Exponential integral

In mathematics, the exponential integral Ei is a special function on the complex plane.

It is defined as one particular definite integral of the ratio between an exponential function and its argument.

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Definitions

For real non-zero values of x, the exponential integral Ei(x) is defined as

\operatorname {Ei} (x)=-\int _{-x}^{\infty }{\frac {e^{-t}}{t}}\,dt=\int _{-\infty }^{x}{\frac {e^{t}}{t}}\,dt.

The Risch algorithm shows that Ei is not an elementary function. The definition above can be used for positive values of x, but the integral has to be understood in terms of the Cauchy principal value due to the singularity of the integrand at zero.

For complex values of the argument, the definition becomes ambiguous due to branch points at 0 and $\infty$ .^[1] Instead of Ei, the following notation is used,^[2]

E_{1}(z)=\int _{z}^{\infty }{\frac {e^{-t}}{t}}\,dt,\qquad |{\rm {Arg}}(z)|<\pi

For positive values of x, we have $-E_{1}(x)=\operatorname {Ei} (-x)$ .

In general, a branch cut is taken on the negative real axis and E₁ can be defined by analytic continuation elsewhere on the complex plane.

For positive values of the real part of $z$ , this can be written^[3]

E_{1}(z)=\int _{1}^{\infty }{\frac {e^{-tz}}{t}}\,dt=\int _{0}^{1}{\frac {e^{-z/u}}{u}}\,du,\qquad \Re (z)\geq 0.

The behaviour of E₁ near the branch cut can be seen by the following relation:^[4]

\lim _{\delta \to 0+}E_{1}(-x\pm i\delta )=-\operatorname {Ei} (x)\mp i\pi ,\qquad x>0.

Properties

Several properties of the exponential integral below, in certain cases, allow one to avoid its explicit evaluation through the definition above.

Convergent series

For real or complex arguments off the negative real axis, $E_{1}(z)$ can be expressed as^[5]

E_{1}(z)=-\gamma -\ln z-\sum _{k=1}^{\infty }{\frac {(-z)^{k}}{k\;k!}}\qquad (\left|\operatorname {Arg} (z)\right|<\pi )

where $\gamma$ is the Euler–Mascheroni constant. The sum converges for all complex $z$ , and we take the usual value of the complex logarithm having a branch cut along the negative real axis.

This formula can be used to compute $E_{1}(x)$ with floating point operations for real $x$ between 0 and 2.5. For $x>2.5$ , the result is inaccurate due to cancellation.

A faster converging series was found by Ramanujan:

{\rm {Ei}}(x)=\gamma +\ln x+\exp {(x/2)}\sum _{n=1}^{\infty }{\frac {(-1)^{n-1}x^{n}}{n!\,2^{n-1}}}\sum _{k=0}^{\lfloor (n-1)/2\rfloor }{\frac {1}{2k+1}}

These alternating series can also be used to give good asymptotic bounds for small x, e.g.^{[citation needed]}:

1-{\frac {3x}{4}}\leq {\rm {Ei}}(x)-\gamma -\ln x\leq 1-{\frac {3x}{4}}+{\frac {11x^{2}}{36}}

for $x\geq 0$ .

Asymptotic (divergent) series

Relative error of the asymptotic approximation for different number $~N~$ of terms in the truncated sum

Unfortunately, the convergence of the series above is slow for arguments of larger modulus. For example, more than 40 terms are required to get an answer correct to three significant figures for $E_{1}(10)$ .^[6] However, for positive values of x, there is a divergent series approximation that can be obtained by integrating $xe^{x}E_{1}(x)$ by parts:^[7]

E_{1}(x)={\frac {\exp(-x)}{x}}\left(\sum _{n=0}^{N-1}{\frac {n!}{(-x)^{n}}}+O(N!x^{-N})\right)

The relative error of the approximation above is plotted on the figure to the right for various values of $N$ , the number of terms in the truncated sum ( $N=1$ in red, $N=5$ in pink).

Asymptotics beyond all orders

Using integration by parts, we can obtain an explicit formula^[8]

\operatorname {Ei} (z)={\frac {e^{z}}{z}}\left(\sum _{k=0}^{n}{\frac {k!}{z^{k}}}+e_{n}(z)\right),\quad e_{n}(z)\equiv (n+1)!\ ze^{-z}\int _{-\infty }^{z}{\frac {e^{t}}{t^{n+2}}}\,dt

For any fixed

z

, the absolute value of the error term

|e_{n}(z)|

decreases, then increases. The minimum occurs at

n\sim |z|

, at which point

\vert e_{n}(z)\vert \leq {\sqrt {\frac {2\pi }{\vert z\vert }}}e^{-\vert z\vert }

. This bound is said to be "asymptotics beyond all orders".

Exponential and logarithmic behavior: bracketing

Bracketing of $E_{1}$ by elementary functions

From the two series suggested in previous subsections, it follows that $E_{1}$ behaves like a negative exponential for large values of the argument and like a logarithm for small values. For positive real values of the argument, $E_{1}$ can be bracketed by elementary functions as follows:^[9]

{\frac {1}{2}}e^{-x}\,\ln \!\left(1+{\frac {2}{x}}\right)<E_{1}(x)<e^{-x}\,\ln \!\left(1+{\frac {1}{x}}\right)\qquad x>0

The left-hand side of this inequality is shown in the graph to the left in blue; the central part $E_{1}(x)$ is shown in black and the right-hand side is shown in red.

Definition by Ein

Both $\operatorname {Ei}$ and $E_{1}$ can be written more simply using the entire function $\operatorname {Ein}$ ^[10] defined as

\operatorname {Ein} (z)=\int _{0}^{z}(1-e^{-t}){\frac {dt}{t}}=\sum _{k=1}^{\infty }{\frac {(-1)^{k+1}z^{k}}{k\;k!}}

(note that this is just the alternating series in the above definition of $E_{1}$ ). Then we have

E_{1}(z)\,=\,-\gamma -\ln z+{\rm {Ein}}(z)\qquad \left|\operatorname {Arg} (z)\right|<\pi

\operatorname {Ei} (x)\,=\,\gamma +\ln {x}-\operatorname {Ein} (-x)\qquad x\neq 0

Relation with other functions

Kummer's equation

z{\frac {d^{2}w}{dz^{2}}}+(b-z){\frac {dw}{dz}}-aw=0

is usually solved by the confluent hypergeometric functions $M(a,b,z)$ and $U(a,b,z).$ But when $a=0$ and $b=1,$ that is,

z{\frac {d^{2}w}{dz^{2}}}+(1-z){\frac {dw}{dz}}=0

we have

M(0,1,z)=U(0,1,z)=1

for all z. A second solution is then given by E₁(−z). In fact,

E_{1}(-z)=-\gamma -i\pi +{\frac {\partial [U(a,1,z)-M(a,1,z)]}{\partial a}},\qquad 0<{\rm {Arg}}(z)<2\pi

with the derivative evaluated at $a=0.$ Another connexion with the confluent hypergeometric functions is that E₁ is an exponential times the function U(1,1,z):

E_{1}(z)=e^{-z}U(1,1,z)

The exponential integral is closely related to the logarithmic integral function li(x) by the formula

\operatorname {li} (e^{x})=\operatorname {Ei} (x)

for non-zero real values of $x$ .

Generalization

The exponential integral may also be generalized to

E_{n}(x)=\int _{1}^{\infty }{\frac {e^{-xt}}{t^{n}}}\,dt,

which can be written as a special case of the upper incomplete gamma function:^[11]

E_{n}(x)=x^{n-1}\Gamma (1-n,x).

The generalized form is sometimes called the Misra function^[12] $\varphi _{m}(x)$ , defined as

\varphi _{m}(x)=E_{-m}(x).

Many properties of this generalized form can be found in the NIST Digital Library of Mathematical Functions.

Including a logarithm defines the generalized integro-exponential function^[13]

E_{s}^{j}(z)={\frac {1}{\Gamma (j+1)}}\int _{1}^{\infty }\left(\log t\right)^{j}{\frac {e^{-zt}}{t^{s}}}\,dt.

The indefinite integral:

\operatorname {Ei} (a\cdot b)=\iint e^{ab}\,da\,db

is similar in form to the ordinary generating function for $d(n)$ , the number of divisors of $n$ :

\sum \limits _{n=1}^{\infty }d(n)x^{n}=\sum \limits _{a=1}^{\infty }\sum \limits _{b=1}^{\infty }x^{ab}

Derivatives

The derivatives of the generalised functions $E_{n}$ can be calculated by means of the formula ^[14]

E_{n}'(z)=-E_{n-1}(z)\qquad (n=1,2,3,\ldots )

Note that the function $E_{0}$ is easy to evaluate (making this recursion useful), since it is just $e^{-z}/z$ .^[15]