# scipy.special.expi¶

scipy.special.expi(x, out=None) = <ufunc 'expi'>

Exponential integral Ei.

For real $$x$$, the exponential integral is defined as [1]

$Ei(x) = \int_{-\infty}^x \frac{e^t}{t} dt.$

For $$x > 0$$ the integral is understood as a Cauchy principle value.

It is extended to the complex plane by analytic continuation of the function on the interval $$(0, \infty)$$. The complex variant has a branch cut on the negative real axis.

Parameters
x: array_like

Real or complex valued argument

out: ndarray, optional

Optional output array for the function results

Returns
scalar or ndarray

Values of the exponential integral

exp1

Exponential integral $$E_1$$

expn

Generalized exponential integral $$E_n$$

Notes

The exponential integrals $$E_1$$ and $$Ei$$ satisfy the relation

$E_1(x) = -Ei(-x)$

for $$x > 0$$.

References

1

Digital Library of Mathematical Functions, 6.2.5 https://dlmf.nist.gov/6.2#E5

Examples

>>> import scipy.special as sc


It is related to exp1.

>>> x = np.array([1, 2, 3, 4])
>>> -sc.expi(-x)
array([0.21938393, 0.04890051, 0.01304838, 0.00377935])
>>> sc.exp1(x)
array([0.21938393, 0.04890051, 0.01304838, 0.00377935])


The complex variant has a branch cut on the negative real axis.

>>> import scipy.special as sc
>>> sc.expi(-1 + 1e-12j)
(-0.21938393439552062+3.1415926535894254j)
>>> sc.expi(-1 - 1e-12j)
(-0.21938393439552062-3.1415926535894254j)


As the complex variant approaches the branch cut, the real parts approach the value of the real variant.

>>> sc.expi(-1)
-0.21938393439552062


The SciPy implementation returns the real variant for complex values on the branch cut.

>>> sc.expi(complex(-1, 0.0))
(-0.21938393439552062-0j)
>>> sc.expi(complex(-1, -0.0))
(-0.21938393439552062-0j)


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