Mittag-Leffler function

In mathematics, the Mittag-Leffler function $$E_{\alpha,\beta}$$ is a special function, a complex function which depends on two complex parameters $$\alpha$$ and $$\beta$$. It may be defined by the following series when the real part of $$\alpha$$ is strictly positive:


 * $$E_{\alpha, \beta} (z) = \sum_{k=0}^\infty \frac{z^k}{\Gamma(\alpha k + \beta)},$$

where $$\Gamma(x) $$ is the gamma function. When $$\beta=1$$, it is abbreviated as $$E_\alpha(z) = E_{\alpha,1}(z)$$. For $$\alpha=0$$, the series above equals the Taylor expansion of the geometric series and consequently $$E_{0,\beta}(z)=\frac{1}{\Gamma(\beta)}\frac{1}{1-z}$$.

In the case $$\alpha$$ and $$\beta$$ are real and positive, the series converges for all values of the argument $$z$$, so the Mittag-Leffler function is an entire function. This function is named after Gösta Mittag-Leffler. This class of functions are important in the theory of the fractional calculus.

For $$\alpha >0 $$, the Mittag-Leffler function $$E_{\alpha,1}(z)$$ is an entire function of order $$1/\alpha$$, and is in some sense the simplest entire function of its order.

The Mittag-Leffler function satisfies the recurrence property (Theorem 5.1 of )


 * $$E_{\alpha,\beta}(z)=\frac{1}{z}E_{\alpha,\beta-\alpha}(z)-\frac{1}{z \Gamma(\beta-\alpha)},$$

from which the following Poincaré asymptotic expansion holds : for $$0<\alpha<2$$ and $$\mu$$ real such that $$\frac{\pi\alpha}{2} < \mu < \min(\pi, \pi\alpha)$$ then for all $$N\in\mathbb{N}^*, N\neq 1$$, we can show the following asymptotic expansions (Section 6. of ):

-as $$\,|z|\to+\infty, |\text{arg}(z)|\leq \mu$$:


 * $$E_{\alpha}(z) = \frac{1}{\alpha} \exp(z^{\frac{1}{\alpha}}) - \sum\limits_{k=1}^{N} \frac{1}{z^k\, \Gamma(1-\alpha k)} + O\left(\frac{1}{z^{N+1}}\right)$$,

-and as $$\,|z|\to+\infty, \mu\leq|\text{arg}(z)|\leq\pi$$:


 * $$E_{\alpha}(z) = - \sum\limits_{k=1}^N \frac{1}{z^k\Gamma(1-\alpha k)} + O\left(\frac{1}{z^{N+1}}\right)$$,

where we used the notation $$E_{\alpha}(z) = E_{\alpha, 1}(z)$$.

The Mittag-Leffler function, characterized by three parameters, is expressed as follows:

$$E_{\alpha,\beta}^\gamma(z)=\left ( \frac{1}{\Gamma(\gamma)} \right )\sum\limits_{k=1}^\infty \frac{\Gamma(\gamma + k)z^k}{k! \Gamma(\alpha k + \beta ) },$$

where $$\alpha, \beta$$ and $$\gamma$$ are complex parameters and $$\Re(\alpha)>0$$.

For $$\gamma \in \mathbb{N}$$, the Mittag-Leffler function with three parameters is reformulated as:

$$E_{\alpha, \beta}^{\gamma}(z) = \sum_{k=0}^{\infty} \frac{(\gamma)_k z^k}{k!\Gamma(\alpha k + \beta)}, $$

where $$(\gamma)_k := \frac{\Gamma(\gamma+k)}{\Gamma(\gamma)} = \gamma(\gamma+1) \cdots (\gamma+k-1) $$ and it exhibits the following property:

$$E_{(\alpha, \beta)}^{\gamma}(z) = \frac{1}{\alpha^\gamma} \left(E_{(\alpha, \beta-1)}^{\gamma-1}(z) + (1-\beta + \alpha\gamma)E_{(\alpha, \beta)}^{\gamma-1}(z)\right)$$.

Additionally, a relation concerning the first parameter of the 2-parameter Mittag-Leffler function is as follows:$$E_{(\alpha, \beta)}(r t^\alpha) = \frac{1}{m} \sum_{i=1}^{m} E_{(\rho, \beta)}(s_i t^\rho),$$

where $$\frac{\alpha}{\rho} = m \in \mathbb{N}$$ and $$s_i $$ are roots of $$s^m = r$$.

Special cases
For $$\alpha=0,1/2,1,2$$ we find: (Section 2 of )

Error function:


 * $$E_{\frac{1}{2}}(z) = \exp(z^2)\operatorname{erfc}(-z).$$

The sum of a geometric progression:
 * $$E_{0}(z) = \sum_{k=0}^\infty z^k = \frac{1}{1-z},\, |z|<1.$$

Exponential function:
 * $$E_{1}(z) = \sum_{k=0}^\infty \frac{z^k}{\Gamma (k + 1)} = \sum_{k=0}^\infty \frac{z^k}{k!} = \exp(z).$$

Hyperbolic cosine:
 * $$E_{2}(z) = \cosh(\sqrt{z}), \text{ and } E_{2}(-z^2) = \cos(z).$$

For $$\beta=2$$, we have


 * $$E_{1,2}(z) = \frac{e^z-1}{z},$$
 * $$E_{2,2}(z) = \frac{\sinh(\sqrt{z})}{\sqrt{z}}.$$

For $$\alpha=0,1,2$$, the integral


 * $$\int_0^z E_{\alpha}(-s^2) \, {\mathrm d}s$$

gives, respectively: $$\arctan(z)$$, $$\tfrac{\sqrt{\pi}}{2}\operatorname{erf}(z)$$, $$\sin(z)$$.

Mittag-Leffler's integral representation
The integral representation of the Mittag-Leffler function is (Section 6 of )


 * $$E_{\alpha,\beta}(z)=\frac{1}{2\pi i}\oint_C \frac{t^{\alpha-\beta}e^t}{t^\alpha-z} \, dt,

\Re(\alpha)>0, \Re(\beta)>0,$$

where the contour $$C$$ starts and ends at $$-\infty$$ and circles around the singularities and branch points of the integrand.

Related to the Laplace transform and Mittag-Leffler summation is the expression (Eq (7.5) of with $$m=0$$)


 * $$\int_0^{\infty}e^{-t z} t^{\beta-1} E_{\alpha,\beta}(\pm r\, t^\alpha) \,dt

= \frac{z^{\alpha-\beta}}{z^{\alpha}\mp r}, \Re(z)>0, \Re(\alpha)>0, \Re(\beta)>0.$$

Applications of Mittag-Leffler function
One of the applications of the Mittag-Leffler function is in modeling fractional order viscoelastic materials. Experimental investigations into the time-dependent relaxation behavior of viscoelastic materials are characterized by a very fast decrease of the stress at the beginning of the relaxation process and an extremely slow decay for large times. It can even take a long time before a constant asymptotic value is reached. Therefore, a lot of Maxwell elements are required to describe relaxation behavior with sufficient accuracy. This ends in a difficult optimization problem in order to identify a large number of material parameters. On the other hand, over the years, the concept of fractional derivatives has been introduced to the theory of viscoelasticity. Among these models, the fractional Zener model was found to be very effective to predict the dynamic nature of rubber-like materials with only a small number of material parameters. The solution of the corresponding constitutive equation leads to a relaxation function of the Mittag-Leffler type. It is defined by the power series with negative arguments. This function represents all essential properties of the relaxation process under the influence of an arbitrary and continuous signal with a jump at the origin.