Dirichlet beta function

Special mathematical function From Wikipedia, the free encyclopedia

Dirichlet beta function

In mathematics, the Dirichlet beta function (also known as the Catalan beta function) is a special function, closely related to the Riemann zeta function. It is a particular Dirichlet L-function, the L-function for the alternating character of period four.

Thumb
The Dirichlet beta function

Definition

Summarize
Perspective

The Dirichlet beta function is defined as

or, equivalently,

In each case, it is assumed that Re(s) > 0.

Alternatively, the following definition, in terms of the Hurwitz zeta function, is valid in the whole complex s-plane:[1]

Another equivalent definition, in terms of the Lerch transcendent, is:

which is once again valid for all complex values of s.

The Dirichlet beta function can also be written in terms of the polylogarithm function:

Also the series representation of Dirichlet beta function can be formed in terms of the polygamma function

but this formula is only valid at positive integer values of .

Euler product formula

Summarize
Perspective

It is also the simplest example of a series non-directly related to which can also be factorized as an Euler product, thus leading to the idea of Dirichlet character defining the exact set of Dirichlet series having a factorization over the prime numbers.

At least for Re(s)  1:

where p≡1 mod 4 are the primes of the form 4n+1 (5,13,17,...) and p≡3 mod 4 are the primes of the form 4n+3 (3,7,11,...). This can be written compactly as

Functional equation

The functional equation extends the beta function to the left side of the complex plane Re(s) ≤ 0. It is given by

where Γ(s) is the gamma function. It was conjectured by Euler in 1749 and proved by Malmsten in 1842.[2]

Specific values

Summarize
Perspective

Positive integers

For every odd positive integer , the following equation holds:[3]

where is the n-th Euler Number. This yields:

For the values of the Dirichlet beta function at even positive integers no elementary closed form is known, and no method has yet been found for determining the arithmetic nature of even beta values (similarly to the Riemann zeta function at odd integers greater than 3). The number is known as Catalan's constant.

It has been proven that infinitely many numbers of the form [4] and at least one of the numbers are irrational.[5]

The even beta values may be given in terms of the polygamma functions and the Bernoulli numbers:[6]

We can also express the beta function for positive in terms of the inverse tangent integral:

For every positive integer k:[citation needed]

where is the Euler zigzag number.

More information s, approximate value β(s) ...
sapproximate value β(s)OEIS
10.7853981633974483096156608A003881
20.9159655941772190150546035A006752
30.9689461462593693804836348A153071
40.9889445517411053361084226A175572
50.9961578280770880640063194A175571
60.9986852222184381354416008A175570
70.9995545078905399094963465A258814
80.9998499902468296563380671A258815
90.9999496841872200898213589A258816
Close

Negative integers

For negative odd integers, the function is zero:

For every negative even integer it holds:[3]

.

It further is:

.

Derivative

We have:[3]

with being Euler's constant and being Catalan's constant. The last identity was derived by Malmsten in 1842.[2]

See also

References

Loading related searches...

Wikiwand - on

Seamless Wikipedia browsing. On steroids.