Gelfond's constant

In mathematics, Gelfond's constant, named after Aleksandr Gelfond, is e^$π$, that is, e raised to the power $π$ . Like both e and $π$ , this constant is a transcendental number. This was first established by Gelfond and may now be considered as an application of the Gelfond–Schneider theorem, noting that

e^{\pi }=(e^{i\pi })^{-i}=(-1)^{-i},

where i is the imaginary unit. Since −i is algebraic but not rational, e^$π$ is transcendental. The constant was mentioned in Hilbert's seventh problem.[1] A related constant is $2^{\sqrt {2}}$ , known as the Gelfond–Schneider constant. The related value $π$ + e^$π$ is also irrational.[2]

Numerical value

The decimal expansion of Gelfond's constant begins

e^{\pi }\approx 23.1406926327792690057290863679485473802661062426002119934450464095243423506904527835169719970675492\dots

OEIS: A039661

Construction

If one defines $k_{0}={\tfrac {1}{\sqrt {2}}}$ and

k_{n+1}={\frac {1-{\sqrt {1-k_{n}^{2}}}}{1+{\sqrt {1-k_{n}^{2}}}}}

for $n>0$ , then the sequence[3]

(4/k_{n+1})^{2^{-n}}

converges rapidly to $e^{\pi }$ .

Continued fraction expansion

e^{\pi }=23+{\cfrac {1}{7+{\cfrac {1}{9+{\cfrac {1}{3+{\cfrac {1}{1+{\cfrac {1}{1+{\cfrac {1}{591+{\cfrac {1}{2+{\cfrac {1}{9+{\cfrac {1}{1+{\cfrac {1}{2+{\cfrac {1}{\ddots }}}}}}}}}}}}}}}}}}}}}}

This is based on the digits for the simple continued fraction:

e^{\pi }=[23;7,9,3,1,1,591,2,9,1,2,34,1,16,1,30,1,1,4,1,2,108,2,2,1,3,1,7,1,2,2,2,1,2,3,2,166,1,2,1,4,8,10,1,1,7,1,2,3,566,1,2,3,3,1,20,1,2,19,1,3,2,1,2,13,2,2,11,...]

As given by the integer sequence A058287.

Geometric property

The volume of the n-dimensional ball (or n-ball), is given by

V_{n}={\frac {\pi ^{\frac {n}{2}}R^{n}}{\Gamma \left({\frac {n}{2}}+1\right)}},

where $R$ is its radius, and $\Gamma$ is the gamma function. Any even-dimensional ball has volume

V_{2n}={\frac {\pi ^{n}}{n!}}R^{2n},

and, summing up all the unit-ball (R = 1) volumes of even-dimension gives[4]

\sum _{n=0}^{\infty }V_{2n}(R=1)=e^{\pi }.

Similar or related constants

Ramanujan's constant

e^{\pi {\sqrt {163}}}=({\text{Gelfond's constant}})^{\sqrt {163}}

This is known as Ramanujan's constant. It is an application of Heegner numbers, where 163 is the Heegner number in question.

Similar to $e^{\pi }-\pi$ , $e^{\pi {\sqrt {163}}}$ is very close to an integer:

e^{\pi {\sqrt {163}}}=262\,537\,412\,640\,768\,743.999\,999\,999\,999\,25\ldots \approx 640\,320^{3}+744

As it was the Indian mathematician Srinivasa Ramanujan who first predicted this almost-integer number, it has been named after him, though the number was first discovered by the French mathematician Charles Hermite in 1859.

The coincidental closeness, to within 0.000 000 000 000 75 of the number $(640,320)^{3}+744$ is explained by complex multiplication and the q-expansion of the j-invariant, specifically:

j((1+{\sqrt {-163}})/2)=(-640\,320)^{3}

and,

(-640\,320)^{3}=-e^{\pi {\sqrt {163}}}+744+O\left(e^{-\pi {\sqrt {163}}}\right)

where $O\left(e^{-\pi {\sqrt {163}}}\right)$ is the error term,

{\displaystyle O\left(e^{-\pi {\sqrt {163}}}\right)=-196\,884/e^{\pi {\sqrt {163}}}\approx -196\,884/(640\,320^{3}+744)\approx -0.000\,000\,000\,000\,75}

which explains why $e^{\pi {\sqrt {163}}}$ is 0.000 000 000 000 75 below $(640,320)^{3}+744$ .

(For more detail on this proof, consult the article on Heegner numbers.)

The number $e^{\pi }-\pi$

The decimal expansion of $e^{\pi }-\pi$ is given by A018938:

e^{\pi }-\pi \approx 19.9990999791894757672664429846690444960689368432251061724701018172165259444042437848889371717254321\dots

Despite this being nearly the integer 20, no explanation has been given for this fact and it is believed to be a mathematical coincidence.

The number $\pi ^{e}$

The decimal expansion of $\pi ^{e}$ is given by A059850:

\pi ^{e}\approx 22.459157718361045473427152204543735027589315133996692249203002554066926040399117912318519752727143031531450\dots

It is not known whether or not this number is transcendental. Note that, by Gelfond-Schneider theorem, we can only infer definitively that $a^{b}$ is transcendental if $a$ is algebraic and $b$ is not rational ( $a$ and $b$ are both considered complex numbers, also $a\neq 0,a\neq 1$ ).

In the case of $e^{\pi }$ , we are only able to prove this number transcendental due to properties of complex exponential forms, where $\pi$ is considered the modulus of the complex number $e^{\pi }$ , and the above equivalency given to transform it into $(-1)^{-i}$ , allowing the application of Gelfond-Schneider theorem.

$\pi ^{e}$ has no such equivalence, and hence, as both $\pi$ and $e$ are transcendental, we can make no conclusion about the transcendence of $\pi ^{e}$ .

The number $e^{\pi }-\pi ^{e}$

As with $\pi ^{e}$ , it is not known whether $e^{\pi }-\pi ^{e}$ is transcendental. Further, no proof exists to show whether or not it is irrational.

The decimal expansion for $e^{\pi }-\pi ^{e}$ is given by A063504:

e^{\pi }-\pi ^{e}\approx 0.681534914418223532301934163404812352676791108603519744242043855457416310291334871198452244340406188144502\dots

The number $i^{i}$

i^{i}=(e^{i\pi /2})^{i}=e^{-\pi /2}=(e^{\pi })^{-1/2}

The decimal expansion of is given by A049006:

i^{i}\approx 0.207879576350761908546955619834978770033877841631769608075135883055419877285482139788600277865426035\dots

Because of the equivalence, we can use Gelfond-Schneider theorem to prove that the reciprocal square root of Gelfond's constant is also transcendental:

$i$ is both algebraic (a solution to the polynomial $x^{2}+1=0$ ), and not rational, hence $i^{i}$ is transcendental.

References

Tijdeman, Robert (1976). "On the Gel'fond–Baker method and its applications". In Felix E. Browder (ed.). Mathematical Developments Arising from Hilbert Problems. Proceedings of Symposia in Pure Mathematics. XXVIII.1. American Mathematical Society. pp. 241–268. ISBN 0-8218-1428-1. Zbl 0341.10026.
Nesterenko, Y (1996). "Modular Functions and Transcendence Problems". Comptes Rendus de l'Académie des Sciences, Série I. 322 (10): 909–914. Zbl 0859.11047.
Borwein, J.; Bailey, D. (2004). Mathematics by Experiment: Plausible Reasoning in the 21st Century. Wellesley, MA: A K Peters. p. 137. ISBN 1-56881-211-6. Zbl 1083.00001.
Connolly, Francis. University of Notre Dame

External links

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[tijdeman-1] Tijdeman, Robert (1976). "On the Gel'fond–Baker method and its applications". In Felix E. Browder (ed.). Mathematical Developments Arising from Hilbert Problems. Proceedings of Symposia in Pure Mathematics. XXVIII.1. American Mathematical Society. pp. 241–268. ISBN 0-8218-1428-1. Zbl 0341.10026.

[2] Nesterenko, Y (1996). "Modular Functions and Transcendence Problems". Comptes Rendus de l'Académie des Sciences, Série I. 322 (10): 909–914. Zbl 0859.11047.

[3] Borwein, J.; Bailey, D. (2004). Mathematics by Experiment: Plausible Reasoning in the 21st Century. Wellesley, MA: A K Peters. p. 137. ISBN 1-56881-211-6. Zbl 1083.00001.

[4] Connolly, Francis. University of Notre Dame

Gelfond's constant