The omega constant is a mathematical constant defined as the unique real number that satisfies the equation

Ω e Ω = 1. {\displaystyle \Omega e^{\Omega }=1.}

It is the value of W(1), where W is Lambert's W function. The name is derived from the alternate name for Lambert's W function, the omega function. The numerical value of Ω is given by

Ω = 0.567143290409783872999968662210... (sequence A030178 in the OEIS).
1/Ω = 1.763222834351896710225201776951... (sequence A030797 in the OEIS).

Properties

Fixed point representation

The defining identity can be expressed, for example, as

ln ( 1 Ω ) = Ω . {\displaystyle \ln \left({\tfrac {1}{\Omega }}\right)=\Omega .}

or

ln ( Ω ) = Ω {\displaystyle -\ln(\Omega )=\Omega }

as well as

e Ω = Ω . {\displaystyle e^{-\Omega }=\Omega .}

Computation

One can calculate Ω iteratively, by starting with an initial guess Ω0, and considering the sequence

Ω n 1 = e Ω n . {\displaystyle \Omega _{n 1}=e^{-\Omega _{n}}.}

This sequence will converge to Ω as n approaches infinity. This is because Ω is an attractive fixed point of the function ex.

It is much more efficient to use the iteration

Ω n 1 = 1 Ω n 1 e Ω n , {\displaystyle \Omega _{n 1}={\frac {1 \Omega _{n}}{1 e^{\Omega _{n}}}},}

because the function

f ( x ) = 1 x 1 e x , {\displaystyle f(x)={\frac {1 x}{1 e^{x}}},}

in addition to having the same fixed point, also has a derivative that vanishes there. This guarantees quadratic convergence; that is, the number of correct digits is roughly doubled with each iteration.

Using Halley's method, Ω can be approximated with cubic convergence (the number of correct digits is roughly tripled with each iteration): (see also Lambert W function § Numerical evaluation).

Ω j 1 = Ω j Ω j e Ω j 1 e Ω j ( Ω j 1 ) ( Ω j 2 ) ( Ω j e Ω j 1 ) 2 Ω j 2 . {\displaystyle \Omega _{j 1}=\Omega _{j}-{\frac {\Omega _{j}e^{\Omega _{j}}-1}{e^{\Omega _{j}}(\Omega _{j} 1)-{\frac {(\Omega _{j} 2)(\Omega _{j}e^{\Omega _{j}}-1)}{2\Omega _{j} 2}}}}.}

Integral representations

An identity due to Victor Adamchik is given by the relationship

d t ( e t t ) 2 π 2 = 1 1 Ω . {\displaystyle \int _{-\infty }^{\infty }{\frac {dt}{(e^{t}-t)^{2} \pi ^{2}}}={\frac {1}{1 \Omega }}.}

Other relations due to Mező and Kalugin-Jeffrey-Corless are:

Ω = 1 π Re 0 π log ( e e i t e i t e e i t e i t ) d t , {\displaystyle \Omega ={\frac {1}{\pi }}\operatorname {Re} \int _{0}^{\pi }\log \left({\frac {e^{e^{it}}-e^{-it}}{e^{e^{it}}-e^{it}}}\right)dt,}
Ω = 1 π 0 π log ( 1 sin t t e t cot t ) d t . {\displaystyle \Omega ={\frac {1}{\pi }}\int _{0}^{\pi }\log \left(1 {\frac {\sin t}{t}}e^{t\cot t}\right)dt.}

The latter two identities can be extended to other values of the W function (see also Lambert W function § Representations).

Transcendence

The constant Ω is transcendental. This can be seen as a direct consequence of the Lindemann–Weierstrass theorem. For a contradiction, suppose that Ω is algebraic. By the theorem, e−Ω is transcendental, but Ω = e−Ω, which is a contradiction. Therefore, it must be transcendental.

References

External links

  • Weisstein, Eric W. "Omega Constant". MathWorld.
  • "Omega constant (1,000,000 digits)", Darkside communication group (in Japan), retrieved 2017-12-25

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