Erlang distribution

From Wikipedia, the free encyclopedia

(Redirected from Erlang-C)
Jump to: navigation, search
Erlang
Probability density function
Probability density plots of Erlang distributions
Cumulative distribution function
Cumulative distribution plots of Erlang distributions
Parameters k > 0\, shape (integer)
\lambda > 0\, rate (real)
alt.: \theta = 1/\lambda > 0\, scale (real)
Support x \in [0; \infty)\!
Probability density function (pdf) \frac{\lambda^k x^{k-1} e^{-\lambda x}}{(k-1)!\,}
Cumulative distribution function (cdf) \frac{\gamma(k, \lambda x)}{(k-1)!}=1-\sum_{n=0}^{k-1}e^{-\lambda x}(\lambda x)^{n}/n!
Mean k/\lambda\,
Median no simple closed form
Mode (k-1)/\lambda\, for k \geq 1\,
Variance k /\lambda^2\,
Skewness \frac{2}{\sqrt{k}}
Excess kurtosis \frac{6}{k}
Entropy k/\lambda+(k-1)\ln(\lambda)+\ln((k-1)!)\,
+(1-k)\psi(k)\,
Moment-generating function (mgf) (1 - t/\lambda)^{-k}\, for t < \lambda\,
Characteristic function (1 - it/\lambda)^{-k}\,

The Erlang distribution is a continuous probability distribution with wide applicability primarily due to its relation to the exponential and Gamma distributions. The Erlang distribution was developed by A. K. Erlang to examine the number of telephone calls which might be made at the same time to the operators of the switching stations. This work on telephone traffic engineering has been expanded to consider waiting times in queueing systems in general. The distribution is now used in the field of stochastic processes.

Contents

The distribution is a continuous distribution, which has a positive value for all real numbers greater than zero, and is given by two parameters: the shape k, which is an integer, and the rate λ, which is a real number. The distribution is sometimes defined using the inverse of the rate parameter, the scale θ.

When the shape parameter k equals 1, the distribution simplifies to the exponential distribution.

The Erlang distribution is a special case of the Gamma distribution where the shape parameter k is an integer. In the Gamma distribution, this parameter is a real number.

The probability density function of the Erlang distribution is

f(x; k,\lambda)={\lambda^k x^{k-1} e^{-\lambda x} \over (k-1)!}\quad\mbox{for }x>0.

where e is the base of the natural logarithm and ! is the factorial function. The parameter k is called the shape parameter and the parameter λ is called the rate parameter. An alternative, but equivalent, parametrization uses the scale parameter θ which is simply the inverse of the rate parameter (i.e. θ = 1 / λ):

f(x; k,\theta)=\frac{ x^{k-1} e^{-\frac{x}{\theta}} }{\theta^k(k-1)!}\quad\mbox{for }x>0.

Because of the factorial function in the denominator, the Erlang distribution is only defined when the parameter k is a positive integer. In fact, this distribution is sometimes called the Erlang-k distribution (e.g., an Erlang-2 distribution is an Erlang distribution with k=2). The Gamma distribution generalizes the Erlang by allowing its first parameter to be a real, using the gamma function instead of the factorial function.

The cumulative distribution function of the Erlang distribution is

F(x; k,\lambda) = \frac{\gamma(k, \lambda x)}{(k-1)!}

where γ() is the lower incomplete gamma function. The CDF may also be expressed as

F(x; k,\lambda) = 1-\sum_{n=0}^{k-1}e^{-\lambda x}(\lambda x)^{n}/n!

Events which occur independently with some average rate are modeled with a Poisson process. The waiting times between k occurrences of the event are Erlang distributed. (The related question of the number of events in a given amount of time is described by the Poisson distribution.)

The Erlang distribution, which measures the time between incoming calls, can be used in conjunction with the expected duration of incoming calls to produce information about the traffic load measured in Erlang units. This can be used to determine the probability of packet loss or delay, according to various assumptions made about whether blocked calls are aborted (Erlang B formula) or queued until served (Erlang C formula). The Erlang B and C formulas are still in everyday use for traffic modelling for applications such as the design of call centers.

The Erlang distribution also occurs as a description of the rate of transition of elements through a system of compartments. Such systems are widely used in biology and ecology.

The Erlang distribution is the distribution of the sum of k independent identically distributed random variables each having an exponential distribution.

 v  d  e Probability distributions
Univariate Multivariate
Discrete: Benford · Bernoulli · binomial · Boltzmann · categorical · compound Poisson · discrete phase-type · degenerate · Gauss-Kuzmin · geometric · hypergeometric · logarithmic · negative binomial · parabolic fractal · Poisson · Rademacher · Skellam · uniform · Yule-Simon · zeta · Zipf · Zipf-Mandelbrot Ewens · multinomial · multivariate Polya
Continuous: Beta · Beta prime · Cauchy · chi-square · Dirac delta function · Coxian · Erlang  · exponential · exponential power · F · fading · Fermi-Dirac · Fisher's z · Fisher-Tippett · Gamma · generalized extreme value · generalized hyperbolic · generalized inverse Gaussian · Half-logistic · Hotelling's T-square · hyperbolic secant · hyper-exponential · hypoexponential · inverse chi-square (scaled inverse chi-square) · inverse Gaussian · inverse gamma (scaled inverse gamma) · Kumaraswamy · Landau · Laplace · Lévy · Lévy skew alpha-stable · logistic · log-normal · Maxwell-Boltzmann · Maxwell speed · Nakagami · normal (Gaussian) · normal-gamma · normal inverse Gaussian · Pareto · Pearson · phase-type · polar · raised cosine · Rayleigh · relativistic Breit-Wigner · Rice · shifted Gompertz · Student's t · triangular · truncated normal · type-1 Gumbel · type-2 Gumbel · uniform · Variance-Gamma · Voigt · von Mises · Weibull · Wigner semicircle · Wilks' lambda Dirichlet · Generalized Dirichlet · inverse-Wishart · Kent · matrix normal · multivariate normal · multivariate Student · von Mises-Fisher · Wigner quasi · Wishart
Miscellaneous: bimodal · Cantor · conditional · equilibrium · exponential family · Infinite divisibility (probability) · location-scale family · marginal · maximum entropy · posterior · prior · quasi · sampling · singular  · unimodal

Retrieved from "http://en.wikipedia.org/wiki/Erlang_distribution"
Advanced Search
Included Web Search Engines


Safe Search

close

Top Matching Results

Occasionally Search.com will highlight specialized results that are based on the context of your query. Examples of specialized results include specific links to news, images, or video.

Top Matching Results may highlight information from other Search.com pages, content from the CNET Network of sites, or third party content. The listings are based purely on relevance. Search.com does not receive payment for listings in this section but our partners that provide this data may get paid for listing these products.

Sponsored Links

This section contains paid listings which have been purchased by companies that want to have their sites appear for specific search terms and related content. These listings are administered, sorted and maintained by a third party and are not endorsed by Search.com.

Search Results

Search.com sends your search query to several search engines at one time and integrates the results into one list which has been sorted by relevance using Search.com's proprietary algorithm. You can customize the list of search engines included in your metasearch from the preferences.

The search engines that are used in your metasearch may allow companies to pay to have their Web sites included within the results. To view the Paid Inclusion policy for a specific search engine, please visit their Web site. Search.com does not accept payment or share revenue with any search engine partner for listings in this section.