right)^{(\cos(\pi x)-1)/4} \Gamma\left(\frac{x}{2}+1\right). **Examples** The integer sequence of double factorials begins:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> nprint([fac2(n) for n in range(10)]) [1.0, 1.0, 2.0, 3.0, 8.0, 15.0, 48.0, 105.0, 384.0, 945.0] For large `x`, double factorials follow a Stirling-like asymptotic approximation:: >>> x = mpf(10000) >>> fac2(x) 5.97272691416282e+17830 >>> sqrt(pi)*x**((x+1)/2)*exp(-x/2) 5.97262736954392e+17830 The recurrence formula `x!! = x (x-2)!!` can be reversed to define the double factorial of negative odd integers (but not negative even integers):: >>> fac2(-1), fac2(-3), fac2(-5), fac2(-7) (1.0, -1.0, 0.333333333333333, -0.0666666666666667) >>> fac2(-2) Traceback (most recent call last): ... ValueError: gamma function pole With the exception of the poles at negative even integers, :func:`~mpmath.fac2` supports evaluation for arbitrary complex arguments. The recurrence formula is valid generally:: >>> fac2(pi+2j) (-1.3697207890154e-12 + 3.93665300979176e-12j) >>> (pi+2j)*fac2(pi-2+2j) (-1.3697207890154e-12 + 3.93665300979176e-12j) Double factorials should not be confused with nested factorials, which are immensely larger:: >>> fac(fac(20)) 5.13805976125208e+43675043585825292774 >>> fac2(20) 3715891200.0 Double factorials appear, among other things, in series expansions of Gaussian functions and the error function. Infinite series include:: >>> nsum(lambda k: 1/fac2(k), [0, inf]) 3.05940740534258 >>> sqrt(e)*(1+sqrt(pi/2)*erf(sqrt(2)/2)) 3.05940740534258 >>> nsum(lambda k: 2**k/fac2(2*k-1), [1, inf]) 4.06015693855741 >>> e * erf(1) * sqrt(pi) 4.06015693855741 A beautiful Ramanujan sum:: >>> nsum(lambda k: (-1)**k*(fac2(2*k-1)/fac2(2*k))**3, [0,inf]) 0.90917279454693 >>> (gamma('9/8')/gamma('5/4')/gamma('7/8'))**2 0.90917279454693 **References** 1. http://functions.wolfram.com/GammaBetaErf/Factorial2/27/01/0002/ 2. http://mathworld.wolfram.com/DoubleFactorial.html """ hyper = r""" Evaluates the generalized hypergeometric function .. math :: \,_pF_q(a_1,\ldots,a_p; b_1,\ldots,b_q; z) = \sum_{n=0}^\infty \frac{(a_1)_n (a_2)_n \ldots (a_p)_n} {(b_1)_n(b_2)_n\ldots(b_q)_n} \frac{z^n}{n!} where `(x)_n` denotes the rising factorial (see :func:`~mpmath.rf`). The parameters lists ``a_s`` and ``b_s`` may contain integers, real numbers, complex numbers, as well as exact fractions given in the form of tuples `(p, q)`. :func:`~mpmath.hyper` is optimized to handle integers and fractions more efficiently than arbitrary floating-point parameters (since rational parameters are by far the most common). **Examples** Verifying that :func:`~mpmath.hyper` gives the sum in the definition, by comparison with :func:`~mpmath.nsum`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> a,b,c,d = 2,3,4,5 >>> x = 0.25 >>> hyper([a,b],[c,d],x) 1.078903941164934876086237 >>> fn = lambda n: rf(a,n)*rf(b,n)/rf(c,n)/rf(d,n)*x**n/fac(n) >>> nsum(fn, [0, inf]) 1.078903941164934876086237 The parameters can be any combination of integers, fractions, floats and complex numbers:: >>> a, b, c, d, e = 1, (-1,2), pi, 3+4j, (2,3) >>> x = 0.2j >>> hyper([a,b],[c,d,e],x) (0.9923571616434024810831887 - 0.005753848733883879742993122j) >>> b, e = -0.5, mpf(2)/3 >>> fn = lambda n: rf(a,n)*rf(b,n)/rf(c,n)/rf(d,n)/rf(e,n)*x**n/fac(n) >>> nsum(fn, [0, inf]) (0.9923571616434024810831887 - 0.005753848733883879742993122j) The `\,_0F_0` and `\,_1F_0` series are just elementary functions:: >>> a, z = sqrt(2), +pi >>> hyper([],[],z) 23.14069263277926900572909 >>> exp(z) 23.14069263277926900572909 >>> hyper([a],[],z) (-0.09069132879922920160334114 + 0.3283224323946162083579656j) >>> (1-z)**(-a) (-0.09069132879922920160334114 + 0.3283224323946162083579656j) If any `a_k` coefficient is a nonpositive integer, the series terminates into a finite polynomial:: >>> hyper([1,1,1,-3],[2,5],1) 0.7904761904761904761904762 >>> identify(_) '(83/105)' If any `b_k` is a nonpositive integer, the function is undefined (unless the series terminates before the division by zero occurs):: >>> hyper([1,1,1,-3],[-2,5],1) Traceback (most recent call last): ... ZeroDivisionError: pole in hypergeometric series >>> hyper([1,1,1,-1],[-2,5],1) 1.1 Except for polynomial cases, the radius of convergence `R` of the hypergeometric series is either `R = \infty` (if `p \le q`), `R = 1` (if `p = q+1`), or `R = 0` (if `p > q+1`). The analytic continuations of the functions with `p = q+1`, i.e. `\,_2F_1`, `\,_3F_2`, `\,_4F_3`, etc, are all implemented and therefore these functions can be evaluated for `|z| \ge 1`. The shortcuts :func:`~mpmath.hyp2f1`, :func:`~mpmath.hyp3f2` are available to handle the most common cases (see their documentation), but functions of higher degree are also supported via :func:`~mpmath.hyper`:: >>> hyper([1,2,3,4], [5,6,7], 1) # 4F3 at finite-valued branch point 1.141783505526870731311423 >>> hyper([4,5,6,7], [1,2,3], 1) # 4F3 at pole +inf >>> hyper([1,2,3,4,5], [6,7,8,9], 10) # 5F4 (1.543998916527972259717257 - 0.5876309929580408028816365j) >>> hyper([1,2,3,4,5,6], [7,8,9,10,11], 1j) # 6F5 (0.9996565821853579063502466 + 0.0129721075905630604445669j) Near `z = 1` with noninteger parameters:: >>> hyper(['1/3',1,'3/2',2], ['1/5','11/6','41/8'], 1) 2.219433352235586121250027 >>> hyper(['1/3',1,'3/2',2], ['1/5','11/6','5/4'], 1) +inf >>> eps1 = extradps(6)(lambda: 1 - mpf('1e-6'))() >>> hyper(['1/3',1,'3/2',2], ['1/5','11/6','5/4'], eps1) 2923978034.412973409330956 Please note that, as currently implemented, evaluation of `\,_pF_{p-1}` with `p \ge 3` may be slow or inaccurate when `|z-1|` is small, for some parameter values. Evaluation may be aborted if convergence appears to be too slow. The optional ``maxterms`` (limiting the number of series terms) and ``maxprec`` (limiting the internal precision) keyword arguments can be used to control evaluation:: >>> hyper([1,2,3], [4,5,6], 10000) Traceback (most recent call last): ... NoConvergence: Hypergeometric series converges too slowly. Try increasing maxterms. >>> hyper([1,2,3], [4,5,6], 10000, maxterms=10**6) 7.622806053177969474396918e+4310 Additional options include ``force_series`` (which forces direct use of a hypergeometric series even if another evaluation method might work better) and ``asymp_tol`` which controls the target tolerance for using asymptotic series. When `p > q+1`, ``hyper`` computes the (iterated) Borel sum of the divergent series. For `\,_2F_0` the Borel sum has an analytic solution and can be computed efficiently (see :func:`~mpmath.hyp2f0`). For higher degrees, the functions is evaluated first by attempting to sum it directly as an asymptotic series (this only works for tiny `|z|`), and then by evaluating the Borel regularized sum using numerical integration. Except for special parameter combinations, this can be extremely slow. >>> hyper([1,1], [], 0.5) # regularization of 2F0 (1.340965419580146562086448 + 0.8503366631752726568782447j) >>> hyper([1,1,1,1], [1], 0.5) # regularization of 4F1 (1.108287213689475145830699 + 0.5327107430640678181200491j) With the following magnitude of argument, the asymptotic series for `\,_3F_1` gives only a few digits. Using Borel summation, ``hyper`` can produce a value with full accuracy:: >>> mp.dps = 15 >>> hyper([2,0.5,4], [5.25], '0.08', force_series=True) Traceback (most recent call last): ... NoConvergence: Hypergeometric series converges too slowly. Try increasing maxterms. >>> hyper([2,0.5,4], [5.25], '0.08', asymp_tol=1e-4) 1.0725535790737 >>> hyper([2,0.5,4], [5.25], '0.08') (1.07269542893559 + 5.54668863216891e-5j) >>> hyper([2,0.5,4], [5.25], '-0.08', asymp_tol=1e-4) 0.946344925484879 >>> hyper([2,0.5,4], [5.25], '-0.08') 0.946312503737771 >>> mp.dps = 25 >>> hyper([2,0.5,4], [5.25], '-0.08') 0.9463125037377662296700858 Note that with the positive `z` value, there is a complex part in the correct result, which falls below the tolerance of the asymptotic series. By default, a parameter that appears in both ``a_s`` and ``b_s`` will be removed unless it is a nonpositive integer. This generally speeds up evaluation by producing a hypergeometric function of lower order. This optimization can be disabled by passing ``eliminate=False``. >>> hyper([1,2,3], [4,5,3], 10000) 1.268943190440206905892212e+4321 >>> hyper([1,2,3], [4,5,3], 10000, eliminate=False) Traceback (most recent call last): ... NoConvergence: Hypergeometric series converges too slowly. Try increasing maxterms. >>> hyper([1,2,3], [4,5,3], 10000, eliminate=False, maxterms=10**6) 1.268943190440206905892212e+4321 If a nonpositive integer `-n` appears in both ``a_s`` and ``b_s``, this parameter cannot be unambiguously removed since it creates a term 0 / 0. In this case the hypergeometric series is understood to terminate before the division by zero occurs. This convention is consistent with Mathematica. An alternative convention of eliminating the parameters can be toggled with ``eliminate_all=True``: >>> hyper([2,-1], [-1], 3) 7.0 >>> hyper([2,-1], [-1], 3, eliminate_all=True) 0.25 >>> hyper([2], [], 3) 0.25 """ hypercomb = r""" Computes a weighted combination of hypergeometric functions .. math :: \sum_{r=1}^N \left[ \prod_{k=1}^{l_r} {w_{r,k}}^{c_{r,k}} \frac{\prod_{k=1}^{m_r} \Gamma(\alpha_{r,k})}{\prod_{k=1}^{n_r} \Gamma(\beta_{r,k})} \,_{p_r}F_{q_r}(a_{r,1},\ldots,a_{r,p}; b_{r,1}, \ldots, b_{r,q}; z_r)\right]. Typically the parameters are linear combinations of a small set of base parameters; :func:`~mpmath.hypercomb` permits computing a correct value in the case that some of the `\alpha`, `\beta`, `b` turn out to be nonpositive integers, or if division by zero occurs for some `w^c`, assuming that there are opposing singularities that cancel out. The limit is computed by evaluating the function with the base parameters perturbed, at a higher working precision. The first argument should be a function that takes the perturbable base parameters ``params`` as input and returns `N` tuples ``(w, c, alpha, beta, a, b, z)``, where the coefficients ``w``, ``c``, gamma factors ``alpha``, ``beta``, and hypergeometric coefficients ``a``, ``b`` each should be lists of numbers, and ``z`` should be a single number. **Examples** The following evaluates .. math :: (a-1) \frac{\Gamma(a-3)}{\Gamma(a-4)} \,_1F_1(a,a-1,z) = e^z(a-4)(a+z-1) with `a=1, z=3`. There is a zero factor, two gamma function poles, and the 1F1 function is singular; all singularities cancel out to give a finite value:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> hypercomb(lambda a: [([a-1],[1],[a-3],[a-4],[a],[a-1],3)], [1]) -180.769832308689 >>> -9*exp(3) -180.769832308689 """ hyp0f1 = r""" Gives the hypergeometric function `\,_0F_1`, sometimes known as the confluent limit function, defined as .. math :: \,_0F_1(a,z) = \sum_{k=0}^{\infty} \frac{1}{(a)_k} \frac{z^k}{k!}. This function satisfies the differential equation `z f''(z) + a f'(z) = f(z)`, and is related to the Bessel function of the first kind (see :func:`~mpmath.besselj`). ``hyp0f1(a,z)`` is equivalent to ``hyper([],[a],z)``; see documentation for :func:`~mpmath.hyper` for more information. **Examples** Evaluation for arbitrary arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyp0f1(2, 0.25) 1.130318207984970054415392 >>> hyp0f1((1,2), 1234567) 6.27287187546220705604627e+964 >>> hyp0f1(3+4j, 1000000j) (3.905169561300910030267132e+606 + 3.807708544441684513934213e+606j) Evaluation is supported for arbitrarily large values of `z`, using asymptotic expansions:: >>> hyp0f1(1, 10**50) 2.131705322874965310390701e+8685889638065036553022565 >>> hyp0f1(1, -10**50) 1.115945364792025420300208e-13 Verifying the differential equation:: >>> a = 2.5 >>> f = lambda z: hyp0f1(a,z) >>> for z in [0, 10, 3+4j]: ... chop(z*diff(f,z,2) + a*diff(f,z) - f(z)) ... 0.0 0.0 0.0 """ hyp1f1 = r""" Gives the confluent hypergeometric function of the first kind, .. math :: \,_1F_1(a,b,z) = \sum_{k=0}^{\infty} \frac{(a)_k}{(b)_k} \frac{z^k}{k!}, also known as Kummer's function and sometimes denoted by `M(a,b,z)`. This function gives one solution to the confluent (Kummer's) differential equation .. math :: z f''(z) + (b-z) f'(z) - af(z) = 0. A second solution is given by the `U` function; see :func:`~mpmath.hyperu`. Solutions are also given in an alternate form by the Whittaker functions (:func:`~mpmath.whitm`, :func:`~mpmath.whitw`). ``hyp1f1(a,b,z)`` is equivalent to ``hyper([a],[b],z)``; see documentation for :func:`~mpmath.hyper` for more information. **Examples** Evaluation for real and complex values of the argument `z`, with fixed parameters `a = 2, b = -1/3`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyp1f1(2, (-1,3), 3.25) -2815.956856924817275640248 >>> hyp1f1(2, (-1,3), -3.25) -1.145036502407444445553107 >>> hyp1f1(2, (-1,3), 1000) -8.021799872770764149793693e+441 >>> hyp1f1(2, (-1,3), -1000) 0.000003131987633006813594535331 >>> hyp1f1(2, (-1,3), 100+100j) (-3.189190365227034385898282e+48 - 1.106169926814270418999315e+49j) Parameters may be complex:: >>> hyp1f1(2+3j, -1+j, 10j) (261.8977905181045142673351 + 160.8930312845682213562172j) Arbitrarily large values of `z` are supported:: >>> hyp1f1(3, 4, 10**20) 3.890569218254486878220752e+43429448190325182745 >>> hyp1f1(3, 4, -10**20) 6.0e-60 >>> hyp1f1(3, 4, 10**20*j) (-1.935753855797342532571597e-20 - 2.291911213325184901239155e-20j) Verifying the differential equation:: >>> a, b = 1.5, 2 >>> f = lambda z: hyp1f1(a,b,z) >>> for z in [0, -10, 3, 3+4j]: ... chop(z*diff(f,z,2) + (b-z)*diff(f,z) - a*f(z)) ... 0.0 0.0 0.0 0.0 An integral representation:: >>> a, b = 1.5, 3 >>> z = 1.5 >>> hyp1f1(a,b,z) 2.269381460919952778587441 >>> g = lambda t: exp(z*t)*t**(a-1)*(1-t)**(b-a-1) >>> gammaprod([b],[a,b-a])*quad(g, [0,1]) 2.269381460919952778587441 """ hyp1f2 = r""" Gives the hypergeometric function `\,_1F_2(a_1,a_2;b_1,b_2; z)`. The call ``hyp1f2(a1,b1,b2,z)`` is equivalent to ``hyper([a1],[b1,b2],z)``. Evaluation works for complex and arbitrarily large arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> a, b, c = 1.5, (-1,3), 2.25 >>> hyp1f2(a, b, c, 10**20) -1.159388148811981535941434e+8685889639 >>> hyp1f2(a, b, c, -10**20) -12.60262607892655945795907 >>> hyp1f2(a, b, c, 10**20*j) (4.237220401382240876065501e+6141851464 - 2.950930337531768015892987e+6141851464j) >>> hyp1f2(2+3j, -2j, 0.5j, 10-20j) (135881.9905586966432662004 - 86681.95885418079535738828j) """ hyp2f2 = r""" Gives the hypergeometric function `\,_2F_2(a_1,a_2;b_1,b_2; z)`. The call ``hyp2f2(a1,a2,b1,b2,z)`` is equivalent to ``hyper([a1,a2],[b1,b2],z)``. Evaluation works for complex and arbitrarily large arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> a, b, c, d = 1.5, (-1,3), 2.25, 4 >>> hyp2f2(a, b, c, d, 10**20) -5.275758229007902299823821e+43429448190325182663 >>> hyp2f2(a, b, c, d, -10**20) 2561445.079983207701073448 >>> hyp2f2(a, b, c, d, 10**20*j) (2218276.509664121194836667 - 1280722.539991603850462856j) >>> hyp2f2(2+3j, -2j, 0.5j, 4j, 10-20j) (80500.68321405666957342788 - 20346.82752982813540993502j) """ hyp2f3 = r""" Gives the hypergeometric function `\,_2F_3(a_1,a_2;b_1,b_2,b_3; z)`. The call ``hyp2f3(a1,a2,b1,b2,b3,z)`` is equivalent to ``hyper([a1,a2],[b1,b2,b3],z)``. Evaluation works for arbitrarily large arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> a1,a2,b1,b2,b3 = 1.5, (-1,3), 2.25, 4, (1,5) >>> hyp2f3(a1,a2,b1,b2,b3,10**20) -4.169178177065714963568963e+8685889590 >>> hyp2f3(a1,a2,b1,b2,b3,-10**20) 7064472.587757755088178629 >>> hyp2f3(a1,a2,b1,b2,b3,10**20*j) (-5.163368465314934589818543e+6141851415 + 1.783578125755972803440364e+6141851416j) >>> hyp2f3(2+3j, -2j, 0.5j, 4j, -1-j, 10-20j) (-2280.938956687033150740228 + 13620.97336609573659199632j) >>> hyp2f3(2+3j, -2j, 0.5j, 4j, -1-j, 10000000-20000000j) (4.849835186175096516193e+3504 - 3.365981529122220091353633e+3504j) """ hyp2f1 = r""" Gives the Gauss hypergeometric function `\,_2F_1` (often simply referred to as *the* hypergeometric function), defined for `|z| < 1` as .. math :: \,_2F_1(a,b,c,z) = \sum_{k=0}^{\infty} \frac{(a)_k (b)_k}{(c)_k} \frac{z^k}{k!}. and for `|z| \ge 1` by analytic continuation, with a branch cut on `(1, \infty)` when necessary. Special cases of this function include many of the orthogonal polynomials as well as the incomplete beta function and other functions. Properties of the Gauss hypergeometric function are documented comprehensively in many references, for example Abramowitz & Stegun, section 15. The implementation supports the analytic continuation as well as evaluation close to the unit circle where `|z| \approx 1`. The syntax ``hyp2f1(a,b,c,z)`` is equivalent to ``hyper([a,b],[c],z)``. **Examples** Evaluation with `z` inside, outside and on the unit circle, for fixed parameters:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyp2f1(2, (1,2), 4, 0.75) 1.303703703703703703703704 >>> hyp2f1(2, (1,2), 4, -1.75) 0.7431290566046919177853916 >>> hyp2f1(2, (1,2), 4, 1.75) (1.418075801749271137026239 - 1.114976146679907015775102j) >>> hyp2f1(2, (1,2), 4, 1) 1.6 >>> hyp2f1(2, (1,2), 4, -1) 0.8235498012182875315037882 >>> hyp2f1(2, (1,2), 4, j) (0.9144026291433065674259078 + 0.2050415770437884900574923j) >>> hyp2f1(2, (1,2), 4, 2+j) (0.9274013540258103029011549 + 0.7455257875808100868984496j) >>> hyp2f1(2, (1,2), 4, 0.25j) (0.9931169055799728251931672 + 0.06154836525312066938147793j) Evaluation with complex parameter values:: >>> hyp2f1(1+j, 0.75, 10j, 1+5j) (0.8834833319713479923389638 + 0.7053886880648105068343509j) Evaluation with `z = 1`:: >>> hyp2f1(-2.5, 3.5, 1.5, 1) 0.0 >>> hyp2f1(-2.5, 3, 4, 1) 0.06926406926406926406926407 >>> hyp2f1(2, 3, 4, 1) +inf Evaluation for huge arguments:: >>> hyp2f1((-1,3), 1.75, 4, '1e100') (7.883714220959876246415651e+32 + 1.365499358305579597618785e+33j) >>> hyp2f1((-1,3), 1.75, 4, '1e1000000') (7.883714220959876246415651e+333332 + 1.365499358305579597618785e+333333j) >>> hyp2f1((-1,3), 1.75, 4, '1e1000000j') (1.365499358305579597618785e+333333 - 7.883714220959876246415651e+333332j) An integral representation:: >>> a,b,c,z = -0.5, 1, 2.5, 0.25 >>> g = lambda t: t**(b-1) * (1-t)**(c-b-1) * (1-t*z)**(-a) >>> gammaprod([c],[b,c-b]) * quad(g, [0,1]) 0.9480458814362824478852618 >>> hyp2f1(a,b,c,z) 0.9480458814362824478852618 Verifying the hypergeometric differential equation:: >>> f = lambda z: hyp2f1(a,b,c,z) >>> chop(z*(1-z)*diff(f,z,2) + (c-(a+b+1)*z)*diff(f,z) - a*b*f(z)) 0.0 """ hyp3f2 = r""" Gives the generalized hypergeometric function `\,_3F_2`, defined for `|z| < 1` as .. math :: \,_3F_2(a_1,a_2,a_3,b_1,b_2,z) = \sum_{k=0}^{\infty} \frac{(a_1)_k (a_2)_k (a_3)_k}{(b_1)_k (b_2)_k} \frac{z^k}{k!}. and for `|z| \ge 1` by analytic continuation. The analytic structure of this function is similar to that of `\,_2F_1`, generally with a singularity at `z = 1` and a branch cut on `(1, \infty)`. Evaluation is supported inside, on, and outside the circle of convergence `|z| = 1`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyp3f2(1,2,3,4,5,0.25) 1.083533123380934241548707 >>> hyp3f2(1,2+2j,3,4,5,-10+10j) (0.1574651066006004632914361 - 0.03194209021885226400892963j) >>> hyp3f2(1,2,3,4,5,-10) 0.3071141169208772603266489 >>> hyp3f2(1,2,3,4,5,10) (-0.4857045320523947050581423 - 0.5988311440454888436888028j) >>> hyp3f2(0.25,1,1,2,1.5,1) 1.157370995096772047567631 >>> (8-pi-2*ln2)/3 1.157370995096772047567631 >>> hyp3f2(1+j,0.5j,2,1,-2j,-1) (1.74518490615029486475959 + 0.1454701525056682297614029j) >>> hyp3f2(1+j,0.5j,2,1,-2j,sqrt(j)) (0.9829816481834277511138055 - 0.4059040020276937085081127j) >>> hyp3f2(-3,2,1,-5,4,1) 1.41 >>> hyp3f2(-3,2,1,-5,4,2) 2.12 Evaluation very close to the unit circle:: >>> hyp3f2(1,2,3,4,5,'1.0001') (1.564877796743282766872279 - 3.76821518787438186031973e-11j) >>> hyp3f2(1,2,3,4,5,'1+0.0001j') (1.564747153061671573212831 + 0.0001305757570366084557648482j) >>> hyp3f2(1,2,3,4,5,'0.9999') 1.564616644881686134983664 >>> hyp3f2(1,2,3,4,5,'-0.9999') 0.7823896253461678060196207 .. note :: Evaluation for `|z-1|` small can currently be inaccurate or slow for some parameter combinations. For various parameter combinations, `\,_3F_2` admits representation in terms of hypergeometric functions of lower degree, or in terms of simpler functions:: >>> for a, b, z in [(1,2,-1), (2,0.5,1)]: ... hyp2f1(a,b,a+b+0.5,z)**2 ... hyp3f2(2*a,a+b,2*b,a+b+0.5,2*a+2*b,z) ... 0.4246104461966439006086308 0.4246104461966439006086308 7.111111111111111111111111 7.111111111111111111111111 >>> z = 2+3j >>> hyp3f2(0.5,1,1.5,2,2,z) (0.7621440939243342419729144 + 0.4249117735058037649915723j) >>> 4*(pi-2*ellipe(z))/(pi*z) (0.7621440939243342419729144 + 0.4249117735058037649915723j) """ hyperu = r""" Gives the Tricomi confluent hypergeometric function `U`, also known as the Kummer or confluent hypergeometric function of the second kind. This function gives a second linearly independent solution to the confluent hypergeometric differential equation (the first is provided by `\,_1F_1` -- see :func:`~mpmath.hyp1f1`). **Examples** Evaluation for arbitrary complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyperu(2,3,4) 0.0625 >>> hyperu(0.25, 5, 1000) 0.1779949416140579573763523 >>> hyperu(0.25, 5, -1000) (0.1256256609322773150118907 - 0.1256256609322773150118907j) The `U` function may be singular at `z = 0`:: >>> hyperu(1.5, 2, 0) +inf >>> hyperu(1.5, -2, 0) 0.1719434921288400112603671 Verifying the differential equation:: >>> a, b = 1.5, 2 >>> f = lambda z: hyperu(a,b,z) >>> for z in [-10, 3, 3+4j]: ... chop(z*diff(f,z,2) + (b-z)*diff(f,z) - a*f(z)) ... 0.0 0.0 0.0 An integral representation:: >>> a,b,z = 2, 3.5, 4.25 >>> hyperu(a,b,z) 0.06674960718150520648014567 >>> quad(lambda t: exp(-z*t)*t**(a-1)*(1+t)**(b-a-1),[0,inf]) / gamma(a) 0.06674960718150520648014567 [1] http://people.math.sfu.ca/~cbm/aands/page_504.htm """ hyp2f0 = r""" Gives the hypergeometric function `\,_2F_0`, defined formally by the series .. math :: \,_2F_0(a,b;;z) = \sum_{n=0}^{\infty} (a)_n (b)_n \frac{z^n}{n!}. This series usually does not converge. For small enough `z`, it can be viewed as an asymptotic series that may be summed directly with an appropriate truncation. When this is not the case, :func:`~mpmath.hyp2f0` gives a regularized sum, or equivalently, it uses a representation in terms of the hypergeometric U function [1]. The series also converges when either `a` or `b` is a nonpositive integer, as it then terminates into a polynomial after `-a` or `-b` terms. **Examples** Evaluation is supported for arbitrary complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hyp2f0((2,3), 1.25, -100) 0.07095851870980052763312791 >>> hyp2f0((2,3), 1.25, 100) (-0.03254379032170590665041131 + 0.07269254613282301012735797j) >>> hyp2f0(-0.75, 1-j, 4j) (-0.3579987031082732264862155 - 3.052951783922142735255881j) Even with real arguments, the regularized value of 2F0 is often complex-valued, but the imaginary part decreases exponentially as `z \to 0`. In the following example, the first call uses complex evaluation while the second has a small enough `z` to evaluate using the direct series and thus the returned value is strictly real (this should be taken to indicate that the imaginary part is less than ``eps``):: >>> mp.dps = 15 >>> hyp2f0(1.5, 0.5, 0.05) (1.04166637647907 + 8.34584913683906e-8j) >>> hyp2f0(1.5, 0.5, 0.0005) 1.00037535207621 The imaginary part can be retrieved by increasing the working precision:: >>> mp.dps = 80 >>> nprint(hyp2f0(1.5, 0.5, 0.009).imag) 1.23828e-46 In the polynomial case (the series terminating), 2F0 can evaluate exactly:: >>> mp.dps = 15 >>> hyp2f0(-6,-6,2) 291793.0 >>> identify(hyp2f0(-2,1,0.25)) '(5/8)' The coefficients of the polynomials can be recovered using Taylor expansion:: >>> nprint(taylor(lambda x: hyp2f0(-3,0.5,x), 0, 10)) [1.0, -1.5, 2.25, -1.875, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0] >>> nprint(taylor(lambda x: hyp2f0(-4,0.5,x), 0, 10)) [1.0, -2.0, 4.5, -7.5, 6.5625, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0] [1] http://people.math.sfu.ca/~cbm/aands/page_504.htm """ gammainc = r""" ``gammainc(z, a=0, b=inf)`` computes the (generalized) incomplete gamma function with integration limits `[a, b]`: .. math :: \Gamma(z,a,b) = \int_a^b t^{z-1} e^{-t} \, dt The generalized incomplete gamma function reduces to the following special cases when one or both endpoints are fixed: * `\Gamma(z,0,\infty)` is the standard ("complete") gamma function, `\Gamma(z)` (available directly as the mpmath function :func:`~mpmath.gamma`) * `\Gamma(z,a,\infty)` is the "upper" incomplete gamma function, `\Gamma(z,a)` * `\Gamma(z,0,b)` is the "lower" incomplete gamma function, `\gamma(z,b)`. Of course, we have `\Gamma(z,0,x) + \Gamma(z,x,\infty) = \Gamma(z)` for all `z` and `x`. Note however that some authors reverse the order of the arguments when defining the lower and upper incomplete gamma function, so one should be careful to get the correct definition. If also given the keyword argument ``regularized=True``, :func:`~mpmath.gammainc` computes the "regularized" incomplete gamma function .. math :: P(z,a,b) = \frac{\Gamma(z,a,b)}{\Gamma(z)}. **Examples** We can compare with numerical quadrature to verify that :func:`~mpmath.gammainc` computes the integral in the definition:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> gammainc(2+3j, 4, 10) (0.00977212668627705160602312 - 0.0770637306312989892451977j) >>> quad(lambda t: t**(2+3j-1) * exp(-t), [4, 10]) (0.00977212668627705160602312 - 0.0770637306312989892451977j) Argument symmetries follow directly from the integral definition:: >>> gammainc(3, 4, 5) + gammainc(3, 5, 4) 0.0 >>> gammainc(3,0,2) + gammainc(3,2,4); gammainc(3,0,4) 1.523793388892911312363331 1.523793388892911312363331 >>> findroot(lambda z: gammainc(2,z,3), 1) 3.0 Evaluation for arbitrarily large arguments:: >>> gammainc(10, 100) 4.083660630910611272288592e-26 >>> gammainc(10, 10000000000000000) 5.290402449901174752972486e-4342944819032375 >>> gammainc(3+4j, 1000000+1000000j) (-1.257913707524362408877881e-434284 + 2.556691003883483531962095e-434284j) Evaluation of a generalized incomplete gamma function automatically chooses the representation that gives a more accurate result, depending on which parameter is larger:: >>> gammainc(10000000, 3) - gammainc(10000000, 2) # Bad 0.0 >>> gammainc(10000000, 2, 3) # Good 1.755146243738946045873491e+4771204 >>> gammainc(2, 0, 100000001) - gammainc(2, 0, 100000000) # Bad 0.0 >>> gammainc(2, 100000000, 100000001) # Good 4.078258353474186729184421e-43429441 The incomplete gamma functions satisfy simple recurrence relations:: >>> mp.dps = 25 >>> z, a = mpf(3.5), mpf(2) >>> gammainc(z+1, a); z*gammainc(z,a) + a**z*exp(-a) 10.60130296933533459267329 10.60130296933533459267329 >>> gammainc(z+1,0,a); z*gammainc(z,0,a) - a**z*exp(-a) 1.030425427232114336470932 1.030425427232114336470932 Evaluation at integers and poles:: >>> gammainc(-3, -4, -5) (-0.2214577048967798566234192 + 0.0j) >>> gammainc(-3, 0, 5) +inf If `z` is an integer, the recurrence reduces the incomplete gamma function to `P(a) \exp(-a) + Q(b) \exp(-b)` where `P` and `Q` are polynomials:: >>> gammainc(1, 2); exp(-2) 0.1353352832366126918939995 0.1353352832366126918939995 >>> mp.dps = 50 >>> identify(gammainc(6, 1, 2), ['exp(-1)', 'exp(-2)']) '(326*exp(-1) + (-872)*exp(-2))' The incomplete gamma functions reduce to functions such as the exponential integral Ei and the error function for special arguments:: >>> mp.dps = 25 >>> gammainc(0, 4); -ei(-4) 0.00377935240984890647887486 0.00377935240984890647887486 >>> gammainc(0.5, 0, 2); sqrt(pi)*erf(sqrt(2)) 1.691806732945198336509541 1.691806732945198336509541 """ erf = r""" Computes the error function, `\mathrm{erf}(x)`. The error function is the normalized antiderivative of the Gaussian function `\exp(-t^2)`. More precisely, .. math:: \mathrm{erf}(x) = \frac{2}{\sqrt \pi} \int_0^x \exp(-t^2) \,dt **Basic examples** Simple values and limits include:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> erf(0) 0.0 >>> erf(1) 0.842700792949715 >>> erf(-1) -0.842700792949715 >>> erf(inf) 1.0 >>> erf(-inf) -1.0 For large real `x`, `\mathrm{erf}(x)` approaches 1 very rapidly:: >>> erf(3) 0.999977909503001 >>> erf(5) 0.999999999998463 The error function is an odd function:: >>> nprint(chop(taylor(erf, 0, 5))) [0.0, 1.12838, 0.0, -0.376126, 0.0, 0.112838] :func:`~mpmath.erf` implements arbitrary-precision evaluation and supports complex numbers:: >>> mp.dps = 50 >>> erf(0.5) 0.52049987781304653768274665389196452873645157575796 >>> mp.dps = 25 >>> erf(1+j) (1.316151281697947644880271 + 0.1904534692378346862841089j) Evaluation is supported for large arguments:: >>> mp.dps = 25 >>> erf('1e1000') 1.0 >>> erf('-1e1000') -1.0 >>> erf('1e-1000') 1.128379167095512573896159e-1000 >>> erf('1e7j') (0.0 + 8.593897639029319267398803e+43429448190317j) >>> erf('1e7+1e7j') (0.9999999858172446172631323 + 3.728805278735270407053139e-8j) **Related functions** See also :func:`~mpmath.erfc`, which is more accurate for large `x`, and :func:`~mpmath.erfi` which gives the antiderivative of `\exp(t^2)`. The Fresnel integrals :func:`~mpmath.fresnels` and :func:`~mpmath.fresnelc` are also related to the error function. """ erfc = r""" Computes the complementary error function, `\mathrm{erfc}(x) = 1-\mathrm{erf}(x)`. This function avoids cancellation that occurs when naively computing the complementary error function as ``1-erf(x)``:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> 1 - erf(10) 0.0 >>> erfc(10) 2.08848758376254e-45 :func:`~mpmath.erfc` works accurately even for ludicrously large arguments:: >>> erfc(10**10) 4.3504398860243e-43429448190325182776 Complex arguments are supported:: >>> erfc(500+50j) (1.19739830969552e-107492 + 1.46072418957528e-107491j) """ erfi = r""" Computes the imaginary error function, `\mathrm{erfi}(x)`. The imaginary error function is defined in analogy with the error function, but with a positive sign in the integrand: .. math :: \mathrm{erfi}(x) = \frac{2}{\sqrt \pi} \int_0^x \exp(t^2) \,dt Whereas the error function rapidly converges to 1 as `x` grows, the imaginary error function rapidly diverges to infinity. The functions are related as `\mathrm{erfi}(x) = -i\,\mathrm{erf}(ix)` for all complex numbers `x`. **Examples** Basic values and limits:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> erfi(0) 0.0 >>> erfi(1) 1.65042575879754 >>> erfi(-1) -1.65042575879754 >>> erfi(inf) +inf >>> erfi(-inf) -inf Note the symmetry between erf and erfi:: >>> erfi(3j) (0.0 + 0.999977909503001j) >>> erf(3) 0.999977909503001 >>> erf(1+2j) (-0.536643565778565 - 5.04914370344703j) >>> erfi(2+1j) (-5.04914370344703 - 0.536643565778565j) Large arguments are supported:: >>> erfi(1000) 1.71130938718796e+434291 >>> erfi(10**10) 7.3167287567024e+43429448190325182754 >>> erfi(-10**10) -7.3167287567024e+43429448190325182754 >>> erfi(1000-500j) (2.49895233563961e+325717 + 2.6846779342253e+325717j) >>> erfi(100000j) (0.0 + 1.0j) >>> erfi(-100000j) (0.0 - 1.0j) """ erfinv = r""" Computes the inverse error function, satisfying .. math :: \mathrm{erf}(\mathrm{erfinv}(x)) = \mathrm{erfinv}(\mathrm{erf}(x)) = x. This function is defined only for `-1 \le x \le 1`. **Examples** Special values include:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> erfinv(0) 0.0 >>> erfinv(1) +inf >>> erfinv(-1) -inf The domain is limited to the standard interval:: >>> erfinv(2) Traceback (most recent call last): ... ValueError: erfinv(x) is defined only for -1 <= x <= 1 It is simple to check that :func:`~mpmath.erfinv` computes inverse values of :func:`~mpmath.erf` as promised:: >>> erf(erfinv(0.75)) 0.75 >>> erf(erfinv(-0.995)) -0.995 :func:`~mpmath.erfinv` supports arbitrary-precision evaluation:: >>> mp.dps = 50 >>> x = erf(2) >>> x 0.99532226501895273416206925636725292861089179704006 >>> erfinv(x) 2.0 A definite integral involving the inverse error function:: >>> mp.dps = 15 >>> quad(erfinv, [0, 1]) 0.564189583547756 >>> 1/sqrt(pi) 0.564189583547756 The inverse error function can be used to generate random numbers with a Gaussian distribution (although this is a relatively inefficient algorithm):: >>> nprint([erfinv(2*rand()-1) for n in range(6)]) # doctest: +SKIP [-0.586747, 1.10233, -0.376796, 0.926037, -0.708142, -0.732012] """ npdf = r""" ``npdf(x, mu=0, sigma=1)`` evaluates the probability density function of a normal distribution with mean value `\mu` and variance `\sigma^2`. Elementary properties of the probability distribution can be verified using numerical integration:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> quad(npdf, [-inf, inf]) 1.0 >>> quad(lambda x: npdf(x, 3), [3, inf]) 0.5 >>> quad(lambda x: npdf(x, 3, 2), [3, inf]) 0.5 See also :func:`~mpmath.ncdf`, which gives the cumulative distribution. """ ncdf = r""" ``ncdf(x, mu=0, sigma=1)`` evaluates the cumulative distribution function of a normal distribution with mean value `\mu` and variance `\sigma^2`. See also :func:`~mpmath.npdf`, which gives the probability density. Elementary properties include:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> ncdf(pi, mu=pi) 0.5 >>> ncdf(-inf) 0.0 >>> ncdf(+inf) 1.0 The cumulative distribution is the integral of the density function having identical mu and sigma:: >>> mp.dps = 15 >>> diff(ncdf, 2) 0.053990966513188 >>> npdf(2) 0.053990966513188 >>> diff(lambda x: ncdf(x, 1, 0.5), 0) 0.107981933026376 >>> npdf(0, 1, 0.5) 0.107981933026376 """ expint = r""" :func:`~mpmath.expint(n,z)` gives the generalized exponential integral or En-function, .. math :: \mathrm{E}_n(z) = \int_1^{\infty} \frac{e^{-zt}}{t^n} dt, where `n` and `z` may both be complex numbers. The case with `n = 1` is also given by :func:`~mpmath.e1`. **Examples** Evaluation at real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> expint(1, 6.25) 0.0002704758872637179088496194 >>> expint(-3, 2+3j) (0.00299658467335472929656159 + 0.06100816202125885450319632j) >>> expint(2+3j, 4-5j) (0.001803529474663565056945248 - 0.002235061547756185403349091j) At negative integer values of `n`, `E_n(z)` reduces to a rational-exponential function:: >>> f = lambda n, z: fac(n)*sum(z**k/fac(k-1) for k in range(1,n+2))/\ ... exp(z)/z**(n+2) >>> n = 3 >>> z = 1/pi >>> expint(-n,z) 584.2604820613019908668219 >>> f(n,z) 584.2604820613019908668219 >>> n = 5 >>> expint(-n,z) 115366.5762594725451811138 >>> f(n,z) 115366.5762594725451811138 """ e1 = r""" Computes the exponential integral `\mathrm{E}_1(z)`, given by .. math :: \mathrm{E}_1(z) = \int_z^{\infty} \frac{e^{-t}}{t} dt. This is equivalent to :func:`~mpmath.expint` with `n = 1`. **Examples** Two ways to evaluate this function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> e1(6.25) 0.0002704758872637179088496194 >>> expint(1,6.25) 0.0002704758872637179088496194 The E1-function is essentially the same as the Ei-function (:func:`~mpmath.ei`) with negated argument, except for an imaginary branch cut term:: >>> e1(2.5) 0.02491491787026973549562801 >>> -ei(-2.5) 0.02491491787026973549562801 >>> e1(-2.5) (-7.073765894578600711923552 - 3.141592653589793238462643j) >>> -ei(2.5) -7.073765894578600711923552 """ ei = r""" Computes the exponential integral or Ei-function, `\mathrm{Ei}(x)`. The exponential integral is defined as .. math :: \mathrm{Ei}(x) = \int_{-\infty\,}^x \frac{e^t}{t} \, dt. When the integration range includes `t = 0`, the exponential integral is interpreted as providing the Cauchy principal value. For real `x`, the Ei-function behaves roughly like `\mathrm{Ei}(x) \approx \exp(x) + \log(|x|)`. The Ei-function is related to the more general family of exponential integral functions denoted by `E_n`, which are available as :func:`~mpmath.expint`. **Basic examples** Some basic values and limits are:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> ei(0) -inf >>> ei(1) 1.89511781635594 >>> ei(inf) +inf >>> ei(-inf) 0.0 For `x < 0`, the defining integral can be evaluated numerically as a reference:: >>> ei(-4) -0.00377935240984891 >>> quad(lambda t: exp(t)/t, [-inf, -4]) -0.00377935240984891 :func:`~mpmath.ei` supports complex arguments and arbitrary precision evaluation:: >>> mp.dps = 50 >>> ei(pi) 10.928374389331410348638445906907535171566338835056 >>> mp.dps = 25 >>> ei(3+4j) (-4.154091651642689822535359 + 4.294418620024357476985535j) **Related functions** The exponential integral is closely related to the logarithmic integral. See :func:`~mpmath.li` for additional information. The exponential integral is related to the hyperbolic and trigonometric integrals (see :func:`~mpmath.chi`, :func:`~mpmath.shi`, :func:`~mpmath.ci`, :func:`~mpmath.si`) similarly to how the ordinary exponential function is related to the hyperbolic and trigonometric functions:: >>> mp.dps = 15 >>> ei(3) 9.93383257062542 >>> chi(3) + shi(3) 9.93383257062542 >>> chop(ci(3j) - j*si(3j) - pi*j/2) 9.93383257062542 Beware that logarithmic corrections, as in the last example above, are required to obtain the correct branch in general. For details, see [1]. The exponential integral is also a special case of the hypergeometric function `\,_2F_2`:: >>> z = 0.6 >>> z*hyper([1,1],[2,2],z) + (ln(z)-ln(1/z))/2 + euler 0.769881289937359 >>> ei(z) 0.769881289937359 **References** 1. Relations between Ei and other functions: http://functions.wolfram.com/GammaBetaErf/ExpIntegralEi/27/01/ 2. Abramowitz & Stegun, section 5: http://people.math.sfu.ca/~cbm/aands/page_228.htm 3. Asymptotic expansion for Ei: http://mathworld.wolfram.com/En-Function.html """ li = r""" Computes the logarithmic integral or li-function `\mathrm{li}(x)`, defined by .. math :: \mathrm{li}(x) = \int_0^x \frac{1}{\log t} \, dt The logarithmic integral has a singularity at `x = 1`. Alternatively, ``li(x, offset=True)`` computes the offset logarithmic integral (used in number theory) .. math :: \mathrm{Li}(x) = \int_2^x \frac{1}{\log t} \, dt. These two functions are related via the simple identity `\mathrm{Li}(x) = \mathrm{li}(x) - \mathrm{li}(2)`. The logarithmic integral should also not be confused with the polylogarithm (also denoted by Li), which is implemented as :func:`~mpmath.polylog`. **Examples** Some basic values and limits:: >>> from mpmath import * >>> mp.dps = 30; mp.pretty = True >>> li(0) 0.0 >>> li(1) -inf >>> li(1) -inf >>> li(2) 1.04516378011749278484458888919 >>> findroot(li, 2) 1.45136923488338105028396848589 >>> li(inf) +inf >>> li(2, offset=True) 0.0 >>> li(1, offset=True) -inf >>> li(0, offset=True) -1.04516378011749278484458888919 >>> li(10, offset=True) 5.12043572466980515267839286347 The logarithmic integral can be evaluated for arbitrary complex arguments:: >>> mp.dps = 20 >>> li(3+4j) (3.1343755504645775265 + 2.6769247817778742392j) The logarithmic integral is related to the exponential integral:: >>> ei(log(3)) 2.1635885946671919729 >>> li(3) 2.1635885946671919729 The logarithmic integral grows like `O(x/\log(x))`:: >>> mp.dps = 15 >>> x = 10**100 >>> x/log(x) 4.34294481903252e+97 >>> li(x) 4.3619719871407e+97 The prime number theorem states that the number of primes less than `x` is asymptotic to `\mathrm{Li}(x)` (equivalently `\mathrm{li}(x)`). For example, it is known that there are exactly 1,925,320,391,606,803,968,923 prime numbers less than `10^{23}` [1]. The logarithmic integral provides a very accurate estimate:: >>> li(10**23, offset=True) 1.92532039161405e+21 A definite integral is:: >>> quad(li, [0, 1]) -0.693147180559945 >>> -ln(2) -0.693147180559945 **References** 1. http://mathworld.wolfram.com/PrimeCountingFunction.html 2. http://mathworld.wolfram.com/LogarithmicIntegral.html """ ci = r""" Computes the cosine integral, .. math :: \mathrm{Ci}(x) = -\int_x^{\infty} \frac{\cos t}{t}\,dt = \gamma + \log x + \int_0^x \frac{\cos t - 1}{t}\,dt **Examples** Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> ci(0) -inf >>> ci(1) 0.3374039229009681346626462 >>> ci(pi) 0.07366791204642548599010096 >>> ci(inf) 0.0 >>> ci(-inf) (0.0 + 3.141592653589793238462643j) >>> ci(2+3j) (1.408292501520849518759125 - 2.983617742029605093121118j) The cosine integral behaves roughly like the sinc function (see :func:`~mpmath.sinc`) for large real `x`:: >>> ci(10**10) -4.875060251748226537857298e-11 >>> sinc(10**10) -4.875060250875106915277943e-11 >>> chop(limit(ci, inf)) 0.0 It has infinitely many roots on the positive real axis:: >>> findroot(ci, 1) 0.6165054856207162337971104 >>> findroot(ci, 2) 3.384180422551186426397851 Evaluation is supported for `z` anywhere in the complex plane:: >>> ci(10**6*(1+j)) (4.449410587611035724984376e+434287 + 9.75744874290013526417059e+434287j) We can evaluate the defining integral as a reference:: >>> mp.dps = 15 >>> -quadosc(lambda t: cos(t)/t, [5, inf], omega=1) -0.190029749656644 >>> ci(5) -0.190029749656644 Some infinite series can be evaluated using the cosine integral:: >>> nsum(lambda k: (-1)**k/(fac(2*k)*(2*k)), [1,inf]) -0.239811742000565 >>> ci(1) - euler -0.239811742000565 """ si = r""" Computes the sine integral, .. math :: \mathrm{Si}(x) = \int_0^x \frac{\sin t}{t}\,dt. The sine integral is thus the antiderivative of the sinc function (see :func:`~mpmath.sinc`). **Examples** Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> si(0) 0.0 >>> si(1) 0.9460830703671830149413533 >>> si(-1) -0.9460830703671830149413533 >>> si(pi) 1.851937051982466170361053 >>> si(inf) 1.570796326794896619231322 >>> si(-inf) -1.570796326794896619231322 >>> si(2+3j) (4.547513889562289219853204 + 1.399196580646054789459839j) The sine integral approaches `\pi/2` for large real `x`:: >>> si(10**10) 1.570796326707584656968511 >>> pi/2 1.570796326794896619231322 Evaluation is supported for `z` anywhere in the complex plane:: >>> si(10**6*(1+j)) (-9.75744874290013526417059e+434287 + 4.449410587611035724984376e+434287j) We can evaluate the defining integral as a reference:: >>> mp.dps = 15 >>> quad(sinc, [0, 5]) 1.54993124494467 >>> si(5) 1.54993124494467 Some infinite series can be evaluated using the sine integral:: >>> nsum(lambda k: (-1)**k/(fac(2*k+1)*(2*k+1)), [0,inf]) 0.946083070367183 >>> si(1) 0.946083070367183 """ chi = r""" Computes the hyperbolic cosine integral, defined in analogy with the cosine integral (see :func:`~mpmath.ci`) as .. math :: \mathrm{Chi}(x) = -\int_x^{\infty} \frac{\cosh t}{t}\,dt = \gamma + \log x + \int_0^x \frac{\cosh t - 1}{t}\,dt Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> chi(0) -inf >>> chi(1) 0.8378669409802082408946786 >>> chi(inf) +inf >>> findroot(chi, 0.5) 0.5238225713898644064509583 >>> chi(2+3j) (-0.1683628683277204662429321 + 2.625115880451325002151688j) Evaluation is supported for `z` anywhere in the complex plane:: >>> chi(10**6*(1+j)) (4.449410587611035724984376e+434287 - 9.75744874290013526417059e+434287j) """ shi = r""" Computes the hyperbolic sine integral, defined in analogy with the sine integral (see :func:`~mpmath.si`) as .. math :: \mathrm{Shi}(x) = \int_0^x \frac{\sinh t}{t}\,dt. Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> shi(0) 0.0 >>> shi(1) 1.057250875375728514571842 >>> shi(-1) -1.057250875375728514571842 >>> shi(inf) +inf >>> shi(2+3j) (-0.1931890762719198291678095 + 2.645432555362369624818525j) Evaluation is supported for `z` anywhere in the complex plane:: >>> shi(10**6*(1+j)) (4.449410587611035724984376e+434287 - 9.75744874290013526417059e+434287j) """ fresnels = r""" Computes the Fresnel sine integral .. math :: S(x) = \int_0^x \sin\left(\frac{\pi t^2}{2}\right) \,dt Note that some sources define this function without the normalization factor `\pi/2`. **Examples** Some basic values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> fresnels(0) 0.0 >>> fresnels(inf) 0.5 >>> fresnels(-inf) -0.5 >>> fresnels(1) 0.4382591473903547660767567 >>> fresnels(1+2j) (36.72546488399143842838788 + 15.58775110440458732748279j) Comparing with the definition:: >>> fresnels(3) 0.4963129989673750360976123 >>> quad(lambda t: sin(pi*t**2/2), [0,3]) 0.4963129989673750360976123 """ fresnelc = r""" Computes the Fresnel cosine integral .. math :: C(x) = \int_0^x \cos\left(\frac{\pi t^2}{2}\right) \,dt Note that some sources define this function without the normalization factor `\pi/2`. **Examples** Some basic values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> fresnelc(0) 0.0 >>> fresnelc(inf) 0.5 >>> fresnelc(-inf) -0.5 >>> fresnelc(1) 0.7798934003768228294742064 >>> fresnelc(1+2j) (16.08787137412548041729489 - 36.22568799288165021578758j) Comparing with the definition:: >>> fresnelc(3) 0.6057207892976856295561611 >>> quad(lambda t: cos(pi*t**2/2), [0,3]) 0.6057207892976856295561611 """ airyai = r""" Computes the Airy function `\operatorname{Ai}(z)`, which is the solution of the Airy differential equation `f''(z) - z f(z) = 0` with initial conditions .. math :: \operatorname{Ai}(0) = \frac{1}{3^{2/3}\Gamma\left(\frac{2}{3}\right)} \operatorname{Ai}'(0) = -\frac{1}{3^{1/3}\Gamma\left(\frac{1}{3}\right)}. Other common ways of defining the Ai-function include integrals such as .. math :: \operatorname{Ai}(x) = \frac{1}{\pi} \int_0^{\infty} \cos\left(\frac{1}{3}t^3+xt\right) dt \qquad x \in \mathbb{R} \operatorname{Ai}(z) = \frac{\sqrt{3}}{2\pi} \int_0^{\infty} \exp\left(-\frac{t^3}{3}-\frac{z^3}{3t^3}\right) dt. The Ai-function is an entire function with a turning point, behaving roughly like a slowly decaying sine wave for `z < 0` and like a rapidly decreasing exponential for `z > 0`. A second solution of the Airy differential equation is given by `\operatorname{Bi}(z)` (see :func:`~mpmath.airybi`). Optionally, with *derivative=alpha*, :func:`airyai` can compute the `\alpha`-th order fractional derivative with respect to `z`. For `\alpha = n = 1,2,3,\ldots` this gives the derivative `\operatorname{Ai}^{(n)}(z)`, and for `\alpha = -n = -1,-2,-3,\ldots` this gives the `n`-fold iterated integral .. math :: f_0(z) = \operatorname{Ai}(z) f_n(z) = \int_0^z f_{n-1}(t) dt. The Ai-function has infinitely many zeros, all located along the negative half of the real axis. They can be computed with :func:`~mpmath.airyaizero`. **Plots** .. literalinclude :: /plots/ai.py .. image :: /plots/ai.png .. literalinclude :: /plots/ai_c.py .. image :: /plots/ai_c.png **Basic examples** Limits and values include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> airyai(0); 1/(power(3,'2/3')*gamma('2/3')) 0.3550280538878172392600632 0.3550280538878172392600632 >>> airyai(1) 0.1352924163128814155241474 >>> airyai(-1) 0.5355608832923521187995166 >>> airyai(inf); airyai(-inf) 0.0 0.0 Evaluation is supported for large magnitudes of the argument:: >>> airyai(-100) 0.1767533932395528780908311 >>> airyai(100) 2.634482152088184489550553e-291 >>> airyai(50+50j) (-5.31790195707456404099817e-68 - 1.163588003770709748720107e-67j) >>> airyai(-50+50j) (1.041242537363167632587245e+158 + 3.347525544923600321838281e+157j) Huge arguments are also fine:: >>> airyai(10**10) 1.162235978298741779953693e-289529654602171 >>> airyai(-10**10) 0.0001736206448152818510510181 >>> w = airyai(10**10*(1+j)) >>> w.real 5.711508683721355528322567e-186339621747698 >>> w.imag 1.867245506962312577848166e-186339621747697 The first root of the Ai-function is:: >>> findroot(airyai, -2) -2.338107410459767038489197 >>> airyaizero(1) -2.338107410459767038489197 **Properties and relations** Verifying the Airy differential equation:: >>> for z in [-3.4, 0, 2.5, 1+2j]: ... chop(airyai(z,2) - z*airyai(z)) ... 0.0 0.0 0.0 0.0 The first few terms of the Taylor series expansion around `z = 0` (every third term is zero):: >>> nprint(taylor(airyai, 0, 5)) [0.355028, -0.258819, 0.0, 0.0591713, -0.0215683, 0.0] The Airy functions satisfy the Wronskian relation `\operatorname{Ai}(z) \operatorname{Bi}'(z) - \operatorname{Ai}'(z) \operatorname{Bi}(z) = 1/\pi`:: >>> z = -0.5 >>> airyai(z)*airybi(z,1) - airyai(z,1)*airybi(z) 0.3183098861837906715377675 >>> 1/pi 0.3183098861837906715377675 The Airy functions can be expressed in terms of Bessel functions of order `\pm 1/3`. For `\Re[z] \le 0`, we have:: >>> z = -3 >>> airyai(z) -0.3788142936776580743472439 >>> y = 2*power(-z,'3/2')/3 >>> (sqrt(-z) * (besselj('1/3',y) + besselj('-1/3',y)))/3 -0.3788142936776580743472439 **Derivatives and integrals** Derivatives of the Ai-function (directly and using :func:`~mpmath.diff`):: >>> airyai(-3,1); diff(airyai,-3) 0.3145837692165988136507873 0.3145837692165988136507873 >>> airyai(-3,2); diff(airyai,-3,2) 1.136442881032974223041732 1.136442881032974223041732 >>> airyai(1000,1); diff(airyai,1000) -2.943133917910336090459748e-9156 -2.943133917910336090459748e-9156 Several derivatives at `z = 0`:: >>> airyai(0,0); airyai(0,1); airyai(0,2) 0.3550280538878172392600632 -0.2588194037928067984051836 0.0 >>> airyai(0,3); airyai(0,4); airyai(0,5) 0.3550280538878172392600632 -0.5176388075856135968103671 0.0 >>> airyai(0,15); airyai(0,16); airyai(0,17) 1292.30211615165475090663 -3188.655054727379756351861 0.0 The integral of the Ai-function:: >>> airyai(3,-1); quad(airyai, [0,3]) 0.3299203760070217725002701 0.3299203760070217725002701 >>> airyai(-10,-1); quad(airyai, [0,-10]) -0.765698403134212917425148 -0.765698403134212917425148 Integrals of high or fractional order:: >>> airyai(-2,0.5); differint(airyai,-2,0.5,0) (0.0 + 0.2453596101351438273844725j) (0.0 + 0.2453596101351438273844725j) >>> airyai(-2,-4); differint(airyai,-2,-4,0) 0.2939176441636809580339365 0.2939176441636809580339365 >>> airyai(0,-1); airyai(0,-2); airyai(0,-3) 0.0 0.0 0.0 Integrals of the Ai-function can be evaluated at limit points:: >>> airyai(-1000000,-1); airyai(-inf,-1) -0.6666843728311539978751512 -0.6666666666666666666666667 >>> airyai(10,-1); airyai(+inf,-1) 0.3333333332991690159427932 0.3333333333333333333333333 >>> airyai(+inf,-2); airyai(+inf,-3) +inf +inf >>> airyai(-1000000,-2); airyai(-inf,-2) 666666.4078472650651209742 +inf >>> airyai(-1000000,-3); airyai(-inf,-3) -333333074513.7520264995733 -inf **References** 1. [DLMF]_ Chapter 9: Airy and Related Functions 2. [WolframFunctions]_ section: Bessel-Type Functions """ airybi = r""" Computes the Airy function `\operatorname{Bi}(z)`, which is the solution of the Airy differential equation `f''(z) - z f(z) = 0` with initial conditions .. math :: \operatorname{Bi}(0) = \frac{1}{3^{1/6}\Gamma\left(\frac{2}{3}\right)} \operatorname{Bi}'(0) = \frac{3^{1/6}}{\Gamma\left(\frac{1}{3}\right)}. Like the Ai-function (see :func:`~mpmath.airyai`), the Bi-function is oscillatory for `z < 0`, but it grows rather than decreases for `z > 0`. Optionally, as for :func:`~mpmath.airyai`, derivatives, integrals and fractional derivatives can be computed with the *derivative* parameter. The Bi-function has infinitely many zeros along the negative half-axis, as well as complex zeros, which can all be computed with :func:`~mpmath.airybizero`. **Plots** .. literalinclude :: /plots/bi.py .. image :: /plots/bi.png .. literalinclude :: /plots/bi_c.py .. image :: /plots/bi_c.png **Basic examples** Limits and values include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> airybi(0); 1/(power(3,'1/6')*gamma('2/3')) 0.6149266274460007351509224 0.6149266274460007351509224 >>> airybi(1) 1.207423594952871259436379 >>> airybi(-1) 0.10399738949694461188869 >>> airybi(inf); airybi(-inf) +inf 0.0 Evaluation is supported for large magnitudes of the argument:: >>> airybi(-100) 0.02427388768016013160566747 >>> airybi(100) 6.041223996670201399005265e+288 >>> airybi(50+50j) (-5.322076267321435669290334e+63 + 1.478450291165243789749427e+65j) >>> airybi(-50+50j) (-3.347525544923600321838281e+157 + 1.041242537363167632587245e+158j) Huge arguments:: >>> airybi(10**10) 1.369385787943539818688433e+289529654602165 >>> airybi(-10**10) 0.001775656141692932747610973 >>> w = airybi(10**10*(1+j)) >>> w.real -6.559955931096196875845858e+186339621747689 >>> w.imag -6.822462726981357180929024e+186339621747690 The first real root of the Bi-function is:: >>> findroot(airybi, -1); airybizero(1) -1.17371322270912792491998 -1.17371322270912792491998 **Properties and relations** Verifying the Airy differential equation:: >>> for z in [-3.4, 0, 2.5, 1+2j]: ... chop(airybi(z,2) - z*airybi(z)) ... 0.0 0.0 0.0 0.0 The first few terms of the Taylor series expansion around `z = 0` (every third term is zero):: >>> nprint(taylor(airybi, 0, 5)) [0.614927, 0.448288, 0.0, 0.102488, 0.0373574, 0.0] The Airy functions can be expressed in terms of Bessel functions of order `\pm 1/3`. For `\Re[z] \le 0`, we have:: >>> z = -3 >>> airybi(z) -0.1982896263749265432206449 >>> p = 2*power(-z,'3/2')/3 >>> sqrt(-mpf(z)/3)*(besselj('-1/3',p) - besselj('1/3',p)) -0.1982896263749265432206449 **Derivatives and integrals** Derivatives of the Bi-function (directly and using :func:`~mpmath.diff`):: >>> airybi(-3,1); diff(airybi,-3) -0.675611222685258537668032 -0.675611222685258537668032 >>> airybi(-3,2); diff(airybi,-3,2) 0.5948688791247796296619346 0.5948688791247796296619346 >>> airybi(1000,1); diff(airybi,1000) 1.710055114624614989262335e+9156 1.710055114624614989262335e+9156 Several derivatives at `z = 0`:: >>> airybi(0,0); airybi(0,1); airybi(0,2) 0.6149266274460007351509224 0.4482883573538263579148237 0.0 >>> airybi(0,3); airybi(0,4); airybi(0,5) 0.6149266274460007351509224 0.8965767147076527158296474 0.0 >>> airybi(0,15); airybi(0,16); airybi(0,17) 2238.332923903442675949357 5522.912562599140729510628 0.0 The integral of the Bi-function:: >>> airybi(3,-1); quad(airybi, [0,3]) 10.06200303130620056316655 10.06200303130620056316655 >>> airybi(-10,-1); quad(airybi, [0,-10]) -0.01504042480614002045135483 -0.01504042480614002045135483 Integrals of high or fractional order:: >>> airybi(-2,0.5); differint(airybi, -2, 0.5, 0) (0.0 + 0.5019859055341699223453257j) (0.0 + 0.5019859055341699223453257j) >>> airybi(-2,-4); differint(airybi,-2,-4,0) 0.2809314599922447252139092 0.2809314599922447252139092 >>> airybi(0,-1); airybi(0,-2); airybi(0,-3) 0.0 0.0 0.0 Integrals of the Bi-function can be evaluated at limit points:: >>> airybi(-1000000,-1); airybi(-inf,-1) 0.000002191261128063434047966873 0.0 >>> airybi(10,-1); airybi(+inf,-1) 147809803.1074067161675853 +inf >>> airybi(+inf,-2); airybi(+inf,-3) +inf +inf >>> airybi(-1000000,-2); airybi(-inf,-2) 0.4482883750599908479851085 0.4482883573538263579148237 >>> gamma('2/3')*power(3,'2/3')/(2*pi) 0.4482883573538263579148237 >>> airybi(-100000,-3); airybi(-inf,-3) -44828.52827206932872493133 -inf >>> airybi(-100000,-4); airybi(-inf,-4) 2241411040.437759489540248 +inf """ airyaizero = r""" Gives the `k`-th zero of the Airy Ai-function, i.e. the `k`-th number `a_k` ordered by magnitude for which `\operatorname{Ai}(a_k) = 0`. Optionally, with *derivative=1*, the corresponding zero `a'_k` of the derivative function, i.e. `\operatorname{Ai}'(a'_k) = 0`, is computed. **Examples** Some values of `a_k`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> airyaizero(1) -2.338107410459767038489197 >>> airyaizero(2) -4.087949444130970616636989 >>> airyaizero(3) -5.520559828095551059129856 >>> airyaizero(1000) -281.0315196125215528353364 Some values of `a'_k`:: >>> airyaizero(1,1) -1.018792971647471089017325 >>> airyaizero(2,1) -3.248197582179836537875424 >>> airyaizero(3,1) -4.820099211178735639400616 >>> airyaizero(1000,1) -280.9378080358935070607097 Verification:: >>> chop(airyai(airyaizero(1))) 0.0 >>> chop(airyai(airyaizero(1,1),1)) 0.0 """ airybizero = r""" With *complex=False*, gives the `k`-th real zero of the Airy Bi-function, i.e. the `k`-th number `b_k` ordered by magnitude for which `\operatorname{Bi}(b_k) = 0`. With *complex=True*, gives the `k`-th complex zero in the upper half plane `\beta_k`. Also the conjugate `\overline{\beta_k}` is a zero. Optionally, with *derivative=1*, the corresponding zero `b'_k` or `\beta'_k` of the derivative function, i.e. `\operatorname{Bi}'(b'_k) = 0` or `\operatorname{Bi}'(\beta'_k) = 0`, is computed. **Examples** Some values of `b_k`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> airybizero(1) -1.17371322270912792491998 >>> airybizero(2) -3.271093302836352715680228 >>> airybizero(3) -4.830737841662015932667709 >>> airybizero(1000) -280.9378112034152401578834 Some values of `b_k`:: >>> airybizero(1,1) -2.294439682614123246622459 >>> airybizero(2,1) -4.073155089071828215552369 >>> airybizero(3,1) -5.512395729663599496259593 >>> airybizero(1000,1) -281.0315164471118527161362 Some values of `\beta_k`:: >>> airybizero(1,complex=True) (0.9775448867316206859469927 + 2.141290706038744575749139j) >>> airybizero(2,complex=True) (1.896775013895336346627217 + 3.627291764358919410440499j) >>> airybizero(3,complex=True) (2.633157739354946595708019 + 4.855468179979844983174628j) >>> airybizero(1000,complex=True) (140.4978560578493018899793 + 243.3907724215792121244867j) Some values of `\beta'_k`:: >>> airybizero(1,1,complex=True) (0.2149470745374305676088329 + 1.100600143302797880647194j) >>> airybizero(2,1,complex=True) (1.458168309223507392028211 + 2.912249367458445419235083j) >>> airybizero(3,1,complex=True) (2.273760763013482299792362 + 4.254528549217097862167015j) >>> airybizero(1000,1,complex=True) (140.4509972835270559730423 + 243.3096175398562811896208j) Verification:: >>> chop(airybi(airybizero(1))) 0.0 >>> chop(airybi(airybizero(1,1),1)) 0.0 >>> u = airybizero(1,complex=True) >>> chop(airybi(u)) 0.0 >>> chop(airybi(conj(u))) 0.0 The complex zeros (in the upper and lower half-planes respectively) asymptotically approach the rays `z = R \exp(\pm i \pi /3)`:: >>> arg(airybizero(1,complex=True)) 1.142532510286334022305364 >>> arg(airybizero(1000,complex=True)) 1.047271114786212061583917 >>> arg(airybizero(1000000,complex=True)) 1.047197624741816183341355 >>> pi/3 1.047197551196597746154214 """ ellipk = r""" Evaluates the complete elliptic integral of the first kind, `K(m)`, defined by .. math :: K(m) = \int_0^{\pi/2} \frac{dt}{\sqrt{1-m \sin^2 t}} \, = \, \frac{\pi}{2} \,_2F_1\left(\frac{1}{2}, \frac{1}{2}, 1, m\right). Note that the argument is the parameter `m = k^2`, not the modulus `k` which is sometimes used. **Plots** .. literalinclude :: /plots/ellipk.py .. image :: /plots/ellipk.png **Examples** Values and limits include:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> ellipk(0) 1.570796326794896619231322 >>> ellipk(inf) (0.0 + 0.0j) >>> ellipk(-inf) 0.0 >>> ellipk(1) +inf >>> ellipk(-1) 1.31102877714605990523242 >>> ellipk(2) (1.31102877714605990523242 - 1.31102877714605990523242j) Verifying the defining integral and hypergeometric representation:: >>> ellipk(0.5) 1.85407467730137191843385 >>> quad(lambda t: (1-0.5*sin(t)**2)**-0.5, [0, pi/2]) 1.85407467730137191843385 >>> pi/2*hyp2f1(0.5,0.5,1,0.5) 1.85407467730137191843385 Evaluation is supported for arbitrary complex `m`:: >>> ellipk(3+4j) (0.9111955638049650086562171 + 0.6313342832413452438845091j) A definite integral:: >>> quad(ellipk, [0, 1]) 2.0 """ agm = r""" ``agm(a, b)`` computes the arithmetic-geometric mean of `a` and `b`, defined as the limit of the following iteration: .. math :: a_0 = a b_0 = b a_{n+1} = \frac{a_n+b_n}{2} b_{n+1} = \sqrt{a_n b_n} This function can be called with a single argument, computing `\mathrm{agm}(a,1) = \mathrm{agm}(1,a)`. **Examples** It is a well-known theorem that the geometric mean of two distinct positive numbers is less than the arithmetic mean. It follows that the arithmetic-geometric mean lies between the two means:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> a = mpf(3) >>> b = mpf(4) >>> sqrt(a*b) 3.46410161513775 >>> agm(a,b) 3.48202767635957 >>> (a+b)/2 3.5 The arithmetic-geometric mean is scale-invariant:: >>> agm(10*e, 10*pi) 29.261085515723 >>> 10*agm(e, pi) 29.261085515723 As an order-of-magnitude estimate, `\mathrm{agm}(1,x) \approx x` for large `x`:: >>> agm(10**10) 643448704.760133 >>> agm(10**50) 1.34814309345871e+48 For tiny `x`, `\mathrm{agm}(1,x) \approx -\pi/(2 \log(x/4))`:: >>> agm('0.01') 0.262166887202249 >>> -pi/2/log('0.0025') 0.262172347753122 The arithmetic-geometric mean can also be computed for complex numbers:: >>> agm(3, 2+j) (2.51055133276184 + 0.547394054060638j) The AGM iteration converges very quickly (each step doubles the number of correct digits), so :func:`~mpmath.agm` supports efficient high-precision evaluation:: >>> mp.dps = 10000 >>> a = agm(1,2) >>> str(a)[-10:] '1679581912' **Mathematical relations** The arithmetic-geometric mean may be used to evaluate the following two parametric definite integrals: .. math :: I_1 = \int_0^{\infty} \frac{1}{\sqrt{(x^2+a^2)(x^2+b^2)}} \,dx I_2 = \int_0^{\pi/2} \frac{1}{\sqrt{a^2 \cos^2(x) + b^2 \sin^2(x)}} \,dx We have:: >>> mp.dps = 15 >>> a = 3 >>> b = 4 >>> f1 = lambda x: ((x**2+a**2)*(x**2+b**2))**-0.5 >>> f2 = lambda x: ((a*cos(x))**2 + (b*sin(x))**2)**-0.5 >>> quad(f1, [0, inf]) 0.451115405388492 >>> quad(f2, [0, pi/2]) 0.451115405388492 >>> pi/(2*agm(a,b)) 0.451115405388492 A formula for `\Gamma(1/4)`:: >>> gamma(0.25) 3.62560990822191 >>> sqrt(2*sqrt(2*pi**3)/agm(1,sqrt(2))) 3.62560990822191 **Possible issues** The branch cut chosen for complex `a` and `b` is somewhat arbitrary. """ gegenbauer = r""" Evaluates the Gegenbauer polynomial, or ultraspherical polynomial, .. math :: C_n^{(a)}(z) = {n+2a-1 \choose n} \,_2F_1\left(-n, n+2a; a+\frac{1}{2}; \frac{1}{2}(1-z)\right). When `n` is a nonnegative integer, this formula gives a polynomial in `z` of degree `n`, but all parameters are permitted to be complex numbers. With `a = 1/2`, the Gegenbauer polynomial reduces to a Legendre polynomial. **Examples** Evaluation for arbitrary arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> gegenbauer(3, 0.5, -10) -2485.0 >>> gegenbauer(1000, 10, 100) 3.012757178975667428359374e+2322 >>> gegenbauer(2+3j, -0.75, -1000j) (-5038991.358609026523401901 + 9414549.285447104177860806j) Evaluation at negative integer orders:: >>> gegenbauer(-4, 2, 1.75) -1.0 >>> gegenbauer(-4, 3, 1.75) 0.0 >>> gegenbauer(-4, 2j, 1.75) 0.0 >>> gegenbauer(-7, 0.5, 3) 8989.0 The Gegenbauer polynomials solve the differential equation:: >>> n, a = 4.5, 1+2j >>> f = lambda z: gegenbauer(n, a, z) >>> for z in [0, 0.75, -0.5j]: ... chop((1-z**2)*diff(f,z,2) - (2*a+1)*z*diff(f,z) + n*(n+2*a)*f(z)) ... 0.0 0.0 0.0 The Gegenbauer polynomials have generating function `(1-2zt+t^2)^{-a}`:: >>> a, z = 2.5, 1 >>> taylor(lambda t: (1-2*z*t+t**2)**(-a), 0, 3) [1.0, 5.0, 15.0, 35.0] >>> [gegenbauer(n,a,z) for n in range(4)] [1.0, 5.0, 15.0, 35.0] The Gegenbauer polynomials are orthogonal on `[-1, 1]` with respect to the weight `(1-z^2)^{a-\frac{1}{2}}`:: >>> a, n, m = 2.5, 4, 5 >>> Cn = lambda z: gegenbauer(n, a, z, zeroprec=1000) >>> Cm = lambda z: gegenbauer(m, a, z, zeroprec=1000) >>> chop(quad(lambda z: Cn(z)*Cm(z)*(1-z**2)*(a-0.5), [-1, 1])) 0.0 """ laguerre = r""" Gives the generalized (associated) Laguerre polynomial, defined by .. math :: L_n^a(z) = \frac{\Gamma(n+b+1)}{\Gamma(b+1) \Gamma(n+1)} \,_1F_1(-n, a+1, z). With `a = 0` and `n` a nonnegative integer, this reduces to an ordinary Laguerre polynomial, the sequence of which begins `L_0(z) = 1, L_1(z) = 1-z, L_2(z) = z^2-2z+1, \ldots`. The Laguerre polynomials are orthogonal with respect to the weight `z^a e^{-z}` on `[0, \infty)`. **Plots** .. literalinclude :: /plots/laguerre.py .. image :: /plots/laguerre.png **Examples** Evaluation for arbitrary arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> laguerre(5, 0, 0.25) 0.03726399739583333333333333 >>> laguerre(1+j, 0.5, 2+3j) (4.474921610704496808379097 - 11.02058050372068958069241j) >>> laguerre(2, 0, 10000) 49980001.0 >>> laguerre(2.5, 0, 10000) -9.327764910194842158583189e+4328 The first few Laguerre polynomials, normalized to have integer coefficients:: >>> for n in range(7): ... chop(taylor(lambda z: fac(n)*laguerre(n, 0, z), 0, n)) ... [1.0] [1.0, -1.0] [2.0, -4.0, 1.0] [6.0, -18.0, 9.0, -1.0] [24.0, -96.0, 72.0, -16.0, 1.0] [120.0, -600.0, 600.0, -200.0, 25.0, -1.0] [720.0, -4320.0, 5400.0, -2400.0, 450.0, -36.0, 1.0] Verifying orthogonality:: >>> Lm = lambda t: laguerre(m,a,t) >>> Ln = lambda t: laguerre(n,a,t) >>> a, n, m = 2.5, 2, 3 >>> chop(quad(lambda t: exp(-t)*t**a*Lm(t)*Ln(t), [0,inf])) 0.0 """ hermite = r""" Evaluates the Hermite polynomial `H_n(z)`, which may be defined using the recurrence .. math :: H_0(z) = 1 H_1(z) = 2z H_{n+1} = 2z H_n(z) - 2n H_{n-1}(z). The Hermite polynomials are orthogonal on `(-\infty, \infty)` with respect to the weight `e^{-z^2}`. More generally, allowing arbitrary complex values of `n`, the Hermite function `H_n(z)` is defined as .. math :: H_n(z) = (2z)^n \,_2F_0\left(-\frac{n}{2}, \frac{1-n}{2}, -\frac{1}{z^2}\right) for `\Re{z} > 0`, or generally .. math :: H_n(z) = 2^n \sqrt{\pi} \left( \frac{1}{\Gamma\left(\frac{1-n}{2}\right)} \,_1F_1\left(-\frac{n}{2}, \frac{1}{2}, z^2\right) - \frac{2z}{\Gamma\left(-\frac{n}{2}\right)} \,_1F_1\left(\frac{1-n}{2}, \frac{3}{2}, z^2\right) \right). **Plots** .. literalinclude :: /plots/hermite.py .. image :: /plots/hermite.png **Examples** Evaluation for arbitrary arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hermite(0, 10) 1.0 >>> hermite(1, 10); hermite(2, 10) 20.0 398.0 >>> hermite(10000, 2) 4.950440066552087387515653e+19334 >>> hermite(3, -10**8) -7999999999999998800000000.0 >>> hermite(-3, -10**8) 1.675159751729877682920301e+4342944819032534 >>> hermite(2+3j, -1+2j) (-0.07652130602993513389421901 - 0.1084662449961914580276007j) Coefficients of the first few Hermite polynomials are:: >>> for n in range(7): ... chop(taylor(lambda z: hermite(n, z), 0, n)) ... [1.0] [0.0, 2.0] [-2.0, 0.0, 4.0] [0.0, -12.0, 0.0, 8.0] [12.0, 0.0, -48.0, 0.0, 16.0] [0.0, 120.0, 0.0, -160.0, 0.0, 32.0] [-120.0, 0.0, 720.0, 0.0, -480.0, 0.0, 64.0] Values at `z = 0`:: >>> for n in range(-5, 9): ... hermite(n, 0) ... 0.02769459142039868792653387 0.08333333333333333333333333 0.2215567313631895034122709 0.5 0.8862269254527580136490837 1.0 0.0 -2.0 0.0 12.0 0.0 -120.0 0.0 1680.0 Hermite functions satisfy the differential equation:: >>> n = 4 >>> f = lambda z: hermite(n, z) >>> z = 1.5 >>> chop(diff(f,z,2) - 2*z*diff(f,z) + 2*n*f(z)) 0.0 Verifying orthogonality:: >>> chop(quad(lambda t: hermite(2,t)*hermite(4,t)*exp(-t**2), [-inf,inf])) 0.0 """ jacobi = r""" ``jacobi(n, a, b, x)`` evaluates the Jacobi polynomial `P_n^{(a,b)}(x)`. The Jacobi polynomials are a special case of the hypergeometric function `\,_2F_1` given by: .. math :: P_n^{(a,b)}(x) = {n+a \choose n} \,_2F_1\left(-n,1+a+b+n,a+1,\frac{1-x}{2}\right). Note that this definition generalizes to nonintegral values of `n`. When `n` is an integer, the hypergeometric series terminates after a finite number of terms, giving a polynomial in `x`. **Evaluation of Jacobi polynomials** A special evaluation is `P_n^{(a,b)}(1) = {n+a \choose n}`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> jacobi(4, 0.5, 0.25, 1) 2.4609375 >>> binomial(4+0.5, 4) 2.4609375 A Jacobi polynomial of degree `n` is equal to its Taylor polynomial of degree `n`. The explicit coefficients of Jacobi polynomials can therefore be recovered easily using :func:`~mpmath.taylor`:: >>> for n in range(5): ... nprint(taylor(lambda x: jacobi(n,1,2,x), 0, n)) ... [1.0] [-0.5, 2.5] [-0.75, -1.5, 5.25] [0.5, -3.5, -3.5, 10.5] [0.625, 2.5, -11.25, -7.5, 20.625] For nonintegral `n`, the Jacobi "polynomial" is no longer a polynomial:: >>> nprint(taylor(lambda x: jacobi(0.5,1,2,x), 0, 4)) [0.309983, 1.84119, -1.26933, 1.26699, -1.34808] **Orthogonality** The Jacobi polynomials are orthogonal on the interval `[-1, 1]` with respect to the weight function `w(x) = (1-x)^a (1+x)^b`. That is, `w(x) P_n^{(a,b)}(x) P_m^{(a,b)}(x)` integrates to zero if `m \ne n` and to a nonzero number if `m = n`. The orthogonality is easy to verify using numerical quadrature:: >>> P = jacobi >>> f = lambda x: (1-x)**a * (1+x)**b * P(m,a,b,x) * P(n,a,b,x) >>> a = 2 >>> b = 3 >>> m, n = 3, 4 >>> chop(quad(f, [-1, 1]), 1) 0.0 >>> m, n = 4, 4 >>> quad(f, [-1, 1]) 1.9047619047619 **Differential equation** The Jacobi polynomials are solutions of the differential equation .. math :: (1-x^2) y'' + (b-a-(a+b+2)x) y' + n (n+a+b+1) y = 0. We can verify that :func:`~mpmath.jacobi` approximately satisfies this equation:: >>> from mpmath import * >>> mp.dps = 15 >>> a = 2.5 >>> b = 4 >>> n = 3 >>> y = lambda x: jacobi(n,a,b,x) >>> x = pi >>> A0 = n*(n+a+b+1)*y(x) >>> A1 = (b-a-(a+b+2)*x)*diff(y,x) >>> A2 = (1-x**2)*diff(y,x,2) >>> nprint(A2 + A1 + A0, 1) 4.0e-12 The difference of order `10^{-12}` is as close to zero as it could be at 15-digit working precision, since the terms are large:: >>> A0, A1, A2 (26560.2328981879, -21503.7641037294, -5056.46879445852) """ legendre = r""" ``legendre(n, x)`` evaluates the Legendre polynomial `P_n(x)`. The Legendre polynomials are given by the formula .. math :: P_n(x) = \frac{1}{2^n n!} \frac{d^n}{dx^n} (x^2 -1)^n. Alternatively, they can be computed recursively using .. math :: P_0(x) = 1 P_1(x) = x (n+1) P_{n+1}(x) = (2n+1) x P_n(x) - n P_{n-1}(x). A third definition is in terms of the hypergeometric function `\,_2F_1`, whereby they can be generalized to arbitrary `n`: .. math :: P_n(x) = \,_2F_1\left(-n, n+1, 1, \frac{1-x}{2}\right) **Plots** .. literalinclude :: /plots/legendre.py .. image :: /plots/legendre.png **Basic evaluation** The Legendre polynomials assume fixed values at the points `x = -1` and `x = 1`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> nprint([legendre(n, 1) for n in range(6)]) [1.0, 1.0, 1.0, 1.0, 1.0, 1.0] >>> nprint([legendre(n, -1) for n in range(6)]) [1.0, -1.0, 1.0, -1.0, 1.0, -1.0] The coefficients of Legendre polynomials can be recovered using degree-`n` Taylor expansion:: >>> for n in range(5): ... nprint(chop(taylor(lambda x: legendre(n, x), 0, n))) ... [1.0] [0.0, 1.0] [-0.5, 0.0, 1.5] [0.0, -1.5, 0.0, 2.5] [0.375, 0.0, -3.75, 0.0, 4.375] The roots of Legendre polynomials are located symmetrically on the interval `[-1, 1]`:: >>> for n in range(5): ... nprint(polyroots(taylor(lambda x: legendre(n, x), 0, n)[::-1])) ... [] [0.0] [-0.57735, 0.57735] [-0.774597, 0.0, 0.774597] [-0.861136, -0.339981, 0.339981, 0.861136] An example of an evaluation for arbitrary `n`:: >>> legendre(0.75, 2+4j) (1.94952805264875 + 2.1071073099422j) **Orthogonality** The Legendre polynomials are orthogonal on `[-1, 1]` with respect to the trivial weight `w(x) = 1`. That is, `P_m(x) P_n(x)` integrates to zero if `m \ne n` and to `2/(2n+1)` if `m = n`:: >>> m, n = 3, 4 >>> quad(lambda x: legendre(m,x)*legendre(n,x), [-1, 1]) 0.0 >>> m, n = 4, 4 >>> quad(lambda x: legendre(m,x)*legendre(n,x), [-1, 1]) 0.222222222222222 **Differential equation** The Legendre polynomials satisfy the differential equation .. math :: ((1-x^2) y')' + n(n+1) y' = 0. We can verify this numerically:: >>> n = 3.6 >>> x = 0.73 >>> P = legendre >>> A = diff(lambda t: (1-t**2)*diff(lambda u: P(n,u), t), x) >>> B = n*(n+1)*P(n,x) >>> nprint(A+B,1) 9.0e-16 """ legenp = r""" Calculates the (associated) Legendre function of the first kind of degree *n* and order *m*, `P_n^m(z)`. Taking `m = 0` gives the ordinary Legendre function of the first kind, `P_n(z)`. The parameters may be complex numbers. In terms of the Gauss hypergeometric function, the (associated) Legendre function is defined as .. math :: P_n^m(z) = \frac{1}{\Gamma(1-m)} \frac{(1+z)^{m/2}}{(1-z)^{m/2}} \,_2F_1\left(-n, n+1, 1-m, \frac{1-z}{2}\right). With *type=3* instead of *type=2*, the alternative definition .. math :: \hat{P}_n^m(z) = \frac{1}{\Gamma(1-m)} \frac{(z+1)^{m/2}}{(z-1)^{m/2}} \,_2F_1\left(-n, n+1, 1-m, \frac{1-z}{2}\right). is used. These functions correspond respectively to ``LegendreP[n,m,2,z]`` and ``LegendreP[n,m,3,z]`` in Mathematica. The general solution of the (associated) Legendre differential equation .. math :: (1-z^2) f''(z) - 2zf'(z) + \left(n(n+1)-\frac{m^2}{1-z^2}\right)f(z) = 0 is given by `C_1 P_n^m(z) + C_2 Q_n^m(z)` for arbitrary constants `C_1`, `C_2`, where `Q_n^m(z)` is a Legendre function of the second kind as implemented by :func:`~mpmath.legenq`. **Examples** Evaluation for arbitrary parameters and arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> legenp(2, 0, 10); legendre(2, 10) 149.5 149.5 >>> legenp(-2, 0.5, 2.5) (1.972260393822275434196053 - 1.972260393822275434196053j) >>> legenp(2+3j, 1-j, -0.5+4j) (-3.335677248386698208736542 - 5.663270217461022307645625j) >>> chop(legenp(3, 2, -1.5, type=2)) 28.125 >>> chop(legenp(3, 2, -1.5, type=3)) -28.125 Verifying the associated Legendre differential equation:: >>> n, m = 2, -0.5 >>> C1, C2 = 1, -3 >>> f = lambda z: C1*legenp(n,m,z) + C2*legenq(n,m,z) >>> deq = lambda z: (1-z**2)*diff(f,z,2) - 2*z*diff(f,z) + \ ... (n*(n+1)-m**2/(1-z**2))*f(z) >>> for z in [0, 2, -1.5, 0.5+2j]: ... chop(deq(mpmathify(z))) ... 0.0 0.0 0.0 0.0 """ legenq = r""" Calculates the (associated) Legendre function of the second kind of degree *n* and order *m*, `Q_n^m(z)`. Taking `m = 0` gives the ordinary Legendre function of the second kind, `Q_n(z)`. The parameters may be complex numbers. The Legendre functions of the second kind give a second set of solutions to the (associated) Legendre differential equation. (See :func:`~mpmath.legenp`.) Unlike the Legendre functions of the first kind, they are not polynomials of `z` for integer `n`, `m` but rational or logarithmic functions with poles at `z = \pm 1`. There are various ways to define Legendre functions of the second kind, giving rise to different complex structure. A version can be selected using the *type* keyword argument. The *type=2* and *type=3* functions are given respectively by .. math :: Q_n^m(z) = \frac{\pi}{2 \sin(\pi m)} \left( \cos(\pi m) P_n^m(z) - \frac{\Gamma(1+m+n)}{\Gamma(1-m+n)} P_n^{-m}(z)\right) \hat{Q}_n^m(z) = \frac{\pi}{2 \sin(\pi m)} e^{\pi i m} \left( \hat{P}_n^m(z) - \frac{\Gamma(1+m+n)}{\Gamma(1-m+n)} \hat{P}_n^{-m}(z)\right) where `P` and `\hat{P}` are the *type=2* and *type=3* Legendre functions of the first kind. The formulas above should be understood as limits when `m` is an integer. These functions correspond to ``LegendreQ[n,m,2,z]`` (or ``LegendreQ[n,m,z]``) and ``LegendreQ[n,m,3,z]`` in Mathematica. The *type=3* function is essentially the same as the function defined in Abramowitz & Stegun (eq. 8.1.3) but with `(z+1)^{m/2}(z-1)^{m/2}` instead of `(z^2-1)^{m/2}`, giving slightly different branches. **Examples** Evaluation for arbitrary parameters and arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> legenq(2, 0, 0.5) -0.8186632680417568557122028 >>> legenq(-1.5, -2, 2.5) (0.6655964618250228714288277 + 0.3937692045497259717762649j) >>> legenq(2-j, 3+4j, -6+5j) (-10001.95256487468541686564 - 6011.691337610097577791134j) Different versions of the function:: >>> legenq(2, 1, 0.5) 0.7298060598018049369381857 >>> legenq(2, 1, 1.5) (-7.902916572420817192300921 + 0.1998650072605976600724502j) >>> legenq(2, 1, 0.5, type=3) (2.040524284763495081918338 - 0.7298060598018049369381857j) >>> chop(legenq(2, 1, 1.5, type=3)) -0.1998650072605976600724502 """ chebyt = r""" ``chebyt(n, x)`` evaluates the Chebyshev polynomial of the first kind `T_n(x)`, defined by the identity .. math :: T_n(\cos x) = \cos(n x). The Chebyshev polynomials of the first kind are a special case of the Jacobi polynomials, and by extension of the hypergeometric function `\,_2F_1`. They can thus also be evaluated for nonintegral `n`. **Plots** .. literalinclude :: /plots/chebyt.py .. image :: /plots/chebyt.png **Basic evaluation** The coefficients of the `n`-th polynomial can be recovered using using degree-`n` Taylor expansion:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(5): ... nprint(chop(taylor(lambda x: chebyt(n, x), 0, n))) ... [1.0] [0.0, 1.0] [-1.0, 0.0, 2.0] [0.0, -3.0, 0.0, 4.0] [1.0, 0.0, -8.0, 0.0, 8.0] **Orthogonality** The Chebyshev polynomials of the first kind are orthogonal on the interval `[-1, 1]` with respect to the weight function `w(x) = 1/\sqrt{1-x^2}`:: >>> f = lambda x: chebyt(m,x)*chebyt(n,x)/sqrt(1-x**2) >>> m, n = 3, 4 >>> nprint(quad(f, [-1, 1]),1) 0.0 >>> m, n = 4, 4 >>> quad(f, [-1, 1]) 1.57079632596448 """ chebyu = r""" ``chebyu(n, x)`` evaluates the Chebyshev polynomial of the second kind `U_n(x)`, defined by the identity .. math :: U_n(\cos x) = \frac{\sin((n+1)x)}{\sin(x)}. The Chebyshev polynomials of the second kind are a special case of the Jacobi polynomials, and by extension of the hypergeometric function `\,_2F_1`. They can thus also be evaluated for nonintegral `n`. **Plots** .. literalinclude :: /plots/chebyu.py .. image :: /plots/chebyu.png **Basic evaluation** The coefficients of the `n`-th polynomial can be recovered using using degree-`n` Taylor expansion:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(5): ... nprint(chop(taylor(lambda x: chebyu(n, x), 0, n))) ... [1.0] [0.0, 2.0] [-1.0, 0.0, 4.0] [0.0, -4.0, 0.0, 8.0] [1.0, 0.0, -12.0, 0.0, 16.0] **Orthogonality** The Chebyshev polynomials of the second kind are orthogonal on the interval `[-1, 1]` with respect to the weight function `w(x) = \sqrt{1-x^2}`:: >>> f = lambda x: chebyu(m,x)*chebyu(n,x)*sqrt(1-x**2) >>> m, n = 3, 4 >>> quad(f, [-1, 1]) 0.0 >>> m, n = 4, 4 >>> quad(f, [-1, 1]) 1.5707963267949 """ besselj = r""" ``besselj(n, x, derivative=0)`` gives the Bessel function of the first kind `J_n(x)`. Bessel functions of the first kind are defined as solutions of the differential equation .. math :: x^2 y'' + x y' + (x^2 - n^2) y = 0 which appears, among other things, when solving the radial part of Laplace's equation in cylindrical coordinates. This equation has two solutions for given `n`, where the `J_n`-function is the solution that is nonsingular at `x = 0`. For positive integer `n`, `J_n(x)` behaves roughly like a sine (odd `n`) or cosine (even `n`) multiplied by a magnitude factor that decays slowly as `x \to \pm\infty`. Generally, `J_n` is a special case of the hypergeometric function `\,_0F_1`: .. math :: J_n(x) = \frac{x^n}{2^n \Gamma(n+1)} \,_0F_1\left(n+1,-\frac{x^2}{4}\right) With *derivative* = `m \ne 0`, the `m`-th derivative .. math :: \frac{d^m}{dx^m} J_n(x) is computed. **Plots** .. literalinclude :: /plots/besselj.py .. image :: /plots/besselj.png .. literalinclude :: /plots/besselj_c.py .. image :: /plots/besselj_c.png **Examples** Evaluation is supported for arbitrary arguments, and at arbitrary precision:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> besselj(2, 1000) -0.024777229528606 >>> besselj(4, 0.75) 0.000801070086542314 >>> besselj(2, 1000j) (-2.48071721019185e+432 + 6.41567059811949e-437j) >>> mp.dps = 25 >>> besselj(0.75j, 3+4j) (-2.778118364828153309919653 - 1.5863603889018621585533j) >>> mp.dps = 50 >>> besselj(1, pi) 0.28461534317975275734531059968613140570981118184947 Arguments may be large:: >>> mp.dps = 25 >>> besselj(0, 10000) -0.007096160353388801477265164 >>> besselj(0, 10**10) 0.000002175591750246891726859055 >>> besselj(2, 10**100) 7.337048736538615712436929e-51 >>> besselj(2, 10**5*j) (-3.540725411970948860173735e+43426 + 4.4949812409615803110051e-43433j) The Bessel functions of the first kind satisfy simple symmetries around `x = 0`:: >>> mp.dps = 15 >>> nprint([besselj(n,0) for n in range(5)]) [1.0, 0.0, 0.0, 0.0, 0.0] >>> nprint([besselj(n,pi) for n in range(5)]) [-0.304242, 0.284615, 0.485434, 0.333458, 0.151425] >>> nprint([besselj(n,-pi) for n in range(5)]) [-0.304242, -0.284615, 0.485434, -0.333458, 0.151425] Roots of Bessel functions are often used:: >>> nprint([findroot(j0, k) for k in [2, 5, 8, 11, 14]]) [2.40483, 5.52008, 8.65373, 11.7915, 14.9309] >>> nprint([findroot(j1, k) for k in [3, 7, 10, 13, 16]]) [3.83171, 7.01559, 10.1735, 13.3237, 16.4706] The roots are not periodic, but the distance between successive roots asymptotically approaches `2 \pi`. Bessel functions of the first kind have the following normalization:: >>> quadosc(j0, [0, inf], period=2*pi) 1.0 >>> quadosc(j1, [0, inf], period=2*pi) 1.0 For `n = 1/2` or `n = -1/2`, the Bessel function reduces to a trigonometric function:: >>> x = 10 >>> besselj(0.5, x), sqrt(2/(pi*x))*sin(x) (-0.13726373575505, -0.13726373575505) >>> besselj(-0.5, x), sqrt(2/(pi*x))*cos(x) (-0.211708866331398, -0.211708866331398) Derivatives of any order can be computed (negative orders correspond to integration):: >>> mp.dps = 25 >>> besselj(0, 7.5, 1) -0.1352484275797055051822405 >>> diff(lambda x: besselj(0,x), 7.5) -0.1352484275797055051822405 >>> besselj(0, 7.5, 10) -0.1377811164763244890135677 >>> diff(lambda x: besselj(0,x), 7.5, 10) -0.1377811164763244890135677 >>> besselj(0,7.5,-1) - besselj(0,3.5,-1) -0.1241343240399987693521378 >>> quad(j0, [3.5, 7.5]) -0.1241343240399987693521378 Differentiation with a noninteger order gives the fractional derivative in the sense of the Riemann-Liouville differintegral, as computed by :func:`~mpmath.differint`:: >>> mp.dps = 15 >>> besselj(1, 3.5, 0.75) -0.385977722939384 >>> differint(lambda x: besselj(1, x), 3.5, 0.75) -0.385977722939384 """ besseli = r""" ``besseli(n, x, derivative=0)`` gives the modified Bessel function of the first kind, .. math :: I_n(x) = i^{-n} J_n(ix). With *derivative* = `m \ne 0`, the `m`-th derivative .. math :: \frac{d^m}{dx^m} I_n(x) is computed. **Plots** .. literalinclude :: /plots/besseli.py .. image :: /plots/besseli.png .. literalinclude :: /plots/besseli_c.py .. image :: /plots/besseli_c.png **Examples** Some values of `I_n(x)`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> besseli(0,0) 1.0 >>> besseli(1,0) 0.0 >>> besseli(0,1) 1.266065877752008335598245 >>> besseli(3.5, 2+3j) (-0.2904369752642538144289025 - 0.4469098397654815837307006j) Arguments may be large:: >>> besseli(2, 1000) 2.480717210191852440616782e+432 >>> besseli(2, 10**10) 4.299602851624027900335391e+4342944813 >>> besseli(2, 6000+10000j) (-2.114650753239580827144204e+2603 + 4.385040221241629041351886e+2602j) For integers `n`, the following integral representation holds:: >>> mp.dps = 15 >>> n = 3 >>> x = 2.3 >>> quad(lambda t: exp(x*cos(t))*cos(n*t), [0,pi])/pi 0.349223221159309 >>> besseli(n,x) 0.349223221159309 Derivatives and antiderivatives of any order can be computed:: >>> mp.dps = 25 >>> besseli(2, 7.5, 1) 195.8229038931399062565883 >>> diff(lambda x: besseli(2,x), 7.5) 195.8229038931399062565883 >>> besseli(2, 7.5, 10) 153.3296508971734525525176 >>> diff(lambda x: besseli(2,x), 7.5, 10) 153.3296508971734525525176 >>> besseli(2,7.5,-1) - besseli(2,3.5,-1) 202.5043900051930141956876 >>> quad(lambda x: besseli(2,x), [3.5, 7.5]) 202.5043900051930141956876 """ bessely = r""" ``bessely(n, x, derivative=0)`` gives the Bessel function of the second kind, .. math :: Y_n(x) = \frac{J_n(x) \cos(\pi n) - J_{-n}(x)}{\sin(\pi n)}. For `n` an integer, this formula should be understood as a limit. With *derivative* = `m \ne 0`, the `m`-th derivative .. math :: \frac{d^m}{dx^m} Y_n(x) is computed. **Plots** .. literalinclude :: /plots/bessely.py .. image :: /plots/bessely.png .. literalinclude :: /plots/bessely_c.py .. image :: /plots/bessely_c.png **Examples** Some values of `Y_n(x)`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> bessely(0,0), bessely(1,0), bessely(2,0) (-inf, -inf, -inf) >>> bessely(1, pi) 0.3588729167767189594679827 >>> bessely(0.5, 3+4j) (9.242861436961450520325216 - 3.085042824915332562522402j) Arguments may be large:: >>> bessely(0, 10000) 0.00364780555898660588668872 >>> bessely(2.5, 10**50) -4.8952500412050989295774e-26 >>> bessely(2.5, -10**50) (0.0 + 4.8952500412050989295774e-26j) Derivatives and antiderivatives of any order can be computed:: >>> bessely(2, 3.5, 1) 0.3842618820422660066089231 >>> diff(lambda x: bessely(2, x), 3.5) 0.3842618820422660066089231 >>> bessely(0.5, 3.5, 1) -0.2066598304156764337900417 >>> diff(lambda x: bessely(0.5, x), 3.5) -0.2066598304156764337900417 >>> diff(lambda x: bessely(2, x), 0.5, 10) -208173867409.5547350101511 >>> bessely(2, 0.5, 10) -208173867409.5547350101511 >>> bessely(2, 100.5, 100) 0.02668487547301372334849043 >>> quad(lambda x: bessely(2,x), [1,3]) -1.377046859093181969213262 >>> bessely(2,3,-1) - bessely(2,1,-1) -1.377046859093181969213262 """ besselk = r""" ``besselk(n, x)`` gives the modified Bessel function of the second kind, .. math :: K_n(x) = \frac{\pi}{2} \frac{I_{-n}(x)-I_{n}(x)}{\sin(\pi n)} For `n` an integer, this formula should be understood as a limit. **Plots** .. literalinclude :: /plots/besselk.py .. image :: /plots/besselk.png .. literalinclude :: /plots/besselk_c.py .. image :: /plots/besselk_c.png **Examples** Evaluation is supported for arbitrary complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> besselk(0,1) 0.4210244382407083333356274 >>> besselk(0, -1) (0.4210244382407083333356274 - 3.97746326050642263725661j) >>> besselk(3.5, 2+3j) (-0.02090732889633760668464128 + 0.2464022641351420167819697j) >>> besselk(2+3j, 0.5) (0.9615816021726349402626083 + 0.1918250181801757416908224j) Arguments may be large:: >>> besselk(0, 100) 4.656628229175902018939005e-45 >>> besselk(1, 10**6) 4.131967049321725588398296e-434298 >>> besselk(1, 10**6*j) (0.001140348428252385844876706 - 0.0005200017201681152909000961j) >>> besselk(4.5, fmul(10**50, j, exact=True)) (1.561034538142413947789221e-26 + 1.243554598118700063281496e-25j) The point `x = 0` is a singularity (logarithmic if `n = 0`):: >>> besselk(0,0) +inf >>> besselk(1,0) +inf >>> for n in range(-4, 5): ... print(besselk(n, '1e-1000')) ... 4.8e+4001 8.0e+3000 2.0e+2000 1.0e+1000 2302.701024509704096466802 1.0e+1000 2.0e+2000 8.0e+3000 4.8e+4001 """ hankel1 = r""" ``hankel1(n,x)`` computes the Hankel function of the first kind, which is the complex combination of Bessel functions given by .. math :: H_n^{(1)}(x) = J_n(x) + i Y_n(x). **Plots** .. literalinclude :: /plots/hankel1.py .. image :: /plots/hankel1.png .. literalinclude :: /plots/hankel1_c.py .. image :: /plots/hankel1_c.png **Examples** The Hankel function is generally complex-valued:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hankel1(2, pi) (0.4854339326315091097054957 - 0.0999007139290278787734903j) >>> hankel1(3.5, pi) (0.2340002029630507922628888 - 0.6419643823412927142424049j) """ hankel2 = r""" ``hankel2(n,x)`` computes the Hankel function of the second kind, which is the complex combination of Bessel functions given by .. math :: H_n^{(2)}(x) = J_n(x) - i Y_n(x). **Plots** .. literalinclude :: /plots/hankel2.py .. image :: /plots/hankel2.png .. literalinclude :: /plots/hankel2_c.py .. image :: /plots/hankel2_c.png **Examples** The Hankel function is generally complex-valued:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> hankel2(2, pi) (0.4854339326315091097054957 + 0.0999007139290278787734903j) >>> hankel2(3.5, pi) (0.2340002029630507922628888 + 0.6419643823412927142424049j) """ lambertw = r""" The Lambert W function `W(z)` is defined as the inverse function of `w \exp(w)`. In other words, the value of `W(z)` is such that `z = W(z) \exp(W(z))` for any complex number `z`. The Lambert W function is a multivalued function with infinitely many branches `W_k(z)`, indexed by `k \in \mathbb{Z}`. Each branch gives a different solution `w` of the equation `z = w \exp(w)`. All branches are supported by :func:`~mpmath.lambertw`: * ``lambertw(z)`` gives the principal solution (branch 0) * ``lambertw(z, k)`` gives the solution on branch `k` The Lambert W function has two partially real branches: the principal branch (`k = 0`) is real for real `z > -1/e`, and the `k = -1` branch is real for `-1/e < z < 0`. All branches except `k = 0` have a logarithmic singularity at `z = 0`. The definition, implementation and choice of branches is based on [Corless]_. **Plots** .. literalinclude :: /plots/lambertw.py .. image :: /plots/lambertw.png .. literalinclude :: /plots/lambertw_c.py .. image :: /plots/lambertw_c.png **Basic examples** The Lambert W function is the inverse of `w \exp(w)`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> w = lambertw(1) >>> w 0.5671432904097838729999687 >>> w*exp(w) 1.0 Any branch gives a valid inverse:: >>> w = lambertw(1, k=3) >>> w (-2.853581755409037807206819 + 17.11353553941214591260783j) >>> w = lambertw(1, k=25) >>> w (-5.047020464221569709378686 + 155.4763860949415867162066j) >>> chop(w*exp(w)) 1.0 **Applications to equation-solving** The Lambert W function may be used to solve various kinds of equations, such as finding the value of the infinite power tower `z^{z^{z^{\ldots}}}`:: >>> def tower(z, n): ... if n == 0: ... return z ... return z ** tower(z, n-1) ... >>> tower(mpf(0.5), 100) 0.6411857445049859844862005 >>> -lambertw(-log(0.5))/log(0.5) 0.6411857445049859844862005 **Properties** The Lambert W function grows roughly like the natural logarithm for large arguments:: >>> lambertw(1000); log(1000) 5.249602852401596227126056 6.907755278982137052053974 >>> lambertw(10**100); log(10**100) 224.8431064451185015393731 230.2585092994045684017991 The principal branch of the Lambert W function has a rational Taylor series expansion around `z = 0`:: >>> nprint(taylor(lambertw, 0, 6), 10) [0.0, 1.0, -1.0, 1.5, -2.666666667, 5.208333333, -10.8] Some special values and limits are:: >>> lambertw(0) 0.0 >>> lambertw(1) 0.5671432904097838729999687 >>> lambertw(e) 1.0 >>> lambertw(inf) +inf >>> lambertw(0, k=-1) -inf >>> lambertw(0, k=3) -inf >>> lambertw(inf, k=2) (+inf + 12.56637061435917295385057j) >>> lambertw(inf, k=3) (+inf + 18.84955592153875943077586j) >>> lambertw(-inf, k=3) (+inf + 21.9911485751285526692385j) The `k = 0` and `k = -1` branches join at `z = -1/e` where `W(z) = -1` for both branches. Since `-1/e` can only be represented approximately with binary floating-point numbers, evaluating the Lambert W function at this point only gives `-1` approximately:: >>> lambertw(-1/e, 0) -0.9999999999998371330228251 >>> lambertw(-1/e, -1) -1.000000000000162866977175 If `-1/e` happens to round in the negative direction, there might be a small imaginary part:: >>> mp.dps = 15 >>> lambertw(-1/e) (-1.0 + 8.22007971483662e-9j) >>> lambertw(-1/e+eps) -0.999999966242188 **References** 1. [Corless]_ """ barnesg = r""" Evaluates the Barnes G-function, which generalizes the superfactorial (:func:`~mpmath.superfac`) and by extension also the hyperfactorial (:func:`~mpmath.hyperfac`) to the complex numbers in an analogous way to how the gamma function generalizes the ordinary factorial. The Barnes G-function may be defined in terms of a Weierstrass product: .. math :: G(z+1) = (2\pi)^{z/2} e^{-[z(z+1)+\gamma z^2]/2} \prod_{n=1}^\infty \left[\left(1+\frac{z}{n}\right)^ne^{-z+z^2/(2n)}\right] For positive integers `n`, we have have relation to superfactorials `G(n) = \mathrm{sf}(n-2) = 0! \cdot 1! \cdots (n-2)!`. **Examples** Some elementary values and limits of the Barnes G-function:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> barnesg(1), barnesg(2), barnesg(3) (1.0, 1.0, 1.0) >>> barnesg(4) 2.0 >>> barnesg(5) 12.0 >>> barnesg(6) 288.0 >>> barnesg(7) 34560.0 >>> barnesg(8) 24883200.0 >>> barnesg(inf) +inf >>> barnesg(0), barnesg(-1), barnesg(-2) (0.0, 0.0, 0.0) Closed-form values are known for some rational arguments:: >>> barnesg('1/2') 0.603244281209446 >>> sqrt(exp(0.25+log(2)/12)/sqrt(pi)/glaisher**3) 0.603244281209446 >>> barnesg('1/4') 0.29375596533861 >>> nthroot(exp('3/8')/exp(catalan/pi)/ ... gamma(0.25)**3/sqrt(glaisher)**9, 4) 0.29375596533861 The Barnes G-function satisfies the functional equation `G(z+1) = \Gamma(z) G(z)`:: >>> z = pi >>> barnesg(z+1) 2.39292119327948 >>> gamma(z)*barnesg(z) 2.39292119327948 The asymptotic growth rate of the Barnes G-function is related to the Glaisher-Kinkelin constant:: >>> limit(lambda n: barnesg(n+1)/(n**(n**2/2-mpf(1)/12)* ... (2*pi)**(n/2)*exp(-3*n**2/4)), inf) 0.847536694177301 >>> exp('1/12')/glaisher 0.847536694177301 The Barnes G-function can be differentiated in closed form:: >>> z = 3 >>> diff(barnesg, z) 0.264507203401607 >>> barnesg(z)*((z-1)*psi(0,z)-z+(log(2*pi)+1)/2) 0.264507203401607 Evaluation is supported for arbitrary arguments and at arbitrary precision:: >>> barnesg(6.5) 2548.7457695685 >>> barnesg(-pi) 0.00535976768353037 >>> barnesg(3+4j) (-0.000676375932234244 - 4.42236140124728e-5j) >>> mp.dps = 50 >>> barnesg(1/sqrt(2)) 0.81305501090451340843586085064413533788206204124732 >>> q = barnesg(10j) >>> q.real 0.000000000021852360840356557241543036724799812371995850552234 >>> q.imag -0.00000000000070035335320062304849020654215545839053210041457588 >>> mp.dps = 15 >>> barnesg(100) 3.10361006263698e+6626 >>> barnesg(-101) 0.0 >>> barnesg(-10.5) 5.94463017605008e+25 >>> barnesg(-10000.5) -6.14322868174828e+167480422 >>> barnesg(1000j) (5.21133054865546e-1173597 + 4.27461836811016e-1173597j) >>> barnesg(-1000+1000j) (2.43114569750291e+1026623 + 2.24851410674842e+1026623j) **References** 1. Whittaker & Watson, *A Course of Modern Analysis*, Cambridge University Press, 4th edition (1927), p.264 2. http://en.wikipedia.org/wiki/Barnes_G-function 3. http://mathworld.wolfram.com/BarnesG-Function.html """ superfac = r""" Computes the superfactorial, defined as the product of consecutive factorials .. math :: \mathrm{sf}(n) = \prod_{k=1}^n k! For general complex `z`, `\mathrm{sf}(z)` is defined in terms of the Barnes G-function (see :func:`~mpmath.barnesg`). **Examples** The first few superfactorials are (OEIS A000178):: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(10): ... print("%s %s" % (n, superfac(n))) ... 0 1.0 1 1.0 2 2.0 3 12.0 4 288.0 5 34560.0 6 24883200.0 7 125411328000.0 8 5.05658474496e+15 9 1.83493347225108e+21 Superfactorials grow very rapidly:: >>> superfac(1000) 3.24570818422368e+1177245 >>> superfac(10**10) 2.61398543581249e+467427913956904067453 Evaluation is supported for arbitrary arguments:: >>> mp.dps = 25 >>> superfac(pi) 17.20051550121297985285333 >>> superfac(2+3j) (-0.005915485633199789627466468 + 0.008156449464604044948738263j) >>> diff(superfac, 1) 0.2645072034016070205673056 **References** 1. http://oeis.org/A000178 """ hyperfac = r""" Computes the hyperfactorial, defined for integers as the product .. math :: H(n) = \prod_{k=1}^n k^k. The hyperfactorial satisfies the recurrence formula `H(z) = z^z H(z-1)`. It can be defined more generally in terms of the Barnes G-function (see :func:`~mpmath.barnesg`) and the gamma function by the formula .. math :: H(z) = \frac{\Gamma(z+1)^z}{G(z)}. The extension to complex numbers can also be done via the integral representation .. math :: H(z) = (2\pi)^{-z/2} \exp \left[ {z+1 \choose 2} + \int_0^z \log(t!)\,dt \right]. **Examples** The rapidly-growing sequence of hyperfactorials begins (OEIS A002109):: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(10): ... print("%s %s" % (n, hyperfac(n))) ... 0 1.0 1 1.0 2 4.0 3 108.0 4 27648.0 5 86400000.0 6 4031078400000.0 7 3.3197663987712e+18 8 5.56964379417266e+25 9 2.15779412229419e+34 Some even larger hyperfactorials are:: >>> hyperfac(1000) 5.46458120882585e+1392926 >>> hyperfac(10**10) 4.60408207642219e+489142638002418704309 The hyperfactorial can be evaluated for arbitrary arguments:: >>> hyperfac(0.5) 0.880449235173423 >>> diff(hyperfac, 1) 0.581061466795327 >>> hyperfac(pi) 205.211134637462 >>> hyperfac(-10+1j) (3.01144471378225e+46 - 2.45285242480185e+46j) The recurrence property of the hyperfactorial holds generally:: >>> z = 3-4*j >>> hyperfac(z) (-4.49795891462086e-7 - 6.33262283196162e-7j) >>> z**z * hyperfac(z-1) (-4.49795891462086e-7 - 6.33262283196162e-7j) >>> z = mpf(-0.6) >>> chop(z**z * hyperfac(z-1)) 1.28170142849352 >>> hyperfac(z) 1.28170142849352 The hyperfactorial may also be computed using the integral definition:: >>> z = 2.5 >>> hyperfac(z) 15.9842119922237 >>> (2*pi)**(-z/2)*exp(binomial(z+1,2) + ... quad(lambda t: loggamma(t+1), [0, z])) 15.9842119922237 :func:`~mpmath.hyperfac` supports arbitrary-precision evaluation:: >>> mp.dps = 50 >>> hyperfac(10) 215779412229418562091680268288000000000000000.0 >>> hyperfac(1/sqrt(2)) 0.89404818005227001975423476035729076375705084390942 **References** 1. http://oeis.org/A002109 2. http://mathworld.wolfram.com/Hyperfactorial.html """ rgamma = r""" Computes the reciprocal of the gamma function, `1/\Gamma(z)`. This function evaluates to zero at the poles of the gamma function, `z = 0, -1, -2, \ldots`. **Examples** Basic examples:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> rgamma(1) 1.0 >>> rgamma(4) 0.1666666666666666666666667 >>> rgamma(0); rgamma(-1) 0.0 0.0 >>> rgamma(1000) 2.485168143266784862783596e-2565 >>> rgamma(inf) 0.0 A definite integral that can be evaluated in terms of elementary integrals:: >>> quad(rgamma, [0,inf]) 2.807770242028519365221501 >>> e + quad(lambda t: exp(-t)/(pi**2+log(t)**2), [0,inf]) 2.807770242028519365221501 """ loggamma = r""" Computes the principal branch of the log-gamma function, `\ln \Gamma(z)`. Unlike `\ln(\Gamma(z))`, which has infinitely many complex branch cuts, the principal log-gamma function only has a single branch cut along the negative half-axis. The principal branch continuously matches the asymptotic Stirling expansion .. math :: \ln \Gamma(z) \sim \frac{\ln(2 \pi)}{2} + \left(z-\frac{1}{2}\right) \ln(z) - z + O(z^{-1}). The real parts of both functions agree, but their imaginary parts generally differ by `2 n \pi` for some `n \in \mathbb{Z}`. They coincide for `z \in \mathbb{R}, z > 0`. Computationally, it is advantageous to use :func:`~mpmath.loggamma` instead of :func:`~mpmath.gamma` for extremely large arguments. **Examples** Comparing with `\ln(\Gamma(z))`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> loggamma('13.2'); log(gamma('13.2')) 20.49400419456603678498394 20.49400419456603678498394 >>> loggamma(3+4j) (-1.756626784603784110530604 + 4.742664438034657928194889j) >>> log(gamma(3+4j)) (-1.756626784603784110530604 - 1.540520869144928548730397j) >>> log(gamma(3+4j)) + 2*pi*j (-1.756626784603784110530604 + 4.742664438034657928194889j) Note the imaginary parts for negative arguments:: >>> loggamma(-0.5); loggamma(-1.5); loggamma(-2.5) (1.265512123484645396488946 - 3.141592653589793238462643j) (0.8600470153764810145109327 - 6.283185307179586476925287j) (-0.05624371649767405067259453 - 9.42477796076937971538793j) Some special values:: >>> loggamma(1); loggamma(2) 0.0 0.0 >>> loggamma(3); +ln2 0.6931471805599453094172321 0.6931471805599453094172321 >>> loggamma(3.5); log(15*sqrt(pi)/8) 1.200973602347074224816022 1.200973602347074224816022 >>> loggamma(inf) +inf Huge arguments are permitted:: >>> loggamma('1e30') 6.807755278982137052053974e+31 >>> loggamma('1e300') 6.897755278982137052053974e+302 >>> loggamma('1e3000') 6.906755278982137052053974e+3003 >>> loggamma('1e100000000000000000000') 2.302585092994045684007991e+100000000000000000020 >>> loggamma('1e30j') (-1.570796326794896619231322e+30 + 6.807755278982137052053974e+31j) >>> loggamma('1e300j') (-1.570796326794896619231322e+300 + 6.897755278982137052053974e+302j) >>> loggamma('1e3000j') (-1.570796326794896619231322e+3000 + 6.906755278982137052053974e+3003j) The log-gamma function can be integrated analytically on any interval of unit length:: >>> z = 0 >>> quad(loggamma, [z,z+1]); log(2*pi)/2 0.9189385332046727417803297 0.9189385332046727417803297 >>> z = 3+4j >>> quad(loggamma, [z,z+1]); (log(z)-1)*z + log(2*pi)/2 (-0.9619286014994750641314421 + 5.219637303741238195688575j) (-0.9619286014994750641314421 + 5.219637303741238195688575j) The derivatives of the log-gamma function are given by the polygamma function (:func:`~mpmath.psi`):: >>> diff(loggamma, -4+3j); psi(0, -4+3j) (1.688493531222971393607153 + 2.554898911356806978892748j) (1.688493531222971393607153 + 2.554898911356806978892748j) >>> diff(loggamma, -4+3j, 2); psi(1, -4+3j) (-0.1539414829219882371561038 - 0.1020485197430267719746479j) (-0.1539414829219882371561038 - 0.1020485197430267719746479j) The log-gamma function satisfies an additive form of the recurrence relation for the ordinary gamma function:: >>> z = 2+3j >>> loggamma(z); loggamma(z+1) - log(z) (-2.092851753092733349564189 + 2.302396543466867626153708j) (-2.092851753092733349564189 + 2.302396543466867626153708j) """ siegeltheta = r""" Computes the Riemann-Siegel theta function, .. math :: \theta(t) = \frac{ \log\Gamma\left(\frac{1+2it}{4}\right) - \log\Gamma\left(\frac{1-2it}{4}\right) }{2i} - \frac{\log \pi}{2} t. The Riemann-Siegel theta function is important in providing the phase factor for the Z-function (see :func:`~mpmath.siegelz`). Evaluation is supported for real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> siegeltheta(0) 0.0 >>> siegeltheta(inf) +inf >>> siegeltheta(-inf) -inf >>> siegeltheta(1) -1.767547952812290388302216 >>> siegeltheta(10+0.25j) (-3.068638039426838572528867 + 0.05804937947429712998395177j) Arbitrary derivatives may be computed with derivative = k >>> siegeltheta(1234, derivative=2) 0.0004051864079114053109473741 >>> diff(siegeltheta, 1234, n=2) 0.0004051864079114053109473741 The Riemann-Siegel theta function has odd symmetry around `t = 0`, two local extreme points and three real roots including 0 (located symmetrically):: >>> nprint(chop(taylor(siegeltheta, 0, 5))) [0.0, -2.68609, 0.0, 2.69433, 0.0, -6.40218] >>> findroot(diffun(siegeltheta), 7) 6.28983598883690277966509 >>> findroot(siegeltheta, 20) 17.84559954041086081682634 For large `t`, there is a famous asymptotic formula for `\theta(t)`, to first order given by:: >>> t = mpf(10**6) >>> siegeltheta(t) 5488816.353078403444882823 >>> -t*log(2*pi/t)/2-t/2 5488816.745777464310273645 """ grampoint = r""" Gives the `n`-th Gram point `g_n`, defined as the solution to the equation `\theta(g_n) = \pi n` where `\theta(t)` is the Riemann-Siegel theta function (:func:`~mpmath.siegeltheta`). The first few Gram points are:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> grampoint(0) 17.84559954041086081682634 >>> grampoint(1) 23.17028270124630927899664 >>> grampoint(2) 27.67018221781633796093849 >>> grampoint(3) 31.71797995476405317955149 Checking the definition:: >>> siegeltheta(grampoint(3)) 9.42477796076937971538793 >>> 3*pi 9.42477796076937971538793 A large Gram point:: >>> grampoint(10**10) 3293531632.728335454561153 Gram points are useful when studying the Z-function (:func:`~mpmath.siegelz`). See the documentation of that function for additional examples. :func:`~mpmath.grampoint` can solve the defining equation for nonintegral `n`. There is a fixed point where `g(x) = x`:: >>> findroot(lambda x: grampoint(x) - x, 10000) 9146.698193171459265866198 **References** 1. http://mathworld.wolfram.com/GramPoint.html """ siegelz = r""" Computes the Z-function, also known as the Riemann-Siegel Z function, .. math :: Z(t) = e^{i \theta(t)} \zeta(1/2+it) where `\zeta(s)` is the Riemann zeta function (:func:`~mpmath.zeta`) and where `\theta(t)` denotes the Riemann-Siegel theta function (see :func:`~mpmath.siegeltheta`). Evaluation is supported for real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> siegelz(1) -0.7363054628673177346778998 >>> siegelz(3+4j) (-0.1852895764366314976003936 - 0.2773099198055652246992479j) The first four derivatives are supported, using the optional *derivative* keyword argument:: >>> siegelz(1234567, derivative=3) 56.89689348495089294249178 >>> diff(siegelz, 1234567, n=3) 56.89689348495089294249178 The Z-function has a Maclaurin expansion:: >>> nprint(chop(taylor(siegelz, 0, 4))) [-1.46035, 0.0, 2.73588, 0.0, -8.39357] The Z-function `Z(t)` is equal to `\pm |\zeta(s)|` on the critical line `s = 1/2+it` (i.e. for real arguments `t` to `Z`). Its zeros coincide with those of the Riemann zeta function:: >>> findroot(siegelz, 14) 14.13472514173469379045725 >>> findroot(siegelz, 20) 21.02203963877155499262848 >>> findroot(zeta, 0.5+14j) (0.5 + 14.13472514173469379045725j) >>> findroot(zeta, 0.5+20j) (0.5 + 21.02203963877155499262848j) Since the Z-function is real-valued on the critical line (and unlike `|\zeta(s)|` analytic), it is useful for investigating the zeros of the Riemann zeta function. For example, one can use a root-finding algorithm based on sign changes:: >>> findroot(siegelz, [100, 200], solver='bisect') 176.4414342977104188888926 To locate roots, Gram points `g_n` which can be computed by :func:`~mpmath.grampoint` are useful. If `(-1)^n Z(g_n)` is positive for two consecutive `n`, then `Z(t)` must have a zero between those points:: >>> g10 = grampoint(10) >>> g11 = grampoint(11) >>> (-1)**10 * siegelz(g10) > 0 True >>> (-1)**11 * siegelz(g11) > 0 True >>> findroot(siegelz, [g10, g11], solver='bisect') 56.44624769706339480436776 >>> g10, g11 (54.67523744685325626632663, 57.54516517954725443703014) """ riemannr = r""" Evaluates the Riemann R function, a smooth approximation of the prime counting function `\pi(x)` (see :func:`~mpmath.primepi`). The Riemann R function gives a fast numerical approximation useful e.g. to roughly estimate the number of primes in a given interval. The Riemann R function is computed using the rapidly convergent Gram series, .. math :: R(x) = 1 + \sum_{k=1}^{\infty} \frac{\log^k x}{k k! \zeta(k+1)}. From the Gram series, one sees that the Riemann R function is a well-defined analytic function (except for a branch cut along the negative real half-axis); it can be evaluated for arbitrary real or complex arguments. The Riemann R function gives a very accurate approximation of the prime counting function. For example, it is wrong by at most 2 for `x < 1000`, and for `x = 10^9` differs from the exact value of `\pi(x)` by 79, or less than two parts in a million. It is about 10 times more accurate than the logarithmic integral estimate (see :func:`~mpmath.li`), which however is even faster to evaluate. It is orders of magnitude more accurate than the extremely fast `x/\log x` estimate. **Examples** For small arguments, the Riemann R function almost exactly gives the prime counting function if rounded to the nearest integer:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> primepi(50), riemannr(50) (15, 14.9757023241462) >>> max(abs(primepi(n)-int(round(riemannr(n)))) for n in range(100)) 1 >>> max(abs(primepi(n)-int(round(riemannr(n)))) for n in range(300)) 2 The Riemann R function can be evaluated for arguments far too large for exact determination of `\pi(x)` to be computationally feasible with any presently known algorithm:: >>> riemannr(10**30) 1.46923988977204e+28 >>> riemannr(10**100) 4.3619719871407e+97 >>> riemannr(10**1000) 4.3448325764012e+996 A comparison of the Riemann R function and logarithmic integral estimates for `\pi(x)` using exact values of `\pi(10^n)` up to `n = 9`. The fractional error is shown in parentheses:: >>> exact = [4,25,168,1229,9592,78498,664579,5761455,50847534] >>> for n, p in enumerate(exact): ... n += 1 ... r, l = riemannr(10**n), li(10**n) ... rerr, lerr = nstr((r-p)/p,3), nstr((l-p)/p,3) ... print("%i %i %s(%s) %s(%s)" % (n, p, r, rerr, l, lerr)) ... 1 4 4.56458314100509(0.141) 6.1655995047873(0.541) 2 25 25.6616332669242(0.0265) 30.1261415840796(0.205) 3 168 168.359446281167(0.00214) 177.609657990152(0.0572) 4 1229 1226.93121834343(-0.00168) 1246.13721589939(0.0139) 5 9592 9587.43173884197(-0.000476) 9629.8090010508(0.00394) 6 78498 78527.3994291277(0.000375) 78627.5491594622(0.00165) 7 664579 664667.447564748(0.000133) 664918.405048569(0.000511) 8 5761455 5761551.86732017(1.68e-5) 5762209.37544803(0.000131) 9 50847534 50847455.4277214(-1.55e-6) 50849234.9570018(3.35e-5) The derivative of the Riemann R function gives the approximate probability for a number of magnitude `x` to be prime:: >>> diff(riemannr, 1000) 0.141903028110784 >>> mpf(primepi(1050) - primepi(950)) / 100 0.15 Evaluation is supported for arbitrary arguments and at arbitrary precision:: >>> mp.dps = 30 >>> riemannr(7.5) 3.72934743264966261918857135136 >>> riemannr(-4+2j) (-0.551002208155486427591793957644 + 2.16966398138119450043195899746j) """ primepi = r""" Evaluates the prime counting function, `\pi(x)`, which gives the number of primes less than or equal to `x`. The argument `x` may be fractional. The prime counting function is very expensive to evaluate precisely for large `x`, and the present implementation is not optimized in any way. For numerical approximation of the prime counting function, it is better to use :func:`~mpmath.primepi2` or :func:`~mpmath.riemannr`. Some values of the prime counting function:: >>> from mpmath import * >>> [primepi(k) for k in range(20)] [0, 0, 1, 2, 2, 3, 3, 4, 4, 4, 4, 5, 5, 6, 6, 6, 6, 7, 7, 8] >>> primepi(3.5) 2 >>> primepi(100000) 9592 """ primepi2 = r""" Returns an interval (as an ``mpi`` instance) providing bounds for the value of the prime counting function `\pi(x)`. For small `x`, :func:`~mpmath.primepi2` returns an exact interval based on the output of :func:`~mpmath.primepi`. For `x > 2656`, a loose interval based on Schoenfeld's inequality .. math :: |\pi(x) - \mathrm{li}(x)| < \frac{\sqrt x \log x}{8 \pi} is returned. This estimate is rigorous assuming the truth of the Riemann hypothesis, and can be computed very quickly. **Examples** Exact values of the prime counting function for small `x`:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> iv.dps = 15; iv.pretty = True >>> primepi2(10) [4.0, 4.0] >>> primepi2(100) [25.0, 25.0] >>> primepi2(1000) [168.0, 168.0] Loose intervals are generated for moderately large `x`: >>> primepi2(10000), primepi(10000) ([1209.0, 1283.0], 1229) >>> primepi2(50000), primepi(50000) ([5070.0, 5263.0], 5133) As `x` increases, the absolute error gets worse while the relative error improves. The exact value of `\pi(10^{23})` is 1925320391606803968923, and :func:`~mpmath.primepi2` gives 9 significant digits:: >>> p = primepi2(10**23) >>> p [1.9253203909477020467e+21, 1.925320392280406229e+21] >>> mpf(p.delta) / mpf(p.a) 6.9219865355293e-10 A more precise, nonrigorous estimate for `\pi(x)` can be obtained using the Riemann R function (:func:`~mpmath.riemannr`). For large enough `x`, the value returned by :func:`~mpmath.primepi2` essentially amounts to a small perturbation of the value returned by :func:`~mpmath.riemannr`:: >>> primepi2(10**100) [4.3619719871407024816e+97, 4.3619719871407032404e+97] >>> riemannr(10**100) 4.3619719871407e+97 """ primezeta = r""" Computes the prime zeta function, which is defined in analogy with the Riemann zeta function (:func:`~mpmath.zeta`) as .. math :: P(s) = \sum_p \frac{1}{p^s} where the sum is taken over all prime numbers `p`. Although this sum only converges for `\mathrm{Re}(s) > 1`, the function is defined by analytic continuation in the half-plane `\mathrm{Re}(s) > 0`. **Examples** Arbitrary-precision evaluation for real and complex arguments is supported:: >>> from mpmath import * >>> mp.dps = 30; mp.pretty = True >>> primezeta(2) 0.452247420041065498506543364832 >>> primezeta(pi) 0.15483752698840284272036497397 >>> mp.dps = 50 >>> primezeta(3) 0.17476263929944353642311331466570670097541212192615 >>> mp.dps = 20 >>> primezeta(3+4j) (-0.12085382601645763295 - 0.013370403397787023602j) The prime zeta function has a logarithmic pole at `s = 1`, with residue equal to the difference of the Mertens and Euler constants:: >>> primezeta(1) +inf >>> extradps(25)(lambda x: primezeta(1+x)+log(x))(+eps) -0.31571845205389007685 >>> mertens-euler -0.31571845205389007685 The analytic continuation to `0 < \mathrm{Re}(s) \le 1` is implemented. In this strip the function exhibits very complex behavior; on the unit interval, it has poles at `1/n` for every squarefree integer `n`:: >>> primezeta(0.5) # Pole at s = 1/2 (-inf + 3.1415926535897932385j) >>> primezeta(0.25) (-1.0416106801757269036 + 0.52359877559829887308j) >>> primezeta(0.5+10j) (0.54892423556409790529 + 0.45626803423487934264j) Although evaluation works in principle for any `\mathrm{Re}(s) > 0`, it should be noted that the evaluation time increases exponentially as `s` approaches the imaginary axis. For large `\mathrm{Re}(s)`, `P(s)` is asymptotic to `2^{-s}`:: >>> primezeta(inf) 0.0 >>> primezeta(10), mpf(2)**-10 (0.00099360357443698021786, 0.0009765625) >>> primezeta(1000) 9.3326361850321887899e-302 >>> primezeta(1000+1000j) (-3.8565440833654995949e-302 - 8.4985390447553234305e-302j) **References** Carl-Erik Froberg, "On the prime zeta function", BIT 8 (1968), pp. 187-202. """ bernpoly = r""" Evaluates the Bernoulli polynomial `B_n(z)`. The first few Bernoulli polynomials are:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(6): ... nprint(chop(taylor(lambda x: bernpoly(n,x), 0, n))) ... [1.0] [-0.5, 1.0] [0.166667, -1.0, 1.0] [0.0, 0.5, -1.5, 1.0] [-0.0333333, 0.0, 1.0, -2.0, 1.0] [0.0, -0.166667, 0.0, 1.66667, -2.5, 1.0] At `z = 0`, the Bernoulli polynomial evaluates to a Bernoulli number (see :func:`~mpmath.bernoulli`):: >>> bernpoly(12, 0), bernoulli(12) (-0.253113553113553, -0.253113553113553) >>> bernpoly(13, 0), bernoulli(13) (0.0, 0.0) Evaluation is accurate for large `n` and small `z`:: >>> mp.dps = 25 >>> bernpoly(100, 0.5) 2.838224957069370695926416e+78 >>> bernpoly(1000, 10.5) 5.318704469415522036482914e+1769 """ polylog = r""" Computes the polylogarithm, defined by the sum .. math :: \mathrm{Li}_s(z) = \sum_{k=1}^{\infty} \frac{z^k}{k^s}. This series is convergent only for `|z| < 1`, so elsewhere the analytic continuation is implied. The polylogarithm should not be confused with the logarithmic integral (also denoted by Li or li), which is implemented as :func:`~mpmath.li`. **Examples** The polylogarithm satisfies a huge number of functional identities. A sample of polylogarithm evaluations is shown below:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> polylog(1,0.5), log(2) (0.693147180559945, 0.693147180559945) >>> polylog(2,0.5), (pi**2-6*log(2)**2)/12 (0.582240526465012, 0.582240526465012) >>> polylog(2,-phi), -log(phi)**2-pi**2/10 (-1.21852526068613, -1.21852526068613) >>> polylog(3,0.5), 7*zeta(3)/8-pi**2*log(2)/12+log(2)**3/6 (0.53721319360804, 0.53721319360804) :func:`~mpmath.polylog` can evaluate the analytic continuation of the polylogarithm when `s` is an integer:: >>> polylog(2, 10) (0.536301287357863 - 7.23378441241546j) >>> polylog(2, -10) -4.1982778868581 >>> polylog(2, 10j) (-3.05968879432873 + 3.71678149306807j) >>> polylog(-2, 10) -0.150891632373114 >>> polylog(-2, -10) 0.067618332081142 >>> polylog(-2, 10j) (0.0384353698579347 + 0.0912451798066779j) Some more examples, with arguments on the unit circle (note that the series definition cannot be used for computation here):: >>> polylog(2,j) (-0.205616758356028 + 0.915965594177219j) >>> j*catalan-pi**2/48 (-0.205616758356028 + 0.915965594177219j) >>> polylog(3,exp(2*pi*j/3)) (-0.534247512515375 + 0.765587078525922j) >>> -4*zeta(3)/9 + 2*j*pi**3/81 (-0.534247512515375 + 0.765587078525921j) Polylogarithms of different order are related by integration and differentiation:: >>> s, z = 3, 0.5 >>> polylog(s+1, z) 0.517479061673899 >>> quad(lambda t: polylog(s,t)/t, [0, z]) 0.517479061673899 >>> z*diff(lambda t: polylog(s+2,t), z) 0.517479061673899 Taylor series expansions around `z = 0` are:: >>> for n in range(-3, 4): ... nprint(taylor(lambda x: polylog(n,x), 0, 5)) ... [0.0, 1.0, 8.0, 27.0, 64.0, 125.0] [0.0, 1.0, 4.0, 9.0, 16.0, 25.0] [0.0, 1.0, 2.0, 3.0, 4.0, 5.0] [0.0, 1.0, 1.0, 1.0, 1.0, 1.0] [0.0, 1.0, 0.5, 0.333333, 0.25, 0.2] [0.0, 1.0, 0.25, 0.111111, 0.0625, 0.04] [0.0, 1.0, 0.125, 0.037037, 0.015625, 0.008] The series defining the polylogarithm is simultaneously a Taylor series and an L-series. For certain values of `z`, the polylogarithm reduces to a pure zeta function:: >>> polylog(pi, 1), zeta(pi) (1.17624173838258, 1.17624173838258) >>> polylog(pi, -1), -altzeta(pi) (-0.909670702980385, -0.909670702980385) Evaluation for arbitrary, nonintegral `s` is supported for `z` within the unit circle: >>> polylog(3+4j, 0.25) (0.24258605789446 - 0.00222938275488344j) >>> nsum(lambda k: 0.25**k / k**(3+4j), [1,inf]) (0.24258605789446 - 0.00222938275488344j) It is also supported outside of the unit circle:: >>> polylog(1+j, 20+40j) (-7.1421172179728 - 3.92726697721369j) >>> polylog(1+j, 200+400j) (-5.41934747194626 - 9.94037752563927j) **References** 1. Richard Crandall, "Note on fast polylogarithm computation" http://people.reed.edu/~crandall/papers/Polylog.pdf 2. http://en.wikipedia.org/wiki/Polylogarithm 3. http://mathworld.wolfram.com/Polylogarithm.html """ bell = r""" For `n` a nonnegative integer, ``bell(n,x)`` evaluates the Bell polynomial `B_n(x)`, the first few of which are .. math :: B_0(x) = 1 B_1(x) = x B_2(x) = x^2+x B_3(x) = x^3+3x^2+x If `x = 1` or :func:`~mpmath.bell` is called with only one argument, it gives the `n`-th Bell number `B_n`, which is the number of partitions of a set with `n` elements. By setting the precision to at least `\log_{10} B_n` digits, :func:`~mpmath.bell` provides fast calculation of exact Bell numbers. In general, :func:`~mpmath.bell` computes .. math :: B_n(x) = e^{-x} \left(\mathrm{sinc}(\pi n) + E_n(x)\right) where `E_n(x)` is the generalized exponential function implemented by :func:`~mpmath.polyexp`. This is an extension of Dobinski's formula [1], where the modification is the sinc term ensuring that `B_n(x)` is continuous in `n`; :func:`~mpmath.bell` can thus be evaluated, differentiated, etc for arbitrary complex arguments. **Examples** Simple evaluations:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> bell(0, 2.5) 1.0 >>> bell(1, 2.5) 2.5 >>> bell(2, 2.5) 8.75 Evaluation for arbitrary complex arguments:: >>> bell(5.75+1j, 2-3j) (-10767.71345136587098445143 - 15449.55065599872579097221j) The first few Bell polynomials:: >>> for k in range(7): ... nprint(taylor(lambda x: bell(k,x), 0, k)) ... [1.0] [0.0, 1.0] [0.0, 1.0, 1.0] [0.0, 1.0, 3.0, 1.0] [0.0, 1.0, 7.0, 6.0, 1.0] [0.0, 1.0, 15.0, 25.0, 10.0, 1.0] [0.0, 1.0, 31.0, 90.0, 65.0, 15.0, 1.0] The first few Bell numbers and complementary Bell numbers:: >>> [int(bell(k)) for k in range(10)] [1, 1, 2, 5, 15, 52, 203, 877, 4140, 21147] >>> [int(bell(k,-1)) for k in range(10)] [1, -1, 0, 1, 1, -2, -9, -9, 50, 267] Large Bell numbers:: >>> mp.dps = 50 >>> bell(50) 185724268771078270438257767181908917499221852770.0 >>> bell(50,-1) -29113173035759403920216141265491160286912.0 Some even larger values:: >>> mp.dps = 25 >>> bell(1000,-1) -1.237132026969293954162816e+1869 >>> bell(1000) 2.989901335682408421480422e+1927 >>> bell(1000,2) 6.591553486811969380442171e+1987 >>> bell(1000,100.5) 9.101014101401543575679639e+2529 A determinant identity satisfied by Bell numbers:: >>> mp.dps = 15 >>> N = 8 >>> det([[bell(k+j) for j in range(N)] for k in range(N)]) 125411328000.0 >>> superfac(N-1) 125411328000.0 **References** 1. http://mathworld.wolfram.com/DobinskisFormula.html """ polyexp = r""" Evaluates the polyexponential function, defined for arbitrary complex `s`, `z` by the series .. math :: E_s(z) = \sum_{k=1}^{\infty} \frac{k^s}{k!} z^k. `E_s(z)` is constructed from the exponential function analogously to how the polylogarithm is constructed from the ordinary logarithm; as a function of `s` (with `z` fixed), `E_s` is an L-series It is an entire function of both `s` and `z`. The polyexponential function provides a generalization of the Bell polynomials `B_n(x)` (see :func:`~mpmath.bell`) to noninteger orders `n`. In terms of the Bell polynomials, .. math :: E_s(z) = e^z B_s(z) - \mathrm{sinc}(\pi s). Note that `B_n(x)` and `e^{-x} E_n(x)` are identical if `n` is a nonzero integer, but not otherwise. In particular, they differ at `n = 0`. **Examples** Evaluating a series:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> nsum(lambda k: sqrt(k)/fac(k), [1,inf]) 2.101755547733791780315904 >>> polyexp(0.5,1) 2.101755547733791780315904 Evaluation for arbitrary arguments:: >>> polyexp(-3-4j, 2.5+2j) (2.351660261190434618268706 + 1.202966666673054671364215j) Evaluation is accurate for tiny function values:: >>> polyexp(4, -100) 3.499471750566824369520223e-36 If `n` is a nonpositive integer, `E_n` reduces to a special instance of the hypergeometric function `\,_pF_q`:: >>> n = 3 >>> x = pi >>> polyexp(-n,x) 4.042192318847986561771779 >>> x*hyper([1]*(n+1), [2]*(n+1), x) 4.042192318847986561771779 """ cyclotomic = r""" Evaluates the cyclotomic polynomial `\Phi_n(x)`, defined by .. math :: \Phi_n(x) = \prod_{\zeta} (x - \zeta) where `\zeta` ranges over all primitive `n`-th roots of unity (see :func:`~mpmath.unitroots`). An equivalent representation, used for computation, is .. math :: \Phi_n(x) = \prod_{d\mid n}(x^d-1)^{\mu(n/d)} = \Phi_n(x) where `\mu(m)` denotes the Moebius function. The cyclotomic polynomials are integer polynomials, the first of which can be written explicitly as .. math :: \Phi_0(x) = 1 \Phi_1(x) = x - 1 \Phi_2(x) = x + 1 \Phi_3(x) = x^3 + x^2 + 1 \Phi_4(x) = x^2 + 1 \Phi_5(x) = x^4 + x^3 + x^2 + x + 1 \Phi_6(x) = x^2 - x + 1 **Examples** The coefficients of low-order cyclotomic polynomials can be recovered using Taylor expansion:: >>> from mpmath import * >>> mp.dps = 15; mp.pretty = True >>> for n in range(9): ... p = chop(taylor(lambda x: cyclotomic(n,x), 0, 10)) ... print("%s %s" % (n, nstr(p[:10+1-p[::-1].index(1)]))) ... 0 [1.0] 1 [-1.0, 1.0] 2 [1.0, 1.0] 3 [1.0, 1.0, 1.0] 4 [1.0, 0.0, 1.0] 5 [1.0, 1.0, 1.0, 1.0, 1.0] 6 [1.0, -1.0, 1.0] 7 [1.0, 1.0, 1.0, 1.0, 1.0, 1.0, 1.0] 8 [1.0, 0.0, 0.0, 0.0, 1.0] The definition as a product over primitive roots may be checked by computing the product explicitly (for a real argument, this method will generally introduce numerical noise in the imaginary part):: >>> mp.dps = 25 >>> z = 3+4j >>> cyclotomic(10, z) (-419.0 - 360.0j) >>> fprod(z-r for r in unitroots(10, primitive=True)) (-419.0 - 360.0j) >>> z = 3 >>> cyclotomic(10, z) 61.0 >>> fprod(z-r for r in unitroots(10, primitive=True)) (61.0 - 3.146045605088568607055454e-25j) Up to permutation, the roots of a given cyclotomic polynomial can be checked to agree with the list of primitive roots:: >>> p = taylor(lambda x: cyclotomic(6,x), 0, 6)[:3] >>> for r in polyroots(p[::-1]): ... print(r) ... (0.5 - 0.8660254037844386467637232j) (0.5 + 0.8660254037844386467637232j) >>> >>> for r in unitroots(6, primitive=True): ... print(r) ... (0.5 + 0.8660254037844386467637232j) (0.5 - 0.8660254037844386467637232j) """ meijerg = r""" Evaluates the Meijer G-function, defined as .. math :: G^{m,n}_{p,q} \left( \left. \begin{matrix} a_1, \dots, a_n ; a_{n+1} \dots a_p \\ b_1, \dots, b_m ; b_{m+1} \dots b_q \end{matrix}\; \right| \; z ; r \right) = \frac{1}{2 \pi i} \int_L \frac{\prod_{j=1}^m \Gamma(b_j+s) \prod_{j=1}^n\Gamma(1-a_j-s)} {\prod_{j=n+1}^{p}\Gamma(a_j+s) \prod_{j=m+1}^q \Gamma(1-b_j-s)} z^{-s/r} ds for an appropriate choice of the contour `L` (see references). There are `p` elements `a_j`. The argument *a_s* should be a pair of lists, the first containing the `n` elements `a_1, \ldots, a_n` and the second containing the `p-n` elements `a_{n+1}, \ldots a_p`. There are `q` elements `b_j`. The argument *b_s* should be a pair of lists, the first containing the `m` elements `b_1, \ldots, b_m` and the second containing the `q-m` elements `b_{m+1}, \ldots b_q`. The implicit tuple `(m, n, p, q)` constitutes the order or degree of the Meijer G-function, and is determined by the lengths of the coefficient vectors. Confusingly, the indices in this tuple appear in a different order from the coefficients, but this notation is standard. The many examples given below should hopefully clear up any potential confusion. **Algorithm** The Meijer G-function is evaluated as a combination of hypergeometric series. There are two versions of the function, which can be selected with the optional *series* argument. *series=1* uses a sum of `m` `\,_pF_{q-1}` functions of `z` *series=2* uses a sum of `n` `\,_qF_{p-1}` functions of `1/z` The default series is chosen based on the degree and `|z|` in order to be consistent with Mathematica's. This definition of the Meijer G-function has a discontinuity at `|z| = 1` for some orders, which can be avoided by explicitly specifying a series. Keyword arguments are forwarded to :func:`~mpmath.hypercomb`. **Examples** Many standard functions are special cases of the Meijer G-function (possibly rescaled and/or with branch cut corrections). We define some test parameters:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> a = mpf(0.75) >>> b = mpf(1.5) >>> z = mpf(2.25) The exponential function: `e^z = G^{1,0}_{0,1} \left( \left. \begin{matrix} - \\ 0 \end{matrix} \; \right| \; -z \right)` >>> meijerg([[],[]], [[0],[]], -z) 9.487735836358525720550369 >>> exp(z) 9.487735836358525720550369 The natural logarithm: `\log(1+z) = G^{1,2}_{2,2} \left( \left. \begin{matrix} 1, 1 \\ 1, 0 \end{matrix} \; \right| \; -z \right)` >>> meijerg([[1,1],[]], [[1],[0]], z) 1.178654996341646117219023 >>> log(1+z) 1.178654996341646117219023 A rational function: `\frac{z}{z+1} = G^{1,2}_{2,2} \left( \left. \begin{matrix} 1, 1 \\ 1, 1 \end{matrix} \; \right| \; z \right)` >>> meijerg([[1,1],[]], [[1],[1]], z) 0.6923076923076923076923077 >>> z/(z+1) 0.6923076923076923076923077 The sine and cosine functions: `\frac{1}{\sqrt \pi} \sin(2 \sqrt z) = G^{1,0}_{0,2} \left( \left. \begin{matrix} - \\ \frac{1}{2}, 0 \end{matrix} \; \right| \; z \right)` `\frac{1}{\sqrt \pi} \cos(2 \sqrt z) = G^{1,0}_{0,2} \left( \left. \begin{matrix} - \\ 0, \frac{1}{2} \end{matrix} \; \right| \; z \right)` >>> meijerg([[],[]], [[0.5],[0]], (z/2)**2) 0.4389807929218676682296453 >>> sin(z)/sqrt(pi) 0.4389807929218676682296453 >>> meijerg([[],[]], [[0],[0.5]], (z/2)**2) -0.3544090145996275423331762 >>> cos(z)/sqrt(pi) -0.3544090145996275423331762 Bessel functions: `J_a(2 \sqrt z) = G^{1,0}_{0,2} \left( \left. \begin{matrix} - \\ \frac{a}{2}, -\frac{a}{2} \end{matrix} \; \right| \; z \right)` `Y_a(2 \sqrt z) = G^{2,0}_{1,3} \left( \left. \begin{matrix} \frac{-a-1}{2} \\ \frac{a}{2}, -\frac{a}{2}, \frac{-a-1}{2} \end{matrix} \; \right| \; z \right)` `(-z)^{a/2} z^{-a/2} I_a(2 \sqrt z) = G^{1,0}_{0,2} \left( \left. \begin{matrix} - \\ \frac{a}{2}, -\frac{a}{2} \end{matrix} \; \right| \; -z \right)` `2 K_a(2 \sqrt z) = G^{2,0}_{0,2} \left( \left. \begin{matrix} - \\ \frac{a}{2}, -\frac{a}{2} \end{matrix} \; \right| \; z \right)` As the example with the Bessel *I* function shows, a branch factor is required for some arguments when inverting the square root. >>> meijerg([[],[]], [[a/2],[-a/2]], (z/2)**2) 0.5059425789597154858527264 >>> besselj(a,z) 0.5059425789597154858527264 >>> meijerg([[],[(-a-1)/2]], [[a/2,-a/2],[(-a-1)/2]], (z/2)**2) 0.1853868950066556941442559 >>> bessely(a, z) 0.1853868950066556941442559 >>> meijerg([[],[]], [[a/2],[-a/2]], -(z/2)**2) (0.8685913322427653875717476 + 2.096964974460199200551738j) >>> (-z)**(a/2) / z**(a/2) * besseli(a, z) (0.8685913322427653875717476 + 2.096964974460199200551738j) >>> 0.5*meijerg([[],[]], [[a/2,-a/2],[]], (z/2)**2) 0.09334163695597828403796071 >>> besselk(a,z) 0.09334163695597828403796071 Error functions: `\sqrt{\pi} z^{2(a-1)} \mathrm{erfc}(z) = G^{2,0}_{1,2} \left( \left. \begin{matrix} a \\ a-1, a-\frac{1}{2} \end{matrix} \; \right| \; z, \frac{1}{2} \right)` >>> meijerg([[],[a]], [[a-1,a-0.5],[]], z, 0.5) 0.00172839843123091957468712 >>> sqrt(pi) * z**(2*a-2) * erfc(z) 0.00172839843123091957468712 A Meijer G-function of higher degree, (1,1,2,3): >>> meijerg([[a],[b]], [[a],[b,a-1]], z) 1.55984467443050210115617 >>> sin((b-a)*pi)/pi*(exp(z)-1)*z**(a-1) 1.55984467443050210115617 A Meijer G-function of still higher degree, (4,1,2,4), that can be expanded as a messy combination of exponential integrals: >>> meijerg([[a],[2*b-a]], [[b,a,b-0.5,-1-a+2*b],[]], z) 0.3323667133658557271898061 >>> chop(4**(a-b+1)*sqrt(pi)*gamma(2*b-2*a)*z**a*\ ... expint(2*b-2*a, -2*sqrt(-z))*expint(2*b-2*a, 2*sqrt(-z))) 0.3323667133658557271898061 In the following case, different series give different values:: >>> chop(meijerg([[1],[0.25]],[[3],[0.5]],-2)) -0.06417628097442437076207337 >>> meijerg([[1],[0.25]],[[3],[0.5]],-2,series=1) 0.1428699426155117511873047 >>> chop(meijerg([[1],[0.25]],[[3],[0.5]],-2,series=2)) -0.06417628097442437076207337 **References** 1. http://en.wikipedia.org/wiki/Meijer_G-function 2. http://mathworld.wolfram.com/MeijerG-Function.html 3. http://functions.wolfram.com/HypergeometricFunctions/MeijerG/ 4. http://functions.wolfram.com/HypergeometricFunctions/MeijerG1/ """ clsin = r""" Computes the Clausen sine function, defined formally by the series .. math :: \mathrm{Cl}_s(z) = \sum_{k=1}^{\infty} \frac{\sin(kz)}{k^s}. The special case `\mathrm{Cl}_2(z)` (i.e. ``clsin(2,z)``) is the classical "Clausen function". More generally, the Clausen function is defined for complex `s` and `z`, even when the series does not converge. The Clausen function is related to the polylogarithm (:func:`~mpmath.polylog`) as .. math :: \mathrm{Cl}_s(z) = \frac{1}{2i}\left(\mathrm{Li}_s\left(e^{iz}\right) - \mathrm{Li}_s\left(e^{-iz}\right)\right) = \mathrm{Im}\left[\mathrm{Li}_s(e^{iz})\right] \quad (s, z \in \mathbb{R}), and this representation can be taken to provide the analytic continuation of the series. The complementary function :func:`~mpmath.clcos` gives the corresponding cosine sum. **Examples** Evaluation for arbitrarily chosen `s` and `z`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> s, z = 3, 4 >>> clsin(s, z); nsum(lambda k: sin(z*k)/k**s, [1,inf]) -0.6533010136329338746275795 -0.6533010136329338746275795 Using `z + \pi` instead of `z` gives an alternating series:: >>> clsin(s, z+pi) 0.8860032351260589402871624 >>> nsum(lambda k: (-1)**k*sin(z*k)/k**s, [1,inf]) 0.8860032351260589402871624 With `s = 1`, the sum can be expressed in closed form using elementary functions:: >>> z = 1 + sqrt(3) >>> clsin(1, z) 0.2047709230104579724675985 >>> chop((log(1-exp(-j*z)) - log(1-exp(j*z)))/(2*j)) 0.2047709230104579724675985 >>> nsum(lambda k: sin(k*z)/k, [1,inf]) 0.2047709230104579724675985 The classical Clausen function `\mathrm{Cl}_2(\theta)` gives the value of the integral `\int_0^{\theta} -\ln(2\sin(x/2)) dx` for `0 < \theta < 2 \pi`:: >>> cl2 = lambda t: clsin(2, t) >>> cl2(3.5) -0.2465045302347694216534255 >>> -quad(lambda x: ln(2*sin(0.5*x)), [0, 3.5]) -0.2465045302347694216534255 This function is symmetric about `\theta = \pi` with zeros and extreme points:: >>> cl2(0); cl2(pi/3); chop(cl2(pi)); cl2(5*pi/3); chop(cl2(2*pi)) 0.0 1.014941606409653625021203 0.0 -1.014941606409653625021203 0.0 Catalan's constant is a special value:: >>> cl2(pi/2) 0.9159655941772190150546035 >>> +catalan 0.9159655941772190150546035 The Clausen sine function can be expressed in closed form when `s` is an odd integer (becoming zero when `s` < 0):: >>> z = 1 + sqrt(2) >>> clsin(1, z); (pi-z)/2 0.3636895456083490948304773 0.3636895456083490948304773 >>> clsin(3, z); pi**2/6*z - pi*z**2/4 + z**3/12 0.5661751584451144991707161 0.5661751584451144991707161 >>> clsin(-1, z) 0.0 >>> clsin(-3, z) 0.0 It can also be expressed in closed form for even integer `s \le 0`, providing a finite sum for series such as `\sin(z) + \sin(2z) + \sin(3z) + \ldots`:: >>> z = 1 + sqrt(2) >>> clsin(0, z) 0.1903105029507513881275865 >>> cot(z/2)/2 0.1903105029507513881275865 >>> clsin(-2, z) -0.1089406163841548817581392 >>> -cot(z/2)*csc(z/2)**2/4 -0.1089406163841548817581392 Call with ``pi=True`` to multiply `z` by `\pi` exactly:: >>> clsin(3, 3*pi) -8.892316224968072424732898e-26 >>> clsin(3, 3, pi=True) 0.0 Evaluation for complex `s`, `z` in a nonconvergent case:: >>> s, z = -1-j, 1+2j >>> clsin(s, z) (-0.593079480117379002516034 + 0.9038644233367868273362446j) >>> extraprec(20)(nsum)(lambda k: sin(k*z)/k**s, [1,inf]) (-0.593079480117379002516034 + 0.9038644233367868273362446j) """ clcos = r""" Computes the Clausen cosine function, defined formally by the series .. math :: \mathrm{\widetilde{Cl}}_s(z) = \sum_{k=1}^{\infty} \frac{\cos(kz)}{k^s}. This function is complementary to the Clausen sine function :func:`~mpmath.clsin`. In terms of the polylogarithm, .. math :: \mathrm{\widetilde{Cl}}_s(z) = \frac{1}{2}\left(\mathrm{Li}_s\left(e^{iz}\right) + \mathrm{Li}_s\left(e^{-iz}\right)\right) = \mathrm{Re}\left[\mathrm{Li}_s(e^{iz})\right] \quad (s, z \in \mathbb{R}). **Examples** Evaluation for arbitrarily chosen `s` and `z`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> s, z = 3, 4 >>> clcos(s, z); nsum(lambda k: cos(z*k)/k**s, [1,inf]) -0.6518926267198991308332759 -0.6518926267198991308332759 Using `z + \pi` instead of `z` gives an alternating series:: >>> s, z = 3, 0.5 >>> clcos(s, z+pi) -0.8155530586502260817855618 >>> nsum(lambda k: (-1)**k*cos(z*k)/k**s, [1,inf]) -0.8155530586502260817855618 With `s = 1`, the sum can be expressed in closed form using elementary functions:: >>> z = 1 + sqrt(3) >>> clcos(1, z) -0.6720334373369714849797918 >>> chop(-0.5*(log(1-exp(j*z))+log(1-exp(-j*z)))) -0.6720334373369714849797918 >>> -log(abs(2*sin(0.5*z))) # Equivalent to above when z is real -0.6720334373369714849797918 >>> nsum(lambda k: cos(k*z)/k, [1,inf]) -0.6720334373369714849797918 It can also be expressed in closed form when `s` is an even integer. For example, >>> clcos(2,z) -0.7805359025135583118863007 >>> pi**2/6 - pi*z/2 + z**2/4 -0.7805359025135583118863007 The case `s = 0` gives the renormalized sum of `\cos(z) + \cos(2z) + \cos(3z) + \ldots` (which happens to be the same for any value of `z`):: >>> clcos(0, z) -0.5 >>> nsum(lambda k: cos(k*z), [1,inf]) -0.5 Also the sums .. math :: \cos(z) + 2\cos(2z) + 3\cos(3z) + \ldots and .. math :: \cos(z) + 2^n \cos(2z) + 3^n \cos(3z) + \ldots for higher integer powers `n = -s` can be done in closed form. They are zero when `n` is positive and even (`s` negative and even):: >>> clcos(-1, z); 1/(2*cos(z)-2) -0.2607829375240542480694126 -0.2607829375240542480694126 >>> clcos(-3, z); (2+cos(z))*csc(z/2)**4/8 0.1472635054979944390848006 0.1472635054979944390848006 >>> clcos(-2, z); clcos(-4, z); clcos(-6, z) 0.0 0.0 0.0 With `z = \pi`, the series reduces to that of the Riemann zeta function (more generally, if `z = p \pi/q`, it is a finite sum over Hurwitz zeta function values):: >>> clcos(2.5, 0); zeta(2.5) 1.34148725725091717975677 1.34148725725091717975677 >>> clcos(2.5, pi); -altzeta(2.5) -0.8671998890121841381913472 -0.8671998890121841381913472 Call with ``pi=True`` to multiply `z` by `\pi` exactly:: >>> clcos(-3, 2*pi) 2.997921055881167659267063e+102 >>> clcos(-3, 2, pi=True) 0.008333333333333333333333333 Evaluation for complex `s`, `z` in a nonconvergent case:: >>> s, z = -1-j, 1+2j >>> clcos(s, z) (0.9407430121562251476136807 + 0.715826296033590204557054j) >>> extraprec(20)(nsum)(lambda k: cos(k*z)/k**s, [1,inf]) (0.9407430121562251476136807 + 0.715826296033590204557054j) """ whitm = r""" Evaluates the Whittaker function `M(k,m,z)`, which gives a solution to the Whittaker differential equation .. math :: \frac{d^2f}{dz^2} + \left(-\frac{1}{4}+\frac{k}{z}+ \frac{(\frac{1}{4}-m^2)}{z^2}\right) f = 0. A second solution is given by :func:`~mpmath.whitw`. The Whittaker functions are defined in Abramowitz & Stegun, section 13.1. They are alternate forms of the confluent hypergeometric functions `\,_1F_1` and `U`: .. math :: M(k,m,z) = e^{-\frac{1}{2}z} z^{\frac{1}{2}+m} \,_1F_1(\tfrac{1}{2}+m-k, 1+2m, z) W(k,m,z) = e^{-\frac{1}{2}z} z^{\frac{1}{2}+m} U(\tfrac{1}{2}+m-k, 1+2m, z). **Examples** Evaluation for arbitrary real and complex arguments is supported:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> whitm(1, 1, 1) 0.7302596799460411820509668 >>> whitm(1, 1, -1) (0.0 - 1.417977827655098025684246j) >>> whitm(j, j/2, 2+3j) (3.245477713363581112736478 - 0.822879187542699127327782j) >>> whitm(2, 3, 100000) 4.303985255686378497193063e+21707 Evaluation at zero:: >>> whitm(1,-1,0); whitm(1,-0.5,0); whitm(1,0,0) +inf nan 0.0 We can verify that :func:`~mpmath.whitm` numerically satisfies the differential equation for arbitrarily chosen values:: >>> k = mpf(0.25) >>> m = mpf(1.5) >>> f = lambda z: whitm(k,m,z) >>> for z in [-1, 2.5, 3, 1+2j]: ... chop(diff(f,z,2) + (-0.25 + k/z + (0.25-m**2)/z**2)*f(z)) ... 0.0 0.0 0.0 0.0 An integral involving both :func:`~mpmath.whitm` and :func:`~mpmath.whitw`, verifying evaluation along the real axis:: >>> quad(lambda x: exp(-x)*whitm(3,2,x)*whitw(1,-2,x), [0,inf]) 3.438869842576800225207341 >>> 128/(21*sqrt(pi)) 3.438869842576800225207341 """ whitw = r""" Evaluates the Whittaker function `W(k,m,z)`, which gives a second solution to the Whittaker differential equation. (See :func:`~mpmath.whitm`.) **Examples** Evaluation for arbitrary real and complex arguments is supported:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> whitw(1, 1, 1) 1.19532063107581155661012 >>> whitw(1, 1, -1) (-0.9424875979222187313924639 - 0.2607738054097702293308689j) >>> whitw(j, j/2, 2+3j) (0.1782899315111033879430369 - 0.01609578360403649340169406j) >>> whitw(2, 3, 100000) 1.887705114889527446891274e-21705 >>> whitw(-1, -1, 100) 1.905250692824046162462058e-24 Evaluation at zero:: >>> for m in [-1, -0.5, 0, 0.5, 1]: ... whitw(1, m, 0) ... +inf nan 0.0 nan +inf We can verify that :func:`~mpmath.whitw` numerically satisfies the differential equation for arbitrarily chosen values:: >>> k = mpf(0.25) >>> m = mpf(1.5) >>> f = lambda z: whitw(k,m,z) >>> for z in [-1, 2.5, 3, 1+2j]: ... chop(diff(f,z,2) + (-0.25 + k/z + (0.25-m**2)/z**2)*f(z)) ... 0.0 0.0 0.0 0.0 """ ber = r""" Computes the Kelvin function ber, which for real arguments gives the real part of the Bessel J function of a rotated argument .. math :: J_n\left(x e^{3\pi i/4}\right) = \mathrm{ber}_n(x) + i \mathrm{bei}_n(x). The imaginary part is given by :func:`~mpmath.bei`. **Plots** .. literalinclude :: /plots/ber.py .. image :: /plots/ber.png **Examples** Verifying the defining relation:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> n, x = 2, 3.5 >>> ber(n,x) 1.442338852571888752631129 >>> bei(n,x) -0.948359035324558320217678 >>> besselj(n, x*root(1,8,3)) (1.442338852571888752631129 - 0.948359035324558320217678j) The ber and bei functions are also defined by analytic continuation for complex arguments:: >>> ber(1+j, 2+3j) (4.675445984756614424069563 - 15.84901771719130765656316j) >>> bei(1+j, 2+3j) (15.83886679193707699364398 + 4.684053288183046528703611j) """ bei = r""" Computes the Kelvin function bei, which for real arguments gives the imaginary part of the Bessel J function of a rotated argument. See :func:`~mpmath.ber`. """ ker = r""" Computes the Kelvin function ker, which for real arguments gives the real part of the (rescaled) Bessel K function of a rotated argument .. math :: e^{-\pi i/2} K_n\left(x e^{3\pi i/4}\right) = \mathrm{ker}_n(x) + i \mathrm{kei}_n(x). The imaginary part is given by :func:`~mpmath.kei`. **Plots** .. literalinclude :: /plots/ker.py .. image :: /plots/ker.png **Examples** Verifying the defining relation:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> n, x = 2, 4.5 >>> ker(n,x) 0.02542895201906369640249801 >>> kei(n,x) -0.02074960467222823237055351 >>> exp(-n*pi*j/2) * besselk(n, x*root(1,8,1)) (0.02542895201906369640249801 - 0.02074960467222823237055351j) The ker and kei functions are also defined by analytic continuation for complex arguments:: >>> ker(1+j, 3+4j) (1.586084268115490421090533 - 2.939717517906339193598719j) >>> kei(1+j, 3+4j) (-2.940403256319453402690132 - 1.585621643835618941044855j) """ kei = r""" Computes the Kelvin function kei, which for real arguments gives the imaginary part of the (rescaled) Bessel K function of a rotated argument. See :func:`~mpmath.ker`. """ struveh = r""" Gives the Struve function .. math :: \,\mathbf{H}_n(z) = \sum_{k=0}^\infty \frac{(-1)^k}{\Gamma(k+\frac{3}{2}) \Gamma(k+n+\frac{3}{2})} {\left({\frac{z}{2}}\right)}^{2k+n+1} which is a solution to the Struve differential equation .. math :: z^2 f''(z) + z f'(z) + (z^2-n^2) f(z) = \frac{2 z^{n+1}}{\pi (2n-1)!!}. **Examples** Evaluation for arbitrary real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> struveh(0, 3.5) 0.3608207733778295024977797 >>> struveh(-1, 10) -0.255212719726956768034732 >>> struveh(1, -100.5) 0.5819566816797362287502246 >>> struveh(2.5, 10000000000000) 3153915652525200060.308937 >>> struveh(2.5, -10000000000000) (0.0 - 3153915652525200060.308937j) >>> struveh(1+j, 1000000+4000000j) (-3.066421087689197632388731e+1737173 - 1.596619701076529803290973e+1737173j) A Struve function of half-integer order is elementary; for example: >>> z = 3 >>> struveh(0.5, 3) 0.9167076867564138178671595 >>> sqrt(2/(pi*z))*(1-cos(z)) 0.9167076867564138178671595 Numerically verifying the differential equation:: >>> z = mpf(4.5) >>> n = 3 >>> f = lambda z: struveh(n,z) >>> lhs = z**2*diff(f,z,2) + z*diff(f,z) + (z**2-n**2)*f(z) >>> rhs = 2*z**(n+1)/fac2(2*n-1)/pi >>> lhs 17.40359302709875496632744 >>> rhs 17.40359302709875496632744 """ struvel = r""" Gives the modified Struve function .. math :: \,\mathbf{L}_n(z) = -i e^{-n\pi i/2} \mathbf{H}_n(i z) which solves to the modified Struve differential equation .. math :: z^2 f''(z) + z f'(z) - (z^2+n^2) f(z) = \frac{2 z^{n+1}}{\pi (2n-1)!!}. **Examples** Evaluation for arbitrary real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> struvel(0, 3.5) 7.180846515103737996249972 >>> struvel(-1, 10) 2670.994904980850550721511 >>> struvel(1, -100.5) 1.757089288053346261497686e+42 >>> struvel(2.5, 10000000000000) 4.160893281017115450519948e+4342944819025 >>> struvel(2.5, -10000000000000) (0.0 - 4.160893281017115450519948e+4342944819025j) >>> struvel(1+j, 700j) (-0.1721150049480079451246076 + 0.1240770953126831093464055j) >>> struvel(1+j, 1000000+4000000j) (-2.973341637511505389128708e+434290 - 5.164633059729968297147448e+434290j) Numerically verifying the differential equation:: >>> z = mpf(3.5) >>> n = 3 >>> f = lambda z: struvel(n,z) >>> lhs = z**2*diff(f,z,2) + z*diff(f,z) - (z**2+n**2)*f(z) >>> rhs = 2*z**(n+1)/fac2(2*n-1)/pi >>> lhs 6.368850306060678353018165 >>> rhs 6.368850306060678353018165 """ appellf1 = r""" Gives the Appell F1 hypergeometric function of two variables, .. math :: F_1(a,b_1,b_2,c,x,y) = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} \frac{(a)_{m+n} (b_1)_m (b_2)_n}{(c)_{m+n}} \frac{x^m y^n}{m! n!}. This series is only generally convergent when `|x| < 1` and `|y| < 1`, although :func:`~mpmath.appellf1` can evaluate an analytic continuation with respecto to either variable, and sometimes both. **Examples** Evaluation is supported for real and complex parameters:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> appellf1(1,0,0.5,1,0.5,0.25) 1.154700538379251529018298 >>> appellf1(1,1+j,0.5,1,0.5,0.5j) (1.138403860350148085179415 + 1.510544741058517621110615j) For some integer parameters, the F1 series reduces to a polynomial:: >>> appellf1(2,-4,-3,1,2,5) -816.0 >>> appellf1(-5,1,2,1,4,5) -20528.0 The analytic continuation with respect to either `x` or `y`, and sometimes with respect to both, can be evaluated:: >>> appellf1(2,3,4,5,100,0.5) (0.0006231042714165329279738662 + 0.0000005769149277148425774499857j) >>> appellf1('1.1', '0.3', '0.2+2j', '0.4', '0.2', 1.5+3j) (-0.1782604566893954897128702 + 0.002472407104546216117161499j) >>> appellf1(1,2,3,4,10,12) -0.07122993830066776374929313 For certain arguments, F1 reduces to an ordinary hypergeometric function:: >>> appellf1(1,2,3,5,0.5,0.25) 1.547902270302684019335555 >>> 4*hyp2f1(1,2,5,'1/3')/3 1.547902270302684019335555 >>> appellf1(1,2,3,4,0,1.5) (-1.717202506168937502740238 - 2.792526803190927323077905j) >>> hyp2f1(1,3,4,1.5) (-1.717202506168937502740238 - 2.792526803190927323077905j) The F1 function satisfies a system of partial differential equations:: >>> a,b1,b2,c,x,y = map(mpf, [1,0.5,0.25,1.125,0.25,-0.25]) >>> F = lambda x,y: appellf1(a,b1,b2,c,x,y) >>> chop(x*(1-x)*diff(F,(x,y),(2,0)) + ... y*(1-x)*diff(F,(x,y),(1,1)) + ... (c-(a+b1+1)*x)*diff(F,(x,y),(1,0)) - ... b1*y*diff(F,(x,y),(0,1)) - ... a*b1*F(x,y)) 0.0 >>> >>> chop(y*(1-y)*diff(F,(x,y),(0,2)) + ... x*(1-y)*diff(F,(x,y),(1,1)) + ... (c-(a+b2+1)*y)*diff(F,(x,y),(0,1)) - ... b2*x*diff(F,(x,y),(1,0)) - ... a*b2*F(x,y)) 0.0 The Appell F1 function allows for closed-form evaluation of various integrals, such as any integral of the form `\int x^r (x+a)^p (x+b)^q dx`:: >>> def integral(a,b,p,q,r,x1,x2): ... a,b,p,q,r,x1,x2 = map(mpmathify, [a,b,p,q,r,x1,x2]) ... f = lambda x: x**r * (x+a)**p * (x+b)**q ... def F(x): ... v = x**(r+1)/(r+1) * (a+x)**p * (b+x)**q ... v *= (1+x/a)**(-p) ... v *= (1+x/b)**(-q) ... v *= appellf1(r+1,-p,-q,2+r,-x/a,-x/b) ... return v ... print("Num. quad: %s" % quad(f, [x1,x2])) ... print("Appell F1: %s" % (F(x2)-F(x1))) ... >>> integral('1/5','4/3','-2','3','1/2',0,1) Num. quad: 9.073335358785776206576981 Appell F1: 9.073335358785776206576981 >>> integral('3/2','4/3','-2','3','1/2',0,1) Num. quad: 1.092829171999626454344678 Appell F1: 1.092829171999626454344678 >>> integral('3/2','4/3','-2','3','1/2',12,25) Num. quad: 1106.323225040235116498927 Appell F1: 1106.323225040235116498927 Also incomplete elliptic integrals fall into this category [1]:: >>> def E(z, m): ... if (pi/2).ae(z): ... return ellipe(m) ... return 2*round(re(z)/pi)*ellipe(m) + mpf(-1)**round(re(z)/pi)*\ ... sin(z)*appellf1(0.5,0.5,-0.5,1.5,sin(z)**2,m*sin(z)**2) ... >>> z, m = 1, 0.5 >>> E(z,m); quad(lambda t: sqrt(1-m*sin(t)**2), [0,pi/4,3*pi/4,z]) 0.9273298836244400669659042 0.9273298836244400669659042 >>> z, m = 3, 2 >>> E(z,m); quad(lambda t: sqrt(1-m*sin(t)**2), [0,pi/4,3*pi/4,z]) (1.057495752337234229715836 + 1.198140234735592207439922j) (1.057495752337234229715836 + 1.198140234735592207439922j) **References** 1. [WolframFunctions]_ http://functions.wolfram.com/EllipticIntegrals/EllipticE2/26/01/ 2. [SrivastavaKarlsson]_ 3. [CabralRosetti]_ 4. [Vidunas]_ 5. [Slater]_ """ angerj = r""" Gives the Anger function .. math :: \mathbf{J}_{\nu}(z) = \frac{1}{\pi} \int_0^{\pi} \cos(\nu t - z \sin t) dt which is an entire function of both the parameter `\nu` and the argument `z`. It solves the inhomogeneous Bessel differential equation .. math :: f''(z) + \frac{1}{z}f'(z) + \left(1-\frac{\nu^2}{z^2}\right) f(z) = \frac{(z-\nu)}{\pi z^2} \sin(\pi \nu). **Examples** Evaluation for real and complex parameter and argument:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> angerj(2,3) 0.4860912605858910769078311 >>> angerj(-3+4j, 2+5j) (-5033.358320403384472395612 + 585.8011892476145118551756j) >>> angerj(3.25, 1e6j) (4.630743639715893346570743e+434290 - 1.117960409887505906848456e+434291j) >>> angerj(-1.5, 1e6) 0.0002795719747073879393087011 The Anger function coincides with the Bessel J-function when `\nu` is an integer:: >>> angerj(1,3); besselj(1,3) 0.3390589585259364589255146 0.3390589585259364589255146 >>> angerj(1.5,3); besselj(1.5,3) 0.4088969848691080859328847 0.4777182150870917715515015 Verifying the differential equation:: >>> v,z = mpf(2.25), 0.75 >>> f = lambda z: angerj(v,z) >>> diff(f,z,2) + diff(f,z)/z + (1-(v/z)**2)*f(z) -0.6002108774380707130367995 >>> (z-v)/(pi*z**2) * sinpi(v) -0.6002108774380707130367995 Verifying the integral representation:: >>> angerj(v,z) 0.1145380759919333180900501 >>> quad(lambda t: cos(v*t-z*sin(t))/pi, [0,pi]) 0.1145380759919333180900501 **References** 1. [DLMF]_ section 11.10: Anger-Weber Functions """ webere = r""" Gives the Weber function .. math :: \mathbf{E}_{\nu}(z) = \frac{1}{\pi} \int_0^{\pi} \sin(\nu t - z \sin t) dt which is an entire function of both the parameter `\nu` and the argument `z`. It solves the inhomogeneous Bessel differential equation .. math :: f''(z) + \frac{1}{z}f'(z) + \left(1-\frac{\nu^2}{z^2}\right) f(z) = -\frac{1}{\pi z^2} (z+\nu+(z-\nu)\cos(\pi \nu)). **Examples** Evaluation for real and complex parameter and argument:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> webere(2,3) -0.1057668973099018425662646 >>> webere(-3+4j, 2+5j) (-585.8081418209852019290498 - 5033.314488899926921597203j) >>> webere(3.25, 1e6j) (-1.117960409887505906848456e+434291 - 4.630743639715893346570743e+434290j) >>> webere(3.25, 1e6) -0.00002812518265894315604914453 Up to addition of a rational function of `z`, the Weber function coincides with the Struve H-function when `\nu` is an integer:: >>> webere(1,3); 2/pi-struveh(1,3) -0.3834897968188690177372881 -0.3834897968188690177372881 >>> webere(5,3); 26/(35*pi)-struveh(5,3) 0.2009680659308154011878075 0.2009680659308154011878075 Verifying the differential equation:: >>> v,z = mpf(2.25), 0.75 >>> f = lambda z: webere(v,z) >>> diff(f,z,2) + diff(f,z)/z + (1-(v/z)**2)*f(z) -1.097441848875479535164627 >>> -(z+v+(z-v)*cospi(v))/(pi*z**2) -1.097441848875479535164627 Verifying the integral representation:: >>> webere(v,z) 0.1486507351534283744485421 >>> quad(lambda t: sin(v*t-z*sin(t))/pi, [0,pi]) 0.1486507351534283744485421 **References** 1. [DLMF]_ section 11.10: Anger-Weber Functions """ lommels1 = r""" Gives the Lommel function `s_{\mu,\nu}` or `s^{(1)}_{\mu,\nu}` .. math :: s_{\mu,\nu}(z) = \frac{z^{\mu+1}}{(\mu-\nu+1)(\mu+\nu+1)} \,_1F_2\left(1; \frac{\mu-\nu+3}{2}, \frac{\mu+\nu+3}{2}; -\frac{z^2}{4} \right) which solves the inhomogeneous Bessel equation .. math :: z^2 f''(z) + z f'(z) + (z^2-\nu^2) f(z) = z^{\mu+1}. A second solution is given by :func:`~mpmath.lommels2`. **Plots** .. literalinclude :: /plots/lommels1.py .. image :: /plots/lommels1.png **Examples** An integral representation:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> u,v,z = 0.25, 0.125, mpf(0.75) >>> lommels1(u,v,z) 0.4276243877565150372999126 >>> (bessely(v,z)*quad(lambda t: t**u*besselj(v,t), [0,z]) - \ ... besselj(v,z)*quad(lambda t: t**u*bessely(v,t), [0,z]))*(pi/2) 0.4276243877565150372999126 A special value:: >>> lommels1(v,v,z) 0.5461221367746048054932553 >>> gamma(v+0.5)*sqrt(pi)*power(2,v-1)*struveh(v,z) 0.5461221367746048054932553 Verifying the differential equation:: >>> f = lambda z: lommels1(u,v,z) >>> z**2*diff(f,z,2) + z*diff(f,z) + (z**2-v**2)*f(z) 0.6979536443265746992059141 >>> z**(u+1) 0.6979536443265746992059141 **References** 1. [GradshteynRyzhik]_ 2. [Weisstein]_ http://mathworld.wolfram.com/LommelFunction.html """ lommels2 = r""" Gives the second Lommel function `S_{\mu,\nu}` or `s^{(2)}_{\mu,\nu}` .. math :: S_{\mu,\nu}(z) = s_{\mu,\nu}(z) + 2^{\mu-1} \Gamma\left(\tfrac{1}{2}(\mu-\nu+1)\right) \Gamma\left(\tfrac{1}{2}(\mu+\nu+1)\right) \times \left[\sin(\tfrac{1}{2}(\mu-\nu)\pi) J_{\nu}(z) - \cos(\tfrac{1}{2}(\mu-\nu)\pi) Y_{\nu}(z) \right] which solves the same differential equation as :func:`~mpmath.lommels1`. **Plots** .. literalinclude :: /plots/lommels2.py .. image :: /plots/lommels2.png **Examples** For large `|z|`, `S_{\mu,\nu} \sim z^{\mu-1}`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> lommels2(10,2,30000) 1.968299831601008419949804e+40 >>> power(30000,9) 1.9683e+40 A special value:: >>> u,v,z = 0.5, 0.125, mpf(0.75) >>> lommels2(v,v,z) 0.9589683199624672099969765 >>> (struveh(v,z)-bessely(v,z))*power(2,v-1)*sqrt(pi)*gamma(v+0.5) 0.9589683199624672099969765 Verifying the differential equation:: >>> f = lambda z: lommels2(u,v,z) >>> z**2*diff(f,z,2) + z*diff(f,z) + (z**2-v**2)*f(z) 0.6495190528383289850727924 >>> z**(u+1) 0.6495190528383289850727924 **References** 1. [GradshteynRyzhik]_ 2. [Weisstein]_ http://mathworld.wolfram.com/LommelFunction.html """ appellf2 = r""" Gives the Appell F2 hypergeometric function of two variables .. math :: F_2(a,b_1,b_2,c_1,c_2,x,y) = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} \frac{(a)_{m+n} (b_1)_m (b_2)_n}{(c_1)_m (c_2)_n} \frac{x^m y^n}{m! n!}. The series is generally absolutely convergent for `|x| + |y| < 1`. **Examples** Evaluation for real and complex arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> appellf2(1,2,3,4,5,0.25,0.125) 1.257417193533135344785602 >>> appellf2(1,-3,-4,2,3,2,3) -42.8 >>> appellf2(0.5,0.25,-0.25,2,3,0.25j,0.25) (0.9880539519421899867041719 + 0.01497616165031102661476978j) >>> chop(appellf2(1,1+j,1-j,3j,-3j,0.25,0.25)) 1.201311219287411337955192 >>> appellf2(1,1,1,4,6,0.125,16) (-0.09455532250274744282125152 - 0.7647282253046207836769297j) A transformation formula:: >>> a,b1,b2,c1,c2,x,y = map(mpf, [1,2,0.5,0.25,1.625,-0.125,0.125]) >>> appellf2(a,b1,b2,c1,c2,x,y) 0.2299211717841180783309688 >>> (1-x)**(-a)*appellf2(a,c1-b1,b2,c1,c2,x/(x-1),y/(1-x)) 0.2299211717841180783309688 A system of partial differential equations satisfied by F2:: >>> a,b1,b2,c1,c2,x,y = map(mpf, [1,0.5,0.25,1.125,1.5,0.0625,-0.0625]) >>> F = lambda x,y: appellf2(a,b1,b2,c1,c2,x,y) >>> chop(x*(1-x)*diff(F,(x,y),(2,0)) - ... x*y*diff(F,(x,y),(1,1)) + ... (c1-(a+b1+1)*x)*diff(F,(x,y),(1,0)) - ... b1*y*diff(F,(x,y),(0,1)) - ... a*b1*F(x,y)) 0.0 >>> chop(y*(1-y)*diff(F,(x,y),(0,2)) - ... x*y*diff(F,(x,y),(1,1)) + ... (c2-(a+b2+1)*y)*diff(F,(x,y),(0,1)) - ... b2*x*diff(F,(x,y),(1,0)) - ... a*b2*F(x,y)) 0.0 **References** See references for :func:`~mpmath.appellf1`. """ appellf3 = r""" Gives the Appell F3 hypergeometric function of two variables .. math :: F_3(a_1,a_2,b_1,b_2,c,x,y) = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} \frac{(a_1)_m (a_2)_n (b_1)_m (b_2)_n}{(c)_{m+n}} \frac{x^m y^n}{m! n!}. The series is generally absolutely convergent for `|x| < 1, |y| < 1`. **Examples** Evaluation for various parameters and variables:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> appellf3(1,2,3,4,5,0.5,0.25) 2.221557778107438938158705 >>> appellf3(1,2,3,4,5,6,0); hyp2f1(1,3,5,6) (-0.5189554589089861284537389 - 0.1454441043328607980769742j) (-0.5189554589089861284537389 - 0.1454441043328607980769742j) >>> appellf3(1,-2,-3,1,1,4,6) -17.4 >>> appellf3(1,2,-3,1,1,4,6) (17.7876136773677356641825 + 19.54768762233649126154534j) >>> appellf3(1,2,-3,1,1,6,4) (85.02054175067929402953645 + 148.4402528821177305173599j) >>> chop(appellf3(1+j,2,1-j,2,3,0.25,0.25)) 1.719992169545200286696007 Many transformations and evaluations for special combinations of the parameters are possible, e.g.: >>> a,b,c,x,y = map(mpf, [0.5,0.25,0.125,0.125,-0.125]) >>> appellf3(a,c-a,b,c-b,c,x,y) 1.093432340896087107444363 >>> (1-y)**(a+b-c)*hyp2f1(a,b,c,x+y-x*y) 1.093432340896087107444363 >>> x**2*appellf3(1,1,1,1,3,x,-x) 0.01568646277445385390945083 >>> polylog(2,x**2) 0.01568646277445385390945083 >>> a1,a2,b1,b2,c,x = map(mpf, [0.5,0.25,0.125,0.5,4.25,0.125]) >>> appellf3(a1,a2,b1,b2,c,x,1) 1.03947361709111140096947 >>> gammaprod([c,c-a2-b2],[c-a2,c-b2])*hyp3f2(a1,b1,c-a2-b2,c-a2,c-b2,x) 1.03947361709111140096947 The Appell F3 function satisfies a pair of partial differential equations:: >>> a1,a2,b1,b2,c,x,y = map(mpf, [0.5,0.25,0.125,0.5,0.625,0.0625,-0.0625]) >>> F = lambda x,y: appellf3(a1,a2,b1,b2,c,x,y) >>> chop(x*(1-x)*diff(F,(x,y),(2,0)) + ... y*diff(F,(x,y),(1,1)) + ... (c-(a1+b1+1)*x)*diff(F,(x,y),(1,0)) - ... a1*b1*F(x,y)) 0.0 >>> chop(y*(1-y)*diff(F,(x,y),(0,2)) + ... x*diff(F,(x,y),(1,1)) + ... (c-(a2+b2+1)*y)*diff(F,(x,y),(0,1)) - ... a2*b2*F(x,y)) 0.0 **References** See references for :func:`~mpmath.appellf1`. """ appellf4 = r""" Gives the Appell F4 hypergeometric function of two variables .. math :: F_4(a,b,c_1,c_2,x,y) = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} \frac{(a)_{m+n} (b)_{m+n}}{(c_1)_m (c_2)_n} \frac{x^m y^n}{m! n!}. The series is generally absolutely convergent for `\sqrt{|x|} + \sqrt{|y|} < 1`. **Examples** Evaluation for various parameters and arguments:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> appellf4(1,1,2,2,0.25,0.125) 1.286182069079718313546608 >>> appellf4(-2,-3,4,5,4,5) 34.8 >>> appellf4(5,4,2,3,0.25j,-0.125j) (-0.2585967215437846642163352 + 2.436102233553582711818743j) Reduction to `\,_2F_1` in a special case:: >>> a,b,c,x,y = map(mpf, [0.5,0.25,0.125,0.125,-0.125]) >>> appellf4(a,b,c,a+b-c+1,x*(1-y),y*(1-x)) 1.129143488466850868248364 >>> hyp2f1(a,b,c,x)*hyp2f1(a,b,a+b-c+1,y) 1.129143488466850868248364 A system of partial differential equations satisfied by F4:: >>> a,b,c1,c2,x,y = map(mpf, [1,0.5,0.25,1.125,0.0625,-0.0625]) >>> F = lambda x,y: appellf4(a,b,c1,c2,x,y) >>> chop(x*(1-x)*diff(F,(x,y),(2,0)) - ... y**2*diff(F,(x,y),(0,2)) - ... 2*x*y*diff(F,(x,y),(1,1)) + ... (c1-(a+b+1)*x)*diff(F,(x,y),(1,0)) - ... ((a+b+1)*y)*diff(F,(x,y),(0,1)) - ... a*b*F(x,y)) 0.0 >>> chop(y*(1-y)*diff(F,(x,y),(0,2)) - ... x**2*diff(F,(x,y),(2,0)) - ... 2*x*y*diff(F,(x,y),(1,1)) + ... (c2-(a+b+1)*y)*diff(F,(x,y),(0,1)) - ... ((a+b+1)*x)*diff(F,(x,y),(1,0)) - ... a*b*F(x,y)) 0.0 **References** See references for :func:`~mpmath.appellf1`. """ zeta = r""" Computes the Riemann zeta function .. math :: \zeta(s) = 1+\frac{1}{2^s}+\frac{1}{3^s}+\frac{1}{4^s}+\ldots or, with `a \ne 1`, the more general Hurwitz zeta function .. math :: \zeta(s,a) = \sum_{k=0}^\infty \frac{1}{(a+k)^s}. Optionally, ``zeta(s, a, n)`` computes the `n`-th derivative with respect to `s`, .. math :: \zeta^{(n)}(s,a) = (-1)^n \sum_{k=0}^\infty \frac{\log^n(a+k)}{(a+k)^s}. Although these series only converge for `\Re(s) > 1`, the Riemann and Hurwitz zeta functions are defined through analytic continuation for arbitrary complex `s \ne 1` (`s = 1` is a pole). The implementation uses three algorithms: the Borwein algorithm for the Riemann zeta function when `s` is close to the real line; the Riemann-Siegel formula for the Riemann zeta function when `s` is large imaginary, and Euler-Maclaurin summation in all other cases. The reflection formula for `\Re(s) < 0` is implemented in some cases. The algorithm can be chosen with ``method = 'borwein'``, ``method='riemann-siegel'`` or ``method = 'euler-maclaurin'``. The parameter `a` is usually a rational number `a = p/q`, and may be specified as such by passing an integer tuple `(p, q)`. Evaluation is supported for arbitrary complex `a`, but may be slow and/or inaccurate when `\Re(s) < 0` for nonrational `a` or when computing derivatives. **Examples** Some values of the Riemann zeta function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> zeta(2); pi**2 / 6 1.644934066848226436472415 1.644934066848226436472415 >>> zeta(0) -0.5 >>> zeta(-1) -0.08333333333333333333333333 >>> zeta(-2) 0.0 For large positive `s`, `\zeta(s)` rapidly approaches 1:: >>> zeta(50) 1.000000000000000888178421 >>> zeta(100) 1.0 >>> zeta(inf) 1.0 >>> 1-sum((zeta(k)-1)/k for k in range(2,85)); +euler 0.5772156649015328606065121 0.5772156649015328606065121 >>> nsum(lambda k: zeta(k)-1, [2, inf]) 1.0 Evaluation is supported for complex `s` and `a`: >>> zeta(-3+4j) (-0.03373057338827757067584698 + 0.2774499251557093745297677j) >>> zeta(2+3j, -1+j) (389.6841230140842816370741 + 295.2674610150305334025962j) The Riemann zeta function has so-called nontrivial zeros on the critical line `s = 1/2 + it`:: >>> findroot(zeta, 0.5+14j); zetazero(1) (0.5 + 14.13472514173469379045725j) (0.5 + 14.13472514173469379045725j) >>> findroot(zeta, 0.5+21j); zetazero(2) (0.5 + 21.02203963877155499262848j) (0.5 + 21.02203963877155499262848j) >>> findroot(zeta, 0.5+25j); zetazero(3) (0.5 + 25.01085758014568876321379j) (0.5 + 25.01085758014568876321379j) >>> chop(zeta(zetazero(10))) 0.0 Evaluation on and near the critical line is supported for large heights `t` by means of the Riemann-Siegel formula (currently for `a = 1`, `n \le 4`):: >>> zeta(0.5+100000j) (1.073032014857753132114076 + 5.780848544363503984261041j) >>> zeta(0.75+1000000j) (0.9535316058375145020351559 + 0.9525945894834273060175651j) >>> zeta(0.5+10000000j) (11.45804061057709254500227 - 8.643437226836021723818215j) >>> zeta(0.5+100000000j, derivative=1) (51.12433106710194942681869 + 43.87221167872304520599418j) >>> zeta(0.5+100000000j, derivative=2) (-444.2760822795430400549229 - 896.3789978119185981665403j) >>> zeta(0.5+100000000j, derivative=3) (3230.72682687670422215339 + 14374.36950073615897616781j) >>> zeta(0.5+100000000j, derivative=4) (-11967.35573095046402130602 - 218945.7817789262839266148j) >>> zeta(1+10000000j) # off the line (2.859846483332530337008882 + 0.491808047480981808903986j) >>> zeta(1+10000000j, derivative=1) (-4.333835494679647915673205 - 0.08405337962602933636096103j) >>> zeta(1+10000000j, derivative=4) (453.2764822702057701894278 - 581.963625832768189140995j) For investigation of the zeta function zeros, the Riemann-Siegel Z-function is often more convenient than working with the Riemann zeta function directly (see :func:`~mpmath.siegelz`). Some values of the Hurwitz zeta function:: >>> zeta(2, 3); -5./4 + pi**2/6 0.3949340668482264364724152 0.3949340668482264364724152 >>> zeta(2, (3,4)); pi**2 - 8*catalan 2.541879647671606498397663 2.541879647671606498397663 For positive integer values of `s`, the Hurwitz zeta function is equivalent to a polygamma function (except for a normalizing factor):: >>> zeta(4, (1,5)); psi(3, '1/5')/6 625.5408324774542966919938 625.5408324774542966919938 Evaluation of derivatives:: >>> zeta(0, 3+4j, 1); loggamma(3+4j) - ln(2*pi)/2 (-2.675565317808456852310934 + 4.742664438034657928194889j) (-2.675565317808456852310934 + 4.742664438034657928194889j) >>> zeta(2, 1, 20) 2432902008176640000.000242 >>> zeta(3+4j, 5.5+2j, 4) (-0.140075548947797130681075 - 0.3109263360275413251313634j) >>> zeta(0.5+100000j, 1, 4) (-10407.16081931495861539236 + 13777.78669862804508537384j) >>> zeta(-100+0.5j, (1,3), derivative=4) (4.007180821099823942702249e+79 + 4.916117957092593868321778e+78j) Generating a Taylor series at `s = 2` using derivatives:: >>> for k in range(11): print("%s * (s-2)^%i" % (zeta(2,1,k)/fac(k), k)) ... 1.644934066848226436472415 * (s-2)^0 -0.9375482543158437537025741 * (s-2)^1 0.9946401171494505117104293 * (s-2)^2 -1.000024300473840810940657 * (s-2)^3 1.000061933072352565457512 * (s-2)^4 -1.000006869443931806408941 * (s-2)^5 1.000000173233769531820592 * (s-2)^6 -0.9999999569989868493432399 * (s-2)^7 0.9999999937218844508684206 * (s-2)^8 -0.9999999996355013916608284 * (s-2)^9 1.000000000004610645020747 * (s-2)^10 Evaluation at zero and for negative integer `s`:: >>> zeta(0, 10) -9.5 >>> zeta(-2, (2,3)); mpf(1)/81 0.01234567901234567901234568 0.01234567901234567901234568 >>> zeta(-3+4j, (5,4)) (0.2899236037682695182085988 + 0.06561206166091757973112783j) >>> zeta(-3.25, 1/pi) -0.0005117269627574430494396877 >>> zeta(-3.5, pi, 1) 11.156360390440003294709 >>> zeta(-100.5, (8,3)) -4.68162300487989766727122e+77 >>> zeta(-10.5, (-8,3)) (-0.01521913704446246609237979 + 29907.72510874248161608216j) >>> zeta(-1000.5, (-8,3)) (1.031911949062334538202567e+1770 + 1.519555750556794218804724e+426j) >>> zeta(-1+j, 3+4j) (-16.32988355630802510888631 - 22.17706465801374033261383j) >>> zeta(-1+j, 3+4j, 2) (32.48985276392056641594055 - 51.11604466157397267043655j) >>> diff(lambda s: zeta(s, 3+4j), -1+j, 2) (32.48985276392056641594055 - 51.11604466157397267043655j) **References** 1. http://mathworld.wolfram.com/RiemannZetaFunction.html 2. http://mathworld.wolfram.com/HurwitzZetaFunction.html 3. http://www.cecm.sfu.ca/personal/pborwein/PAPERS/P155.pdf """ dirichlet = r""" Evaluates the Dirichlet L-function .. math :: L(s,\chi) = \sum_{k=1}^\infty \frac{\chi(k)}{k^s}. where `\chi` is a periodic sequence of length `q` which should be supplied in the form of a list `[\chi(0), \chi(1), \ldots, \chi(q-1)]`. Strictly, `\chi` should be a Dirichlet character, but any periodic sequence will work. For example, ``dirichlet(s, [1])`` gives the ordinary Riemann zeta function and ``dirichlet(s, [-1,1])`` gives the alternating zeta function (Dirichlet eta function). Also the derivative with respect to `s` (currently only a first derivative) can be evaluated. **Examples** The ordinary Riemann zeta function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> dirichlet(3, [1]); zeta(3) 1.202056903159594285399738 1.202056903159594285399738 >>> dirichlet(1, [1]) +inf The alternating zeta function:: >>> dirichlet(1, [-1,1]); ln(2) 0.6931471805599453094172321 0.6931471805599453094172321 The following defines the Dirichlet beta function `\beta(s) = \sum_{k=0}^\infty \frac{(-1)^k}{(2k+1)^s}` and verifies several values of this function:: >>> B = lambda s, d=0: dirichlet(s, [0, 1, 0, -1], d) >>> B(0); 1./2 0.5 0.5 >>> B(1); pi/4 0.7853981633974483096156609 0.7853981633974483096156609 >>> B(2); +catalan 0.9159655941772190150546035 0.9159655941772190150546035 >>> B(2,1); diff(B, 2) 0.08158073611659279510291217 0.08158073611659279510291217 >>> B(-1,1); 2*catalan/pi 0.5831218080616375602767689 0.5831218080616375602767689 >>> B(0,1); log(gamma(0.25)**2/(2*pi*sqrt(2))) 0.3915943927068367764719453 0.3915943927068367764719454 >>> B(1,1); 0.25*pi*(euler+2*ln2+3*ln(pi)-4*ln(gamma(0.25))) 0.1929013167969124293631898 0.1929013167969124293631898 A custom L-series of period 3:: >>> dirichlet(2, [2,0,1]) 0.7059715047839078092146831 >>> 2*nsum(lambda k: (3*k)**-2, [1,inf]) + \ ... nsum(lambda k: (3*k+2)**-2, [0,inf]) 0.7059715047839078092146831 """ coulombf = r""" Calculates the regular Coulomb wave function .. math :: F_l(\eta,z) = C_l(\eta) z^{l+1} e^{-iz} \,_1F_1(l+1-i\eta, 2l+2, 2iz) where the normalization constant `C_l(\eta)` is as calculated by :func:`~mpmath.coulombc`. This function solves the differential equation .. math :: f''(z) + \left(1-\frac{2\eta}{z}-\frac{l(l+1)}{z^2}\right) f(z) = 0. A second linearly independent solution is given by the irregular Coulomb wave function `G_l(\eta,z)` (see :func:`~mpmath.coulombg`) and thus the general solution is `f(z) = C_1 F_l(\eta,z) + C_2 G_l(\eta,z)` for arbitrary constants `C_1`, `C_2`. Physically, the Coulomb wave functions give the radial solution to the Schrodinger equation for a point particle in a `1/z` potential; `z` is then the radius and `l`, `\eta` are quantum numbers. The Coulomb wave functions with real parameters are defined in Abramowitz & Stegun, section 14. However, all parameters are permitted to be complex in this implementation (see references). **Plots** .. literalinclude :: /plots/coulombf.py .. image :: /plots/coulombf.png .. literalinclude :: /plots/coulombf_c.py .. image :: /plots/coulombf_c.png **Examples** Evaluation is supported for arbitrary magnitudes of `z`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> coulombf(2, 1.5, 3.5) 0.4080998961088761187426445 >>> coulombf(-2, 1.5, 3.5) 0.7103040849492536747533465 >>> coulombf(2, 1.5, '1e-10') 4.143324917492256448770769e-33 >>> coulombf(2, 1.5, 1000) 0.4482623140325567050716179 >>> coulombf(2, 1.5, 10**10) -0.066804196437694360046619 Verifying the differential equation:: >>> l, eta, z = 2, 3, mpf(2.75) >>> A, B = 1, 2 >>> f = lambda z: A*coulombf(l,eta,z) + B*coulombg(l,eta,z) >>> chop(diff(f,z,2) + (1-2*eta/z - l*(l+1)/z**2)*f(z)) 0.0 A Wronskian relation satisfied by the Coulomb wave functions:: >>> l = 2 >>> eta = 1.5 >>> F = lambda z: coulombf(l,eta,z) >>> G = lambda z: coulombg(l,eta,z) >>> for z in [3.5, -1, 2+3j]: ... chop(diff(F,z)*G(z) - F(z)*diff(G,z)) ... 1.0 1.0 1.0 Another Wronskian relation:: >>> F = coulombf >>> G = coulombg >>> for z in [3.5, -1, 2+3j]: ... chop(F(l-1,eta,z)*G(l,eta,z)-F(l,eta,z)*G(l-1,eta,z) - l/sqrt(l**2+eta**2)) ... 0.0 0.0 0.0 An integral identity connecting the regular and irregular wave functions:: >>> l, eta, z = 4+j, 2-j, 5+2j >>> coulombf(l,eta,z) + j*coulombg(l,eta,z) (0.7997977752284033239714479 + 0.9294486669502295512503127j) >>> g = lambda t: exp(-t)*t**(l-j*eta)*(t+2*j*z)**(l+j*eta) >>> j*exp(-j*z)*z**(-l)/fac(2*l+1)/coulombc(l,eta)*quad(g, [0,inf]) (0.7997977752284033239714479 + 0.9294486669502295512503127j) Some test case with complex parameters, taken from Michel [2]:: >>> mp.dps = 15 >>> coulombf(1+0.1j, 50+50j, 100.156) (-1.02107292320897e+15 - 2.83675545731519e+15j) >>> coulombg(1+0.1j, 50+50j, 100.156) (2.83675545731519e+15 - 1.02107292320897e+15j) >>> coulombf(1e-5j, 10+1e-5j, 0.1+1e-6j) (4.30566371247811e-14 - 9.03347835361657e-19j) >>> coulombg(1e-5j, 10+1e-5j, 0.1+1e-6j) (778709182061.134 + 18418936.2660553j) The following reproduces a table in Abramowitz & Stegun, at twice the precision:: >>> mp.dps = 10 >>> eta = 2; z = 5 >>> for l in [5, 4, 3, 2, 1, 0]: ... print("%s %s %s" % (l, coulombf(l,eta,z), ... diff(lambda z: coulombf(l,eta,z), z))) ... 5 0.09079533488 0.1042553261 4 0.2148205331 0.2029591779 3 0.4313159311 0.320534053 2 0.7212774133 0.3952408216 1 0.9935056752 0.3708676452 0 1.143337392 0.2937960375 **References** 1. I.J. Thompson & A.R. Barnett, "Coulomb and Bessel Functions of Complex Arguments and Order", J. Comp. Phys., vol 64, no. 2, June 1986. 2. N. Michel, "Precise Coulomb wave functions for a wide range of complex `l`, `\eta` and `z`", http://arxiv.org/abs/physics/0702051v1 """ coulombg = r""" Calculates the irregular Coulomb wave function .. math :: G_l(\eta,z) = \frac{F_l(\eta,z) \cos(\chi) - F_{-l-1}(\eta,z)}{\sin(\chi)} where `\chi = \sigma_l - \sigma_{-l-1} - (l+1/2) \pi` and `\sigma_l(\eta) = (\ln \Gamma(1+l+i\eta)-\ln \Gamma(1+l-i\eta))/(2i)`. See :func:`~mpmath.coulombf` for additional information. **Plots** .. literalinclude :: /plots/coulombg.py .. image :: /plots/coulombg.png .. literalinclude :: /plots/coulombg_c.py .. image :: /plots/coulombg_c.png **Examples** Evaluation is supported for arbitrary magnitudes of `z`:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> coulombg(-2, 1.5, 3.5) 1.380011900612186346255524 >>> coulombg(2, 1.5, 3.5) 1.919153700722748795245926 >>> coulombg(-2, 1.5, '1e-10') 201126715824.7329115106793 >>> coulombg(-2, 1.5, 1000) 0.1802071520691149410425512 >>> coulombg(-2, 1.5, 10**10) 0.652103020061678070929794 The following reproduces a table in Abramowitz & Stegun, at twice the precision:: >>> mp.dps = 10 >>> eta = 2; z = 5 >>> for l in [1, 2, 3, 4, 5]: ... print("%s %s %s" % (l, coulombg(l,eta,z), ... -diff(lambda z: coulombg(l,eta,z), z))) ... 1 1.08148276 0.6028279961 2 1.496877075 0.5661803178 3 2.048694714 0.7959909551 4 3.09408669 1.731802374 5 5.629840456 4.549343289 Evaluation close to the singularity at `z = 0`:: >>> mp.dps = 15 >>> coulombg(0,10,1) 3088184933.67358 >>> coulombg(0,10,'1e-10') 5554866000719.8 >>> coulombg(0,10,'1e-100') 5554866221524.1 Evaluation with a half-integer value for `l`:: >>> coulombg(1.5, 1, 10) 0.852320038297334 """ coulombc = r""" Gives the normalizing Gamow constant for Coulomb wave functions, .. math :: C_l(\eta) = 2^l \exp\left(-\pi \eta/2 + [\ln \Gamma(1+l+i\eta) + \ln \Gamma(1+l-i\eta)]/2 - \ln \Gamma(2l+2)\right), where the log gamma function with continuous imaginary part away from the negative half axis (see :func:`~mpmath.loggamma`) is implied. This function is used internally for the calculation of Coulomb wave functions, and automatically cached to make multiple evaluations with fixed `l`, `\eta` fast. """ ellipfun = r""" Computes any of the Jacobi elliptic functions, defined in terms of Jacobi theta functions as .. math :: \mathrm{sn}(u,m) = \frac{\vartheta_3(0,q)}{\vartheta_2(0,q)} \frac{\vartheta_1(t,q)}{\vartheta_4(t,q)} \mathrm{cn}(u,m) = \frac{\vartheta_4(0,q)}{\vartheta_2(0,q)} \frac{\vartheta_2(t,q)}{\vartheta_4(t,q)} \mathrm{dn}(u,m) = \frac{\vartheta_4(0,q)}{\vartheta_3(0,q)} \frac{\vartheta_3(t,q)}{\vartheta_4(t,q)}, or more generally computes a ratio of two such functions. Here `t = u/\vartheta_3(0,q)^2`, and `q = q(m)` denotes the nome (see :func:`~mpmath.nome`). Optionally, you can specify the nome directly instead of `m` by passing ``q=``, or you can directly specify the elliptic parameter `k` with ``k=``. The first argument should be a two-character string specifying the function using any combination of ``'s'``, ``'c'``, ``'d'``, ``'n'``. These letters respectively denote the basic functions `\mathrm{sn}(u,m)`, `\mathrm{cn}(u,m)`, `\mathrm{dn}(u,m)`, and `1`. The identifier specifies the ratio of two such functions. For example, ``'ns'`` identifies the function .. math :: \mathrm{ns}(u,m) = \frac{1}{\mathrm{sn}(u,m)} and ``'cd'`` identifies the function .. math :: \mathrm{cd}(u,m) = \frac{\mathrm{cn}(u,m)}{\mathrm{dn}(u,m)}. If called with only the first argument, a function object evaluating the chosen function for given arguments is returned. **Examples** Basic evaluation:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> ellipfun('cd', 3.5, 0.5) -0.9891101840595543931308394 >>> ellipfun('cd', 3.5, q=0.25) 0.07111979240214668158441418 The sn-function is doubly periodic in the complex plane with periods `4 K(m)` and `2 i K(1-m)` (see :func:`~mpmath.ellipk`):: >>> sn = ellipfun('sn') >>> sn(2, 0.25) 0.9628981775982774425751399 >>> sn(2+4*ellipk(0.25), 0.25) 0.9628981775982774425751399 >>> chop(sn(2+2*j*ellipk(1-0.25), 0.25)) 0.9628981775982774425751399 The cn-function is doubly periodic with periods `4 K(m)` and `4 i K(1-m)`:: >>> cn = ellipfun('cn') >>> cn(2, 0.25) -0.2698649654510865792581416 >>> cn(2+4*ellipk(0.25), 0.25) -0.2698649654510865792581416 >>> chop(cn(2+4*j*ellipk(1-0.25), 0.25)) -0.2698649654510865792581416 The dn-function is doubly periodic with periods `2 K(m)` and `4 i K(1-m)`:: >>> dn = ellipfun('dn') >>> dn(2, 0.25) 0.8764740583123262286931578 >>> dn(2+2*ellipk(0.25), 0.25) 0.8764740583123262286931578 >>> chop(dn(2+4*j*ellipk(1-0.25), 0.25)) 0.8764740583123262286931578 """ jtheta = r""" Computes the Jacobi theta function `\vartheta_n(z, q)`, where `n = 1, 2, 3, 4`, defined by the infinite series: .. math :: \vartheta_1(z,q) = 2 q^{1/4} \sum_{n=0}^{\infty} (-1)^n q^{n^2+n\,} \sin((2n+1)z) \vartheta_2(z,q) = 2 q^{1/4} \sum_{n=0}^{\infty} q^{n^{2\,} + n} \cos((2n+1)z) \vartheta_3(z,q) = 1 + 2 \sum_{n=1}^{\infty} q^{n^2\,} \cos(2 n z) \vartheta_4(z,q) = 1 + 2 \sum_{n=1}^{\infty} (-q)^{n^2\,} \cos(2 n z) The theta functions are functions of two variables: * `z` is the *argument*, an arbitrary real or complex number * `q` is the *nome*, which must be a real or complex number in the unit disk (i.e. `|q| < 1`). For `|q| \ll 1`, the series converge very quickly, so the Jacobi theta functions can efficiently be evaluated to high precision. The compact notations `\vartheta_n(q) = \vartheta_n(0,q)` and `\vartheta_n = \vartheta_n(0,q)` are also frequently encountered. Finally, Jacobi theta functions are frequently considered as functions of the half-period ratio `\tau` and then usually denoted by `\vartheta_n(z|\tau)`. Optionally, ``jtheta(n, z, q, derivative=d)`` with `d > 0` computes a `d`-th derivative with respect to `z`. **Examples and basic properties** Considered as functions of `z`, the Jacobi theta functions may be viewed as generalizations of the ordinary trigonometric functions cos and sin. They are periodic functions:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> jtheta(1, 0.25, '0.2') 0.2945120798627300045053104 >>> jtheta(1, 0.25 + 2*pi, '0.2') 0.2945120798627300045053104 Indeed, the series defining the theta functions are essentially trigonometric Fourier series. The coefficients can be retrieved using :func:`~mpmath.fourier`:: >>> mp.dps = 10 >>> nprint(fourier(lambda x: jtheta(2, x, 0.5), [-pi, pi], 4)) ([0.0, 1.68179, 0.0, 0.420448, 0.0], [0.0, 0.0, 0.0, 0.0, 0.0]) The Jacobi theta functions are also so-called quasiperiodic functions of `z` and `\tau`, meaning that for fixed `\tau`, `\vartheta_n(z, q)` and `\vartheta_n(z+\pi \tau, q)` are the same except for an exponential factor:: >>> mp.dps = 25 >>> tau = 3*j/10 >>> q = exp(pi*j*tau) >>> z = 10 >>> jtheta(4, z+tau*pi, q) (-0.682420280786034687520568 + 1.526683999721399103332021j) >>> -exp(-2*j*z)/q * jtheta(4, z, q) (-0.682420280786034687520568 + 1.526683999721399103332021j) The Jacobi theta functions satisfy a huge number of other functional equations, such as the following identity (valid for any `q`):: >>> q = mpf(3)/10 >>> jtheta(3,0,q)**4 6.823744089352763305137427 >>> jtheta(2,0,q)**4 + jtheta(4,0,q)**4 6.823744089352763305137427 Extensive listings of identities satisfied by the Jacobi theta functions can be found in standard reference works. The Jacobi theta functions are related to the gamma function for special arguments:: >>> jtheta(3, 0, exp(-pi)) 1.086434811213308014575316 >>> pi**(1/4.) / gamma(3/4.) 1.086434811213308014575316 :func:`~mpmath.jtheta` supports arbitrary precision evaluation and complex arguments:: >>> mp.dps = 50 >>> jtheta(4, sqrt(2), 0.5) 2.0549510717571539127004115835148878097035750653737 >>> mp.dps = 25 >>> jtheta(4, 1+2j, (1+j)/5) (7.180331760146805926356634 - 1.634292858119162417301683j) Evaluation of derivatives:: >>> mp.dps = 25 >>> jtheta(1, 7, 0.25, 1); diff(lambda z: jtheta(1, z, 0.25), 7) 1.209857192844475388637236 1.209857192844475388637236 >>> jtheta(1, 7, 0.25, 2); diff(lambda z: jtheta(1, z, 0.25), 7, 2) -0.2598718791650217206533052 -0.2598718791650217206533052 >>> jtheta(2, 7, 0.25, 1); diff(lambda z: jtheta(2, z, 0.25), 7) -1.150231437070259644461474 -1.150231437070259644461474 >>> jtheta(2, 7, 0.25, 2); diff(lambda z: jtheta(2, z, 0.25), 7, 2) -0.6226636990043777445898114 -0.6226636990043777445898114 >>> jtheta(3, 7, 0.25, 1); diff(lambda z: jtheta(3, z, 0.25), 7) -0.9990312046096634316587882 -0.9990312046096634316587882 >>> jtheta(3, 7, 0.25, 2); diff(lambda z: jtheta(3, z, 0.25), 7, 2) -0.1530388693066334936151174 -0.1530388693066334936151174 >>> jtheta(4, 7, 0.25, 1); diff(lambda z: jtheta(4, z, 0.25), 7) 0.9820995967262793943571139 0.9820995967262793943571139 >>> jtheta(4, 7, 0.25, 2); diff(lambda z: jtheta(4, z, 0.25), 7, 2) 0.3936902850291437081667755 0.3936902850291437081667755 **Possible issues** For `|q| \ge 1` or `\Im(\tau) \le 0`, :func:`~mpmath.jtheta` raises ``ValueError``. This exception is also raised for `|q|` extremely close to 1 (or equivalently `\tau` very close to 0), since the series would converge too slowly:: >>> jtheta(1, 10, 0.99999999 * exp(0.5*j)) Traceback (most recent call last): ... ValueError: abs(q) > THETA_Q_LIM = 1.000000 """ eulernum = r""" Gives the `n`-th Euler number, defined as the `n`-th derivative of `\mathrm{sech}(t) = 1/\cosh(t)` evaluated at `t = 0`. Equivalently, the Euler numbers give the coefficients of the Taylor series .. math :: \mathrm{sech}(t) = \sum_{n=0}^{\infty} \frac{E_n}{n!} t^n. The Euler numbers are closely related to Bernoulli numbers and Bernoulli polynomials. They can also be evaluated in terms of Euler polynomials (see :func:`~mpmath.eulerpoly`) as `E_n = 2^n E_n(1/2)`. **Examples** Computing the first few Euler numbers and verifying that they agree with the Taylor series:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> [eulernum(n) for n in range(11)] [1.0, 0.0, -1.0, 0.0, 5.0, 0.0, -61.0, 0.0, 1385.0, 0.0, -50521.0] >>> chop(diffs(sech, 0, 10)) [1.0, 0.0, -1.0, 0.0, 5.0, 0.0, -61.0, 0.0, 1385.0, 0.0, -50521.0] Euler numbers grow very rapidly. :func:`~mpmath.eulernum` efficiently computes numerical approximations for large indices:: >>> eulernum(50) -6.053285248188621896314384e+54 >>> eulernum(1000) 3.887561841253070615257336e+2371 >>> eulernum(10**20) 4.346791453661149089338186e+1936958564106659551331 Comparing with an asymptotic formula for the Euler numbers:: >>> n = 10**5 >>> (-1)**(n//2) * 8 * sqrt(n/(2*pi)) * (2*n/(pi*e))**n 3.69919063017432362805663e+436961 >>> eulernum(n) 3.699193712834466537941283e+436961 Pass ``exact=True`` to obtain exact values of Euler numbers as integers:: >>> print(eulernum(50, exact=True)) -6053285248188621896314383785111649088103498225146815121 >>> print(eulernum(200, exact=True) % 10**10) 1925859625 >>> eulernum(1001, exact=True) 0 """ eulerpoly = r""" Evaluates the Euler polynomial `E_n(z)`, defined by the generating function representation .. math :: \frac{2e^{zt}}{e^t+1} = \sum_{n=0}^\infty E_n(z) \frac{t^n}{n!}. The Euler polynomials may also be represented in terms of Bernoulli polynomials (see :func:`~mpmath.bernpoly`) using various formulas, for example .. math :: E_n(z) = \frac{2}{n+1} \left( B_n(z)-2^{n+1}B_n\left(\frac{z}{2}\right) \right). Special values include the Euler numbers `E_n = 2^n E_n(1/2)` (see :func:`~mpmath.eulernum`). **Examples** Computing the coefficients of the first few Euler polynomials:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> for n in range(6): ... chop(taylor(lambda z: eulerpoly(n,z), 0, n)) ... [1.0] [-0.5, 1.0] [0.0, -1.0, 1.0] [0.25, 0.0, -1.5, 1.0] [0.0, 1.0, 0.0, -2.0, 1.0] [-0.5, 0.0, 2.5, 0.0, -2.5, 1.0] Evaluation for arbitrary `z`:: >>> eulerpoly(2,3) 6.0 >>> eulerpoly(5,4) 423.5 >>> eulerpoly(35, 11111111112) 3.994957561486776072734601e+351 >>> eulerpoly(4, 10+20j) (-47990.0 - 235980.0j) >>> eulerpoly(2, '-3.5e-5') 0.000035001225 >>> eulerpoly(3, 0.5) 0.0 >>> eulerpoly(55, -10**80) -1.0e+4400 >>> eulerpoly(5, -inf) -inf >>> eulerpoly(6, -inf) +inf Computing Euler numbers:: >>> 2**26 * eulerpoly(26,0.5) -4087072509293123892361.0 >>> eulernum(26) -4087072509293123892361.0 Evaluation is accurate for large `n` and small `z`:: >>> eulerpoly(100, 0.5) 2.29047999988194114177943e+108 >>> eulerpoly(1000, 10.5) 3.628120031122876847764566e+2070 >>> eulerpoly(10000, 10.5) 1.149364285543783412210773e+30688 """ spherharm = r""" Evaluates the spherical harmonic `Y_l^m(\theta,\phi)`, .. math :: Y_l^m(\theta,\phi) = \sqrt{\frac{2l+1}{4\pi}\frac{(l-m)!}{(l+m)!}} P_l^m(\cos \theta) e^{i m \phi} where `P_l^m` is an associated Legendre function (see :func:`~mpmath.legenp`). Here `\theta \in [0, \pi]` denotes the polar coordinate (ranging from the north pole to the south pole) and `\phi \in [0, 2 \pi]` denotes the azimuthal coordinate on a sphere. Care should be used since many different conventions for spherical coordinate variables are used. Usually spherical harmonics are considered for `l \in \mathbb{N}`, `m \in \mathbb{Z}`, `|m| \le l`. More generally, `l,m,\theta,\phi` are permitted to be complex numbers. .. note :: :func:`~mpmath.spherharm` returns a complex number, even if the value is purely real. **Plots** .. literalinclude :: /plots/spherharm40.py `Y_{4,0}`: .. image :: /plots/spherharm40.png `Y_{4,1}`: .. image :: /plots/spherharm41.png `Y_{4,2}`: .. image :: /plots/spherharm42.png `Y_{4,3}`: .. image :: /plots/spherharm43.png `Y_{4,4}`: .. image :: /plots/spherharm44.png **Examples** Some low-order spherical harmonics with reference values:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> theta = pi/4 >>> phi = pi/3 >>> spherharm(0,0,theta,phi); 0.5*sqrt(1/pi)*expj(0) (0.2820947917738781434740397 + 0.0j) (0.2820947917738781434740397 + 0.0j) >>> spherharm(1,-1,theta,phi); 0.5*sqrt(3/(2*pi))*expj(-phi)*sin(theta) (0.1221506279757299803965962 - 0.2115710938304086076055298j) (0.1221506279757299803965962 - 0.2115710938304086076055298j) >>> spherharm(1,0,theta,phi); 0.5*sqrt(3/pi)*cos(theta)*expj(0) (0.3454941494713354792652446 + 0.0j) (0.3454941494713354792652446 + 0.0j) >>> spherharm(1,1,theta,phi); -0.5*sqrt(3/(2*pi))*expj(phi)*sin(theta) (-0.1221506279757299803965962 - 0.2115710938304086076055298j) (-0.1221506279757299803965962 - 0.2115710938304086076055298j) With the normalization convention used, the spherical harmonics are orthonormal on the unit sphere:: >>> sphere = [0,pi], [0,2*pi] >>> dS = lambda t,p: fp.sin(t) # differential element >>> Y1 = lambda t,p: fp.spherharm(l1,m1,t,p) >>> Y2 = lambda t,p: fp.conj(fp.spherharm(l2,m2,t,p)) >>> l1 = l2 = 3; m1 = m2 = 2 >>> print(fp.quad(lambda t,p: Y1(t,p)*Y2(t,p)*dS(t,p), *sphere)) (1+0j) >>> m2 = 1 # m1 != m2 >>> print(fp.chop(fp.quad(lambda t,p: Y1(t,p)*Y2(t,p)*dS(t,p), *sphere))) 0.0 Evaluation is accurate for large orders:: >>> spherharm(1000,750,0.5,0.25) (3.776445785304252879026585e-102 - 5.82441278771834794493484e-102j) Evaluation works with complex parameter values:: >>> spherharm(1+j, 2j, 2+3j, -0.5j) (64.44922331113759992154992 + 1981.693919841408089681743j) """ scorergi = r""" Evaluates the Scorer function .. math :: \operatorname{Gi}(z) = \operatorname{Ai}(z) \int_0^z \operatorname{Bi}(t) dt + \operatorname{Bi}(z) \int_z^{\infty} \operatorname{Ai}(t) dt which gives a particular solution to the inhomogeneous Airy differential equation `f''(z) - z f(z) = 1/\pi`. Another particular solution is given by the Scorer Hi-function (:func:`~mpmath.scorerhi`). The two functions are related as `\operatorname{Gi}(z) + \operatorname{Hi}(z) = \operatorname{Bi}(z)`. **Plots** .. literalinclude :: /plots/gi.py .. image :: /plots/gi.png .. literalinclude :: /plots/gi_c.py .. image :: /plots/gi_c.png **Examples** Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> scorergi(0); 1/(power(3,'7/6')*gamma('2/3')) 0.2049755424820002450503075 0.2049755424820002450503075 >>> diff(scorergi, 0); 1/(power(3,'5/6')*gamma('1/3')) 0.1494294524512754526382746 0.1494294524512754526382746 >>> scorergi(+inf); scorergi(-inf) 0.0 0.0 >>> scorergi(1) 0.2352184398104379375986902 >>> scorergi(-1) -0.1166722172960152826494198 Evaluation for large arguments:: >>> scorergi(10) 0.03189600510067958798062034 >>> scorergi(100) 0.003183105228162961476590531 >>> scorergi(1000000) 0.0000003183098861837906721743873 >>> 1/(pi*1000000) 0.0000003183098861837906715377675 >>> scorergi(-1000) -0.08358288400262780392338014 >>> scorergi(-100000) 0.02886866118619660226809581 >>> scorergi(50+10j) (0.0061214102799778578790984 - 0.001224335676457532180747917j) >>> scorergi(-50-10j) (5.236047850352252236372551e+29 - 3.08254224233701381482228e+29j) >>> scorergi(100000j) (-8.806659285336231052679025e+6474077 + 8.684731303500835514850962e+6474077j) Verifying the connection between Gi and Hi:: >>> z = 0.25 >>> scorergi(z) + scorerhi(z) 0.7287469039362150078694543 >>> airybi(z) 0.7287469039362150078694543 Verifying the differential equation:: >>> for z in [-3.4, 0, 2.5, 1+2j]: ... chop(diff(scorergi,z,2) - z*scorergi(z)) ... -0.3183098861837906715377675 -0.3183098861837906715377675 -0.3183098861837906715377675 -0.3183098861837906715377675 Verifying the integral representation:: >>> z = 0.5 >>> scorergi(z) 0.2447210432765581976910539 >>> Ai,Bi = airyai,airybi >>> Bi(z)*(Ai(inf,-1)-Ai(z,-1)) + Ai(z)*(Bi(z,-1)-Bi(0,-1)) 0.2447210432765581976910539 **References** 1. [DLMF]_ section 9.12: Scorer Functions """ scorerhi = r""" Evaluates the second Scorer function .. math :: \operatorname{Hi}(z) = \operatorname{Bi}(z) \int_{-\infty}^z \operatorname{Ai}(t) dt - \operatorname{Ai}(z) \int_{-\infty}^z \operatorname{Bi}(t) dt which gives a particular solution to the inhomogeneous Airy differential equation `f''(z) - z f(z) = 1/\pi`. See also :func:`~mpmath.scorergi`. **Plots** .. literalinclude :: /plots/hi.py .. image :: /plots/hi.png .. literalinclude :: /plots/hi_c.py .. image :: /plots/hi_c.png **Examples** Some values and limits:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> scorerhi(0); 2/(power(3,'7/6')*gamma('2/3')) 0.4099510849640004901006149 0.4099510849640004901006149 >>> diff(scorerhi,0); 2/(power(3,'5/6')*gamma('1/3')) 0.2988589049025509052765491 0.2988589049025509052765491 >>> scorerhi(+inf); scorerhi(-inf) +inf 0.0 >>> scorerhi(1) 0.9722051551424333218376886 >>> scorerhi(-1) 0.2206696067929598945381098 Evaluation for large arguments:: >>> scorerhi(10) 455641153.5163291358991077 >>> scorerhi(100) 6.041223996670201399005265e+288 >>> scorerhi(1000000) 7.138269638197858094311122e+289529652 >>> scorerhi(-10) 0.0317685352825022727415011 >>> scorerhi(-100) 0.003183092495767499864680483 >>> scorerhi(100j) (-6.366197716545672122983857e-9 + 0.003183098861710582761688475j) >>> scorerhi(50+50j) (-5.322076267321435669290334e+63 + 1.478450291165243789749427e+65j) >>> scorerhi(-1000-1000j) (0.0001591549432510502796565538 - 0.000159154943091895334973109j) Verifying the differential equation:: >>> for z in [-3.4, 0, 2, 1+2j]: ... chop(diff(scorerhi,z,2) - z*scorerhi(z)) ... 0.3183098861837906715377675 0.3183098861837906715377675 0.3183098861837906715377675 0.3183098861837906715377675 Verifying the integral representation:: >>> z = 0.5 >>> scorerhi(z) 0.6095559998265972956089949 >>> Ai,Bi = airyai,airybi >>> Bi(z)*(Ai(z,-1)-Ai(-inf,-1)) - Ai(z)*(Bi(z,-1)-Bi(-inf,-1)) 0.6095559998265972956089949 """ stirling1 = r""" Gives the Stirling number of the first kind `s(n,k)`, defined by .. math :: x(x-1)(x-2)\cdots(x-n+1) = \sum_{k=0}^n s(n,k) x^k. The value is computed using an integer recurrence. The implementation is not optimized for approximating large values quickly. **Examples** Comparing with the generating function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> taylor(lambda x: ff(x, 5), 0, 5) [0.0, 24.0, -50.0, 35.0, -10.0, 1.0] >>> [stirling1(5, k) for k in range(6)] [0.0, 24.0, -50.0, 35.0, -10.0, 1.0] Recurrence relation:: >>> n, k = 5, 3 >>> stirling1(n+1,k) + n*stirling1(n,k) - stirling1(n,k-1) 0.0 The matrices of Stirling numbers of first and second kind are inverses of each other:: >>> A = matrix(5, 5); B = matrix(5, 5) >>> for n in range(5): ... for k in range(5): ... A[n,k] = stirling1(n,k) ... B[n,k] = stirling2(n,k) ... >>> A * B [1.0 0.0 0.0 0.0 0.0] [0.0 1.0 0.0 0.0 0.0] [0.0 0.0 1.0 0.0 0.0] [0.0 0.0 0.0 1.0 0.0] [0.0 0.0 0.0 0.0 1.0] Pass ``exact=True`` to obtain exact values of Stirling numbers as integers:: >>> stirling1(42, 5) -2.864498971768501633736628e+50 >>> print stirling1(42, 5, exact=True) -286449897176850163373662803014001546235808317440000 """ stirling2 = r""" Gives the Stirling number of the second kind `S(n,k)`, defined by .. math :: x^n = \sum_{k=0}^n S(n,k) x(x-1)(x-2)\cdots(x-k+1) The value is computed using integer arithmetic to evaluate a power sum. The implementation is not optimized for approximating large values quickly. **Examples** Comparing with the generating function:: >>> from mpmath import * >>> mp.dps = 25; mp.pretty = True >>> taylor(lambda x: sum(stirling2(5,k) * ff(x,k) for k in range(6)), 0, 5) [0.0, 0.0, 0.0, 0.0, 0.0, 1.0] Recurrence relation:: >>> n, k = 5, 3 >>> stirling2(n+1,k) - k*stirling2(n,k) - stirling2(n,k-1) 0.0 Pass ``exact=True`` to obtain exact values of Stirling numbers as integers:: >>> stirling2(52, 10) 2.641822121003543906807485e+45 >>> print stirling2(52, 10, exact=True) 2641822121003543906807485307053638921722527655 """