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Normal-inverse Gaussian distribution
Continuous probability distribution
Continuous probability distribution
name =Normal-inverse Gaussian (NIG)| type =density| pdf_image =| cdf_image =| parameters =\mu location (real) \alpha tail heaviness (real) \beta asymmetry parameter (real) \delta scale parameter (real) \gamma = \sqrt{\alpha^2 - \beta^2}| support =x \in (-\infty; +\infty)!| pdf =\frac{\alpha\delta K_1 \left(\alpha\sqrt{\delta^2 + (x - \mu)^2}\right)}{\pi \sqrt{\delta^2 + (x - \mu)^2}} ; e^{\delta \gamma + \beta (x - \mu)}
K_j denotes a modified Bessel function of the second kind| cdf =| mean =\mu + \delta \beta / \gamma| median =| mode =| variance =\delta\alpha^2/\gamma^3| skewness = 3 \beta /\sqrt{\alpha^2\delta \gamma}| kurtosis =3(1+4 \beta^2/\alpha^2)/(\delta\gamma)| entropy =| mgf =e^{\mu z + \delta (\gamma - \sqrt{\alpha^2 -(\beta +z)^2})}| char =e^{i\mu z + \delta (\gamma - \sqrt{\alpha^2 -(\beta +iz)^2})}|
The normal-inverse Gaussian distribution (NIG, also known as the normal-Wald distribution) is a continuous probability distribution that is defined as the normal variance-mean mixture where the mixing density is the inverse Gaussian distribution. The NIG distribution was noted by Blaesild in 1977 as a subclass of the generalised hyperbolic distribution discovered by Ole Barndorff-Nielsen. In the next year Barndorff-Nielsen published the NIG in another paper. It was introduced in the mathematical finance literature in 1997.
The parameters of the normal-inverse Gaussian distribution are often used to construct a heaviness and skewness plot called the NIG-triangle.
Properties
Moments
The fact that there is a simple expression for the moment generating function implies that simple expressions for all moments are available.
Linear transformation
This class is closed under affine transformations, since it is a particular case of the Generalized hyperbolic distribution, which has the same property. If : x\sim\mathcal{NIG}(\alpha,\beta,\delta,\mu) \text{ and } y=ax+b, then : y\sim\mathcal{NIG}\bigl(\frac{\alpha}{\left|a\right|},\frac{\beta}{a},\left|a\right|\delta,a\mu+b\bigr).
Summation
This class is infinitely divisible, since it is a particular case of the Generalized hyperbolic distribution, which has the same property.
Convolution
The class of normal-inverse Gaussian distributions is closed under convolution in the following sense: if X_1 and X_2 are independent random variables that are NIG-distributed with the same values of the parameters \alpha and \beta, but possibly different values of the location and scale parameters, \mu_1, \delta_1 and \mu_2, \delta_2, respectively, then X_1 + X_2 is NIG-distributed with parameters \alpha, \beta, \mu_1+\mu_2 and \delta_1 + \delta_2.
Stochastic process
The normal-inverse Gaussian distribution can also be seen as the marginal distribution of the normal-inverse Gaussian process which provides an alternative way of explicitly constructing it. Starting with a drifting Brownian motion (Wiener process), W^{(\gamma)}(t)=W(t)+\gamma t, we can define the inverse Gaussian process A_t=\inf{s0:W^{(\gamma)}(s)=\delta t}. Then given a second independent drifting Brownian motion, W^{(\beta)}(t)=\tilde W(t)+\beta t, the normal-inverse Gaussian process is the time-changed process X_t=W^{(\beta)}(A_t). The process X(t) at time t=1 has the normal-inverse Gaussian distribution described above. The NIG process is a particular instance of the more general class of Lévy processes.
As a variance-mean mixture
Let \mathcal{IG} denote the inverse Gaussian distribution and \mathcal{N} denote the normal distribution. Let z\sim\mathcal{IG}(\delta,\gamma), where \gamma=\sqrt{\alpha^2-\beta^2}; and let x\sim\mathcal{N}(\mu+\beta z,z), then x follows the NIG distribution, with parameters, \alpha,\beta,\delta,\mu. This can be used to generate NIG variates by ancestral sampling. It can also be used to derive an EM algorithm for maximum-likelihood estimation of the NIG parameters.
References
References
- Ole E Barndorff-Nielsen, Thomas Mikosch and Sidney I. Resnick, Lévy Processes: Theory and Applications, Birkhäuser 2013 ''Note: in the literature this function is also referred to as Modified Bessel function of the third kind''
- Barndorff-Nielsen, Ole. (1977). "Exponentially decreasing distributions for the logarithm of particle size". The Royal Society.
- O. Barndorff-Nielsen, Hyperbolic Distributions and Distributions on Hyperbolae, Scandinavian Journal of Statistics 1978
- O. Barndorff-Nielsen, Normal Inverse Gaussian Distributions and Stochastic Volatility Modelling, Scandinavian Journal of Statistics 1997
- S.T Rachev, Handbook of Heavy Tailed Distributions in Finance, Volume 1: Handbooks in Finance, Book 1, North Holland 2003
- Erik Bolviken, Fred Espen Beth, Quantification of Risk in Norwegian Stocks via the Normal Inverse Gaussian Distribution, Proceedings of the AFIR 2000 Colloquium
- Anna Kalemanova, Bernd Schmid, Ralf Werner, The Normal inverse Gaussian distribution for synthetic CDO pricing, Journal of Derivatives 2007
- (2007). "Intermediate Probability: A computational Approach". John Wiley & Sons.
- Ole E Barndorff-Nielsen, Thomas Mikosch and Sidney I. Resnick, Lévy Processes: Theory and Applications, Birkhäuser 2013
- (2002). "An EM Type Algorithm for ML estimation for the Normal–Inverse Gaussian Distribution". Statistics and Probability Letters.
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