Formulas
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* [http://socr.ucla.edu/htmls/dist/HyperbolicSecant_Distribution.html Standard Cauchy to Hyperbolic Secant]: <math> \frac{log|x|}{\pi} \ </math> | * [http://socr.ucla.edu/htmls/dist/HyperbolicSecant_Distribution.html Standard Cauchy to Hyperbolic Secant]: <math> \frac{log|x|}{\pi} \ </math> | ||
* [http://socr.ucla.edu/htmls/dist/Standard_Power.html Beta to Standard Power]: <math> \alpha=\beta, \beta=1 \ </math> | * [http://socr.ucla.edu/htmls/dist/Standard_Power.html Beta to Standard Power]: <math> \alpha=\beta, \beta=1 \ </math> | ||
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* [http://en.wikipedia.org/wiki/Pascal Power series to Pascal]: <math> A(c)=(1-c)^{-x}, c=1-p \ </math> | * [http://en.wikipedia.org/wiki/Pascal Power series to Pascal]: <math> A(c)=(1-c)^{-x}, c=1-p \ </math> | ||
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* [http://en.wikipedia.org/wiki/Pacal Gamma Poisson to Pascal]: <math> \alpha=(1-p)/p, \beta=n \ </math> | * [http://en.wikipedia.org/wiki/Pacal Gamma Poisson to Pascal]: <math> \alpha=(1-p)/p, \beta=n \ </math> | ||
* [http://en.wikipedia.org/wiki/Gamma_Poisson Poisson to Gamma Poisson]: <math> \mu \sim gamma \ </math> | * [http://en.wikipedia.org/wiki/Gamma_Poisson Poisson to Gamma Poisson]: <math> \mu \sim gamma \ </math> | ||
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* [http://en.wikipedia.org/wiki/standard_normal normal to standard normal]: <math> \mu=0, \sigma=1\ </math> | * [http://en.wikipedia.org/wiki/standard_normal normal to standard normal]: <math> \mu=0, \sigma=1\ </math> | ||
* [http://en.wikipedia.org/wiki/Noncentral_chi-square normal to noncentral_chi-square]: <math> \sum{X_i^2/{\sigma}^2}\ </math> | * [http://en.wikipedia.org/wiki/Noncentral_chi-square normal to noncentral_chi-square]: <math> \sum{X_i^2/{\sigma}^2}\ </math> | ||
| + | * [http://socr.ucla.edu/htmls/dist/ChiSquare_Distribution.html Normal to Chi-square]: <math> (iid) \sum (\frac{x_i-\mu}{\sigma})^2\ </math> | ||
| + | * [http://socr.ucla.edu/htmls/dist/Normal_Distribution.html Beta to Normal]: <math> \beta=\gamma \to \infty \ </math> | ||
| + | * [http://socr.ucla.edu/htmls/dist/Normal_Distribution.html Normal to Gamma-normal]: <math> \sigma \sim Inverted gamma \ </math> | ||
| + | * [http://socr.ucla.edu/htmls/dist/Cauchy_Distribution.html Standard Normal to Standard Cauchy]: <math> \frac{X_1}{X_2} \ </math> | ||
| + | * [http://socr.ucla.edu/htmls/dist/Normal_Distribution.html Inverse Gaussian to Standard normal]: <math> \lambda \to \infty \ </math> | ||
* [http://socr.ucla.edu/htmls/dist/ChiSquare_Distribution.html Noncentral chi-square to Chi-square]: <math> \delta=0 \ </math> | * [http://socr.ucla.edu/htmls/dist/ChiSquare_Distribution.html Noncentral chi-square to Chi-square]: <math> \delta=0 \ </math> | ||
* [http://socr.ucla.edu/htmls/dist/Gamma_Distribution.html Gamma to Log gamma]:<math> log X \ </math> | * [http://socr.ucla.edu/htmls/dist/Gamma_Distribution.html Gamma to Log gamma]:<math> log X \ </math> | ||
Revision as of 19:36, 6 May 2010
Probability Density Functions (PDFs)
- Standard Normal PDF:
- General Normal PDF:
- Chi-Square PDF:
- Gamma PDF:
- Beta PDF:
- Student's T PDF:
- Poisson PDF:
- Chi PDF:
- Cauchy PDF:
![\frac{1}{\pi\gamma \left[1 + \left(\frac{x-x_0}{\gamma}\right)^2\right]}](/socr/uploads/math/a/9/2/a9260c6814d86ac3231f3934db752577.png)
- Exponential PDF:
- F Distribution PDF:
- Bernoulli PMF:
- Binomial PMF:
- Multinomial PMF:
, where 
, 
, and 
.
- Negative Binomial PMF:
- Negative-Multinomial Binomial PMF:
- Geometric PMF:
- Erlang PDF:
- Laplace PDF:
- Continuous Uniform PDF:
- Discrete Uniform PMF:
- Logarithmic PDF:
- Logistic PDF:
- Logistic-Exponential PDF:
- Power Function PDF:
- Benford's Law:
- Pareto PDF:
- Non-Central Student T PDF:
![f(t)=\frac{\nu^{\nu/2}e^{-\nu\mu^2/2(t^2+\nu)}} {\sqrt{\pi}\Gamma(\nu/2)2^{(\nu-1)/2}(t^2+\nu)^{(\nu+1)/2}} \times\int\limits_0^\infty x^\nu\exp\left[-\frac{1}{2}\left(x-\frac{\mu t}{\sqrt{t^2+\nu}}\right)^2\right]dx](/socr/uploads/math/e/3/7/e37a9ea8dea4ca3d0d7d55f76aaa430b.png)
- ArcSine PDF:
- Circle PDF:
![f(x)={2\sqrt{r^2 - x^2}\over \pi r^2 }, \forall x \in [-r , r]](/socr/uploads/math/4/5/a/45a7876ef35972bf28385be926c52b62.png)
- U-Quadratic PDF:
- Standard Uniform PDF:
- Zipf:
- Inverse Gamma:
- Fisher-Tippett:
where
- Gumbel:
- HyperGeometric:
- Log-Normal:
![\frac{1}{x\sigma\sqrt{2\pi}}\exp\left[-\frac{\left(\ln(x)-\mu\right)^2}{2\sigma^2}\right]](/socr/uploads/math/b/3/f/b3f2a95779f28c24a5a265ba6498ceec.png)
- Gilbrats:
![\frac{1}{\sigma\sqrt{2\pi}}\exp\left[-\frac{\left(\ln(x)\right)^2}{2\sigma^2}\right]](/socr/uploads/math/d/0/3/d03d955b51d917ba307deef3c7e277a0.png)
- Hyperbolic Secant:
- Gompertz:
![b e^{-bx} e^{-\eta e^{-bx}}\left[1 + \eta\left(1 - e^{-bx}\right)\right]](/socr/uploads/math/4/e/f/4efe11d1016f67a67761bf1697fb5a9b.png)
- Standard Cauchy:
- Rectangular:
- Beta-Binomial:
- Negative Hypergeometric:
- Standard Power:
- Power_Series:
- Zeta:
- Logarithm:
- Beta_Pascal:
- Gamma_Poisson:
- Pascal:
- Polya:
- Normal-Gamma:
- Discrete_Weibull:
- Log Gamma:
![f(x)=[1/ \alpha^\beta \Gamma(\beta)]e^{\beta x}e^{-e^x/a}. (-\infty<x<\infty) \!](/socr/uploads/math/7/c/4/7c4a06b45d1e495c5a95fa4c34eb7e01.png)
- Generalized Gamma:
- Noncentral-Beta:
- Inverse Gausian:
- Noncentral_chi-square:
- Standard Wald:
- Inverted Beta:
- Arctangent:
![f(x; \lambda, \phi)= \frac{\lambda}{[arctan(\lambda \phi)+\pi/2][1+\lambda^2 (x - \phi)^2]} (x \geq 0, -\infty < \lambda < \infty) \!](/socr/uploads/math/7/6/d/76da984a4dca1594e390bcd6708e18cd.png)
- Makeham:
- Hypoexponential:
- Doubly Noncentral t:
- Hyperexponential:
- Muth:
- Error:
![f(x) = \frac{exp[-(|x-a|/b)^{2/c}/2]}{b 2^{c/2+1}\Gamma(1+c/2)}. -\infty < x < \infty \!](/socr/uploads/math/6/e/4/6e42fd0f037ed8770a2702cb2d94ffe0.png)
- Minimax:
- Noncentral F:
- IDB:
- Standard Power:
- Rayleigh:
- Standard Triangular:
- Doubly noncentral F:
![f(x)= \sum_{j=0}^{\infty}\sum_{k=0}^{\infty}[\frac{e^{-\delta/2}(\frac{1}{2}\delta)^j}{j!}][\frac{e^{-\gamma/2}(\frac{1}{2}\gamma)^k}{k!}]\times n_1^{(n_1/2)+j}n_2^{(n_2/2)+k}x^{(n_1/2)+j-1}\times (n_2+n_1 x)^{-\frac{1}{2}(n_1+n_2)-j-k}\times [B(\frac{1}{2}n_1+j,\frac{1}{2}n_2+k)]^{-1}. x>0 \!](/socr/uploads/math/d/8/8/d888b49a4abc96cf20e931e233f1d9c7.png)
- Power:
- Weibull:
![f(x)=(\beta/\alpha)x^{\beta-1}exp[-(1/\alpha)x^\beta]. x>0 \!](/socr/uploads/math/0/d/c/0dc3d3e9bdecd2f48c9af39fcc40692d.png)
- Log-logistic:
![f(x)=\frac{\lambda \kappa(\lambda x)^{\kappa-1}}{[1+(\lambda x)^\kappa]^2}. x>0 \!](/socr/uploads/math/1/c/d/1cd47902dd18fe543bc4fd2e55f98c76.png)
- TSP:
- Extreme value:
- Lomax:
- von Mises:
- Generalized Pareto:
- Triangular:
- Kolmogorov-Smirnov:
- Exponential Power:
Transformations
- Standard Normal to General Normal Transformation:
- General Normal to Standard Normal Transformation:
- Standard Normal to Chi Transformation:
- Standard Normal to Chi-Square Transformation:
- Gamma to General Normal Transformation:
- Gamma to Exponential Transformation: The special case of
is equivalent to exponential Exp(λ).
- Gamma to Beta Transformation:
.
- Student's T to Standard Normal Transformation:
- Student's T to Cauchy Transformation:
- Cauchy to General Cauchy Transformation:
- General Cauchy to Cauchy Transformation:
- Fisher's F to Student's T:
- Student's T to Fisher's F: X2
- Bernoulli to Binomial Transformation:
(iid)
- Binomial to Bernoulli Transformation:
- Binomial to General Normal Transformation:
- Binomial to Poisson Transformation:
- Multinomial to Binomial Transformation:
- Negative Binomial to Geometric Transformation:
- Erlang to Exponential Transformation:
- Erlang to Chi-Square Transformation:
- Laplace to Exponential Transformation:
- Exponential to Laplace Transformation:
- Beta to Arcsine Transformation:
- Noncentral Student's T to Normal Transformation:
- Noncentral Student's T to Student's T Transformation:
- Standard Uniform to Pareto Transformation:
- Standard Uniform to Benford Transformation:
- Standard Uniform to Exponential Transformation:
- Standard Uniform to Log Logistic Transformation:
- Standard Uniform to Standard Triangular Transformation: X1 − X2
- Standard Uniform to Logistic Exponential Transformation:
![\frac{log[1+(\frac{X}{1-X})^{1/K}]}{\lambda}](/socr/uploads/math/b/b/1/bb14e96da3be11b8bee63fcfbb54fefa.png)
- Standard Uniform to Beta Transformation: If X has a standard uniform distribution,
has a beta distribution
- Beta to Standard Uniform Transformation: β = γ = 1
- Continuous Uniform to Standard Uniform Transformation:
- Pareto to Exponential:
- Logistic Exponential to Exponential:
- Zipf to Discrete Uniform:
- Discrete Uniform to Rectangular:
- Poisson to Normal:
- Binomial to Poisson:
- Gamma to Inverted Gamma:
- Fisher-Tippett to Gumbel:
- Hypergeometric to Binomial:
- Log-Normal to Normal:
- Normal to Log-Normal:
- Log-Normal to Gibrat's:
- Cauchy to Standard Cauchy:
- Standard Cauchy to Cauchy:
- Standard Cauchy to Hyperbolic Secant:
- Beta to Standard Power:
- Power series to Pascal:
- Gamma Poisson to Pascal:
- Poisson to Gamma Poisson:
- Discrete uniform to Rectangular:
- beta binomial to rectangular:
- beta binomial to negative hypergeometric:
- Zipf to Zeta:
- Power series to Logarithm:
- Power series to Poisson:
- Pascal to Beta pascal:
- pascal to poisson:
- binomial to beta binomial:
- negative hypergeometric to binomial:
- Polya to Binomial:
- Pascal to geometric:
- geometric to pascal:
- discrete weibull to geometric:
- pascal to normal:
- normal to standard normal:
- normal to noncentral_chi-square:
- Normal to Chi-square:
- Beta to Normal:
- Normal to Gamma-normal:
- Standard Normal to Standard Cauchy:
- Inverse Gaussian to Standard normal:
- Noncentral chi-square to Chi-square:
- Gamma to Log gamma:
- Generalized gamma to Log normal:
- Generalized gamma to Gamma:
- Inverse Gaussian to Standard Wald:
- Inverse Gaussian to Chi-square:
- Chi-square to Chi:
- Chi-square to F:
- F to Chi-square:
- Exponential to Chi-square:
- Chi-square to Exponential:
- Chi-square to Erlang:
- Gamma to Chi-square:
- Beta to Standard Uniform:
- Gamma to Erlang:
- SOCR Home page: http://www.socr.ucla.edu
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