Gamma process

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Also known as the (Moran-)Gamma Process,^[1] the gamma process is a random process studied in mathematics, statistics, probability theory, and stochastics. The gamma process is a stochastic or random process consisting of independently distributed gamma distributions where ${\displaystyle N(t)}$ represents the number of event occurrences from time 0 to time ${\displaystyle t}$. The gamma distribution has shape parameter ${\displaystyle \gamma }$ and rate parameter ${\displaystyle \lambda }$, often written as ${\displaystyle \Gamma (\gamma ,\lambda )}$.^[1] Both ${\displaystyle \gamma }$ and ${\displaystyle \lambda }$ must be greater than 0. The gamma process is often written as ${\displaystyle \Gamma (t,\gamma ,\lambda )}$ where ${\displaystyle t}$ represents the time from 0. The process is a pure-jump increasing Lévy process with intensity measure ${\displaystyle \nu (x)=\gamma x^{-1}\exp(-\lambda x),}$ for all positive ${\displaystyle x}$. Thus jumps whose size lies in the interval ${\displaystyle [x,x+dx)}$ occur as a Poisson process with intensity ${\displaystyle \nu (x)\,dx.}$ The parameter ${\displaystyle \gamma }$ controls the rate of jump arrivals and the scaling parameter ${\displaystyle \lambda }$ inversely controls the jump size. It is assumed that the process starts from a value 0 at t = 0 meaning ${\displaystyle N(0)=0}$.  

The gamma process is sometimes also parameterised in terms of the mean (${\displaystyle \mu }$) and variance (${\displaystyle v}$) of the increase per unit time, which is equivalent to ${\displaystyle \gamma =\mu ^{2}/v}$ and ${\displaystyle \lambda =\mu /v}$.

Plain English definition[edit]

The gamma process is a process which measures the number of occurrences of independent gamma-distributed variables over a span of time. This image below displays two different gamma processes on from time 0 until time 4. The red process has more occurrences in the timeframe compared to the blue process because its shape parameter is larger than the blue shape parameter.

Properties[edit]

We use the Gamma function in these properties, so the reader should distinguish between ${\displaystyle \Gamma (\cdot )}$ (the Gamma function) and ${\displaystyle \Gamma (t;\gamma ,\lambda )}$ (the Gamma process). We will sometimes abbreviate the process as ${\displaystyle X_{t}\equiv \Gamma (t;\gamma ,\lambda )}$.

Some basic properties of the gamma process are:^{[citation needed]}

Marginal distribution[edit]

The marginal distribution of a gamma process at time ${\displaystyle t}$ is a gamma distribution with mean ${\displaystyle \gamma t/\lambda }$ and variance ${\displaystyle \gamma t/\lambda ^{2}.}$

That is, the probability distribution ${\displaystyle f}$ of the random variable ${\displaystyle X_{t}}$ is given by the density

$${\displaystyle f(x;t,\gamma ,\lambda )={\frac {\lambda ^{\gamma t}}{\Gamma (\gamma t)}}x^{\gamma t\,-\,1}e^{-\lambda x}.}$$

Scaling[edit]

Multiplication of a gamma process by a scalar constant ${\displaystyle \alpha }$ is again a gamma process with different mean increase rate.

${\displaystyle \alpha \Gamma (t;\gamma ,\lambda )\simeq \Gamma (t;\gamma ,\lambda /\alpha )}$

Adding independent processes[edit]

The sum of two independent gamma processes is again a gamma process.

${\displaystyle \Gamma (t;\gamma _{1},\lambda )+\Gamma (t;\gamma _{2},\lambda )\simeq \Gamma (t;\gamma _{1}+\gamma _{2},\lambda )}$

Moments[edit]

The moment function helps mathematicians find expected values, variances, skewness, and kurtosis.

${\displaystyle \operatorname {E} (X_{t}^{n})=\lambda ^{-n}\cdot {\frac {\Gamma (\gamma t+n)}{\Gamma (\gamma t)}},\ \quad n\geq 0,}$ where ${\displaystyle \Gamma (z)}$ is the Gamma function.

Moment generating function[edit]

The moment generating function is the expected value of ${\displaystyle \exp(tX)}$ where X is the random variable.

${\displaystyle \operatorname {E} {\Big (}\exp(\theta X_{t}){\Big )}=\left(1-{\frac {\theta }{\lambda }}\right)^{-\gamma t},\ \quad \theta <\lambda }$

Correlation[edit]

Correlation displays the statistical relationship between any two gamma processes.

${\displaystyle \operatorname {Corr} (X_{s},X_{t})={\sqrt {\frac {s}{t}}},\ s<t}$, for any gamma process ${\displaystyle X(t).}$

The gamma process is used as the distribution for random time change in the variance gamma process.

Literature[edit]

• Lévy Processes and Stochastic Calculus by David Applebaum, CUP 2004, ISBN 0-521-83263-2.

References[edit]