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This mathematical constant is sometimes called the MRB constant^{[1][2][3][4][5]} or MRB..^[6] MRB stands for Marvin Ray Burns. Being a sum of irrational numbers its irrationally remains an open problem.^[7]

The numerical value of the constant, truncated to 6 decimal places, is

0.187859… (sequence A037077 in the OEIS).

Definition[edit]

The constant is related to the following divergent series:

${\displaystyle \sum _{k=1}^{\infty }(-1)^{k}k^{1/k}.}$

Its partial sums

${\displaystyle s_{n}=\sum _{k=1}^{n}(-1)^{k}k^{1/k}}$

are bounded so that their limit points form an interval [−0.812140…,0.187859…] of length 1..^[8] The upper limit point 0.187859… is what is sometimes called the MRB constant. ^[9] The constant can be explicitly defined by the following infinite sums: ^{[10] [11]}

${\displaystyle 0.187859\ldots =\sum _{k=1}^{\infty }(-1)^{k}(k^{1/k}-1)=\sum _{k=1}^{\infty }\left((2k)^{1/(2k)}-(2k-1)^{1/(2k-1)}\right).}$

There is no known closed-form expression of this constant.^[12]

History[edit]

Marvin Ray Burns published his discovery of the constant in 1999.^[13] The discovery is a result of a "math binge" that started in the spring of 1994.^[14] Before verifying with colleague Simon Plouffe that such a constant had not already been discovered or at least not widely published, Burns called the constant "rc" for root constant.^[15] At Plouffe's suggestion, the constant was renamed Marvin Ray Burns's Constant, and then shortened to "MRB constant" in 1999.^[16] Since then it has been added to tables of constants in a few countries, including Turkey,^[17] Iran,^[18] Germany.^[19] and the United States.^[20]

References[edit]

External links[edit]

• (sequence A037077 in the OEIS)

Category:Mathematical constants Category:Number theory

The MRB constant, named after Marvin Ray Burns, is a mathematical constant for which no closed-form expression is known. It is not known whether the MRB constant is algebraic, transcendental, or even irrational.

The numerical value of MRB constant, truncated to 6 decimal places, is

0.187859… (sequence A037077 in the OEIS).

Definition[edit]

The MRB constant is related to the following divergent series:

${\displaystyle \sum _{k=1}^{\infty }(-1)^{k}k^{1/k}.}$

Its partial sums

${\displaystyle s_{n}=\sum _{k=1}^{n}(-1)^{k}k^{1/k}}$

are bounded so that their limit points form an interval [−0.812140…,0.187859…] of length 1. The upper limit point 0.187859… is what is known as the MRB constant.^{[1][2][3][4][5][6][7]}

The MRB constant can be explicitly defined by the following infinite sums:^[8]

${\displaystyle 0.187859\ldots =\sum _{k=1}^{\infty }(-1)^{k}(k^{1/k}-1)=\sum _{k=1}^{\infty }\left((2k)^{1/(2k)}-(2k-1)^{1/(2k-1)}\right).}$

There is no known closed-form expression of the MRB constant.^[9]

History[edit]

History Marvin Ray Burns published his discovery of the constant in 1999.^[10] The discovery is a result of a "math binge" that started in the spring of 1994.^[11] Before verifying with colleague Simon Plouffe that such a constant had not already been discovered or at least not widely published, Burns called the constant "rc" for root constant.^[12] At Plouffe's suggestion, the constant was renamed Marvin Ray Burns's Constant, and then shortened to "MRB constant" in 1999.^[13] Since then it has been added to tables and lists of constants in a few countries, including Turkey,^[14] Iran,^[15] Germany.^[16] , the United States.^[17] and Italy^[18]

References[edit]

External links[edit]

• Official site of M.R. Burns, constant's author

Iterated exponentials are an example of an iterated function system based on ${\displaystyle x^{x}}$. Such systems have induced some interesting mathematical constants and interesting fractal properties based on its generalization to the complex plane.Cite error: A <ref> tag is missing the closing </ref> (see the help page).

Inverse[edit]

In fact, ${\displaystyle f(x)=x^{x}}$ does have an inverse

${\displaystyle x=f^{-1}(y)=y^{({\frac {1}{y}})^{({\frac {1}{y}})^{\dots }}}}$

which is well-defined for ${\displaystyle y\in [({\frac {1}{e}})^{\frac {1}{e}},e^{e}]}$

This has induced interest in the function ${\displaystyle x^{\frac {1}{x}}}$, which has similar limiting properties to ${\displaystyle x^{x}}$. ^[1]

Convergence[edit]

By an old result of Euler, repeated exponentiation convergence for real values inbetween ${\displaystyle e^{-e}}$ and ${\displaystyle e^{\frac {1}{e}}}$.^[2]

Calculation of Iterated Exponential[edit]

In certain situations, one may calculate the iterated exponential, and certain constants remain of mathematical interest.

Connection to Lambert's Function[edit]

If one defines

${\displaystyle h(z)=z^{z^{z^{\dots }}}}$

for such ${\displaystyle z}$ where such a process converges,

Then ${\displaystyle h(z)}$ actually has a closed form expression in terms of a function known as Lambert's function which is defined implicitly via the following equation:

${\displaystyle W(z)e^{W(z)}=z}$

Namely, that

${\displaystyle h(z)={\frac {W(-log(z))}{-log(z)}}}$

This can be seen by inputting this definition of ${\displaystyle h(z)}$ into the other equation that ${\displaystyle h(z)}$ satisfies, ${\displaystyle h(z)=z^{h(z)}}$. ^[3]

Iteration on the Complex Plane[edit]

The function may also be extended to the complex plane, where such a map tends to display interesting fractal properties.^[4]

Of particular interest is evaluation of the constant

${\displaystyle i^{i^{i^{\dots }}}}$

Which does indeed converge ^[5] and has been evaluated as

${\displaystyle ~=0.43828+0.36059i}$

<ref>Galidakis, I. N. (2004). On an application of Lambert's W function to infinite exponentials. Complex Variables, Theory and Application: An International Journal, 49(11), 759-780.</math>

Category:Mathematical constants Category:Number theory