Kaniadakis statistics (also known as κ-statistics) is a generalization of Boltzmann–Gibbs statistical mechanics,[1] based on a relativistic[2][3][4] generalization of the classical Boltzmann–Gibbs–Shannon entropy (commonly referred to as Kaniadakis entropy or κ-entropy). Introduced by the Greek Italian physicist Giorgio Kaniadakis in 2001,[5] κ-statistical mechanics preserve the main features of ordinary statistical mechanics and have attracted the interest of many researchers in recent years. The κ-distribution is currently considered one of the most viable candidates for explaining complex physical,[6][7] natural or artificial systems involving power-law tailed statistical distributions. Kaniadakis statistics have been adopted successfully in the description of a variety of systems in the fields of cosmology, astrophysics,[8][9] condensed matter, quantum physics,[10][11] seismology,[12][13] genomics,[14][15] economics,[16][17] epidemiology,[18] and many others.

Mathematical formalism

The mathematical formalism of κ-statistics is generated by κ-deformed functions, especially the κ-exponential function.

κ-exponential function

Plot of the κ-exponential function for three different κ-values. The solid black curve corresponding to the ordinary exponential function ().

The Kaniadakis exponential (or κ-exponential) function is a one-parameter generalization of an exponential function, given by:

with .

The κ-exponential for can also be written in the form:

The first five terms of the Taylor expansion of are given by:

where the first three are the same as a typical exponential function.

Basic properties

The κ-exponential function has the following properties of an exponential function:

For a real number , the κ-exponential has the property:

.

κ-logarithm function

Plot of the κ-logarithmic function for three different κ-values. The solid black curve corresponding to the ordinary logarithmic function ().

The Kaniadakis logarithm (or κ-logarithm) is a relativistic one-parameter generalization of the ordinary logarithm function,

with , which is the inverse function of the κ-exponential:

The κ-logarithm for can also be written in the form:

The first three terms of the Taylor expansion of are given by:

following the rule

with , and

where and . The two first terms of the Taylor expansion of are the same as an ordinary logarithmic function.

Basic properties

The κ-logarithm function has the following properties of a logarithmic function:

For a real number , the κ-logarithm has the property:

κ-Algebra

κ-sum

For any and , the Kaniadakis sum (or κ-sum) is defined by the following composition law:

,

that can also be written in form:

,

where the ordinary sum is a particular case in the classical limit : .

The κ-sum, like the ordinary sum, has the following properties:

The κ-difference is given by .

The fundamental property arises as a special case of the more general expression below:

Furthermore, the κ-functions and the κ-sum present the following relationships:

κ-product

For any and , the Kaniadakis product (or κ-product) is defined by the following composition law:

,

where the ordinary product is a particular case in the classical limit : .

The κ-product, like the ordinary product, has the following properties:

The κ-division is given by .

The κ-sum and the κ-product obey the distributive law: .

The fundamental property arises as a special case of the more general expression below:

Furthermore, the κ-functions and the κ-product present the following relationships:

κ-Calculus

κ-Differential

The Kaniadakis differential (or κ-differential) of is defined by:

.

So, the κ-derivative of a function is related to the Leibniz derivative through:

,

where is the Lorentz factor. The ordinary derivative is a particular case of κ-derivative in the classical limit .

κ-Integral

The Kaniadakis integral (or κ-integral) is the inverse operator of the κ-derivative defined through

,

which recovers the ordinary integral in the classical limit .

κ-Trigonometry

κ-Cyclic Trigonometry

Plot of the κ-sine and κ-cosine functions for  {\displaystyle \kappa =0}  (black curve) and  {\displaystyle \kappa =0.1}  (blue curve).
[click on the figure] Plot of the κ-sine and κ-cosine functions for (black curve) and (blue curve).

The Kaniadakis cyclic trigonometry (or κ-cyclic trigonometry) is based on the κ-cyclic sine (or κ-sine) and κ-cyclic cosine (or κ-cosine) functions defined by:

,
,

where the κ-generalized Euler formula is

.:

The κ-cyclic trigonometry preserves fundamental expressions of the ordinary cyclic trigonometry, which is a special case in the limit κ → 0, such as:

.

The κ-cyclic tangent and κ-cyclic cotangent functions are given by:

.

The κ-cyclic trigonometric functions become the ordinary trigonometric function in the classical limit .

κ-Inverse cyclic function

The Kaniadakis inverse cyclic functions (or κ-inverse cyclic functions) are associated to the κ-logarithm:

,
,
,
.

κ-Hyperbolic Trigonometry

The Kaniadakis hyperbolic trigonometry (or κ-hyperbolic trigonometry) is based on the κ-hyperbolic sine and κ-hyperbolic cosine given by:

,
,

where the κ-Euler formula is

.

The κ-hyperbolic tangent and κ-hyperbolic cotangent functions are given by:

.

The κ-hyperbolic trigonometric functions become the ordinary hyperbolic trigonometric functions in the classical limit .

From the κ-Euler formula and the property the fundamental expression of κ-hyperbolic trigonometry is given as follows:

κ-Inverse hyperbolic function

The Kaniadakis inverse hyperbolic functions (or κ-inverse hyperbolic functions) are associated to the κ-logarithm:

,
,
,
,

in which are valid the following relations:

,
,
.

The κ-cyclic and κ-hyperbolic trigonometric functions are connected by the following relationships:

,
,
,
,
,
,
,
.

Kaniadakis entropy

The Kaniadakis statistics is based on the Kaniadakis κ-entropy, which is defined through:

where is a probability distribution function defined for a random variable , and is the entropic index.

The Kaniadakis κ-entropy is thermodynamically and Lesche stable[19][20] and obeys the Shannon-Khinchin axioms of continuity, maximality, generalized additivity and expandability.

Kaniadakis distributions

A Kaniadakis distribution (or κ-distribution) is a probability distribution derived from the maximization of Kaniadakis entropy under appropriate constraints. In this regard, several probability distributions emerge for analyzing a wide variety of phenomenology associated with experimental power-law tailed statistical distributions.

κ-Exponential distribution

κ-Gaussian distribution

κ-Gamma distribution

κ-Weibull distribution

κ-Logistic distribution

Kaniadakis integral transform

κ-Laplace Transform

The Kaniadakis Laplace transform (or κ-Laplace transform) is a κ-deformed integral transform of the ordinary Laplace transform. The κ-Laplace transform converts a function of a real variable to a new function in the complex frequency domain, represented by the complex variable . This κ-integral transform is defined as:[21]

The inverse κ-Laplace transform is given by:

The ordinary Laplace transform and its inverse transform are recovered as .

Properties

Let two functions and , and their respective κ-Laplace transforms and , the following table presents the main properties of κ-Laplace transform:[21]

Properties of the κ-Laplace transform
Property
Linearity
Time scaling
Frequency shifting
Derivative
Derivative
Time-domain integration
Dirac delta-function
Heaviside unit function
Power function
Power function
Power function

The κ-Laplace transforms presented in the latter table reduce to the corresponding ordinary Laplace transforms in the classical limit .

κ-Fourier Transform

The Kaniadakis Fourier transform (or κ-Fourier transform) is a κ-deformed integral transform of the ordinary Fourier transform, which is consistent with the κ-algebra and the κ-calculus. The κ-Fourier transform is defined as:[22]

which can be rewritten as

where and . The κ-Fourier transform imposes an asymptotically log-periodic behavior by deforming the parameters and in addition to a damping factor, namely .

Real (top panel) and imaginary (bottom panel) part of the kernel for typical -values and .

The kernel of the κ-Fourier transform is given by:

The inverse κ-Fourier transform is defined as:[22]

Let , the following table shows the κ-Fourier transforms of several notable functions:[22]

κ-Fourier transform of several functions
Step function
Modulation
Causal -exponential
Symmetric -exponential
Constant
-Phasor
Impuslse
Signum Sgn
Rectangular

The κ-deformed version of the Fourier transform preserves the main properties of the ordinary Fourier transform, as summarized in the following table.

κ-Fourier properties
Linearity
Scaling
where and
-Scaling
Complex conjugation
Duality
Reverse
-Frequency shift
-Time shift
Transform of -derivative
-Derivative of transform
Transform of integral
-Convolution
where
Modulation

The properties of the κ-Fourier transform presented in the latter table reduce to the corresponding ordinary Fourier transforms in the classical limit .

See also

References

  •  This article incorporates text available under the CC BY 3.0 license.
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