Editing Logarithmic integral function

{{Short description|Special function defined by an integral}}
{{Redirect|Li(x)|the polylogarithm denoted by Li<sub>''s''</sub>(''z'')|Polylogarithm}}
{{Use American English|date = January 2019}}
[[File:Plot of the logarithmic integral function li(z) in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D.svg|alt=Plot of the logarithmic integral function li(z) in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D|thumb|Plot of the logarithmic integral function li(z) in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D]]
In [[mathematics]], the '''logarithmic integral function''' or '''integral logarithm''' li(''x'') is a [[special function]]. It is relevant in problems of [[physics]] and has [[number theory|number theoretic]] significance. In particular, according to the [[prime number theorem]], it is a very good [[approximation]] to the [[prime-counting function]], which is defined as the number of [[prime numbers]] less than or equal to a given value {{mvar|x}}. [[Image:Logarithmic integral function.svg|thumb|right|300px|Logarithmic integral function plot]]

== Integral representation ==
The logarithmic integral has an integral representation defined for all positive [[real number]]s {{mvar|x}}&nbsp;≠&nbsp;1 by the [[integral|definite integral]]
: <math> \operatorname{li}(x) = \int_0^x \frac{dt}{\ln t}. </math>

Here, {{math|ln}} denotes the [[natural logarithm]]. The function {{math|1/(ln ''t'')}} has a [[mathematical singularity|singularity]] at {{math|1=''t'' = 1}}, and the integral for {{math|''x'' > 1}} is interpreted as a [[Cauchy principal value]],
: <math> \operatorname{li}(x) = \lim_{\varepsilon \to 0+} \left( \int_0^{1-\varepsilon} \frac{dt}{\ln t} + \int_{1+\varepsilon}^x \frac{dt}{\ln t} \right).</math>

== Offset logarithmic integral ==
The '''offset logarithmic integral''' or '''Eulerian logarithmic integral''' is defined as
: <math> \operatorname{Li}(x) = \int_2^x \frac{dt}{\ln t} = \operatorname{li}(x) - \operatorname{li}(2). </math>

As such, the integral representation has the advantage of avoiding the singularity in the domain of integration.

Equivalently,
: <math> \operatorname{li}(x) = \int_0^x \frac{dt}{\ln t} = \operatorname{Li}(x) + \operatorname{li}(2). </math>

== Special values ==
The function li(''x'') has a single positive zero; it occurs at ''x'' ≈ 1.45136 92348 83381 05028 39684 85892 02744 94930... {{OEIS2C|A070769}}; this number is known as the [[Ramanujan–Soldner constant]].

<math>\operatorname{li}(\text{Li}^{-1}(0)) = \text{li}(2)</math> ≈ 1.045163 780117 492784 844588 889194 613136 522615 578151... {{OEIS2C|A069284}}

This is <math>-(\Gamma(0,-\ln 2) + i\,\pi)</math> where <math>\Gamma(a,x)</math> is the [[incomplete gamma function]]. It must be understood as the [[Cauchy principal value]] of the function.

== Series representation ==
The function li(''x'') is related to the ''[[exponential integral]]'' Ei(''x'') via the equation
: <math>\operatorname{li}(x)=\hbox{Ei}(\ln x) ,</math>

which is valid for ''x''&nbsp;>&nbsp;0. This identity provides a series representation of li(''x'') as
: <math> \operatorname{li}(e^u) = \hbox{Ei}(u) = 
\gamma + \ln |u| + \sum_{n=1}^\infty {u^{n}\over n \cdot n!} 
\quad \text{ for } u \ne 0 \, , </math>
where ''γ'' ≈ 0.57721 56649 01532 ... {{OEIS2C|id=A001620}} is the [[Euler–Mascheroni constant]]. A more rapidly convergent series by [[Srinivasa Ramanujan|Ramanujan]]  <ref>{{MathWorld | urlname=LogarithmicIntegral | title=Logarithmic Integral}}</ref> is
: <math>
 \operatorname{li}(x) =
 \gamma
 + \ln |\ln x|
 + \sqrt{x} \sum_{n=1}^\infty
                \left( \frac{ (-1)^{n-1} (\ln x)^n}  {n! \, 2^{n-1}}
                \sum_{k=0}^{\lfloor (n-1)/2 \rfloor} \frac{1}{2k+1} \right).
</math>
<!-- cribbed from Mathworld, which cites
Berndt, B. C. Ramanujan's Notebooks, Part IV. New York: Springer-Verlag, pp. 126–131, 1994.
-->

== Asymptotic expansion ==
The asymptotic behavior for <math>x\to\infty</math> is
: <math> \operatorname{li}(x) = O \left( \frac{x }{\ln x} \right) . </math>
where <math>O</math> is the [[big O notation]]. The full [[asymptotic expansion]] is
: <math> \operatorname{li}(x) \sim \frac{x}{\ln x} \sum_{k=0}^\infty \frac{k!}{(\ln x)^k} </math>
or
: <math> \frac{\operatorname{li}(x)}{x/\ln x}  \sim  1 + \frac{1}{\ln x} + \frac{2}{(\ln x)^2} + \frac{6}{(\ln x)^3} + \cdots. </math>

This gives the following more accurate asymptotic behaviour:
: <math> \operatorname{li}(x) - \frac{x}{ \ln x} = O \left( \frac{x}{(\ln x)^2} \right) . </math>

As an asymptotic expansion, this series is [[divergent series|not convergent]]: it is a reasonable approximation only if the series is truncated at a finite number of terms, and only large values of ''x'' are employed. This expansion follows directly from the asymptotic expansion for the [[exponential integral]].

This implies e.g. that we can bracket li as:
: <math> 1+\frac{1}{\ln x} < \operatorname{li}(x) \frac{\ln x}{x} < 1+\frac{1}{\ln x}+\frac{3}{(\ln x)^2} </math>
for all <math>\ln x \ge 11</math>.

== Number theoretic significance ==
The logarithmic integral is important in [[number theory]], appearing in estimates of the number of [[prime number]]s less than a given value. For example, the [[prime number theorem]] states that:
: <math>\pi(x)\sim\operatorname{li}(x)</math>
where <math>\pi(x)</math> denotes the number of primes smaller than or equal to <math>x</math>. 

Assuming the [[Riemann hypothesis]], we get the even stronger:<ref>Abramowitz and Stegun, p.&nbsp;230, 5.1.20</ref>
: <math>|\operatorname{li}(x)-\pi(x)| = O(\sqrt{x}\log x)</math>

In fact, the [[Riemann hypothesis]] is equivalent to the statement that:
: <math>|\operatorname{li}(x)-\pi(x)| = O(x^{1/2+a})</math> for any <math>a>0</math>.

For small <math>x</math>, <math>\operatorname{li}(x)>\pi(x)</math> but the difference changes sign an infinite number of times as <math>x</math> increases, and the [[Skewes's number|first time that this happens]] is somewhere between 10<sup>19</sup> and {{val|1.4|e=316}}.

== See also ==
* [[Jørgen Pedersen Gram]]
* [[Skewes' number]]
* [[List of integrals of logarithmic functions]]

== References ==
{{reflist}}
* {{AS ref|5|228}} 
* {{dlmf|id=6|title=Exponential, Logarithmic, Sine, and Cosine Integrals|first=N. M. |last=Temme}}

{{Nonelementary Integral}}
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[[Category:Special hypergeometric functions]]
[[Category:Integrals]]