Difference between revisions of "AP Statistics Curriculum 2007 Beta"

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==[[AP_Statistics_Curriculum_2007 | General Advance-Placement (AP) Statistics Curriculum]] - Beta Distribution==
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===Beta Distribution===
 
===Beta Distribution===
 
'''Definition''': Beta distribution is a distribution that models events which are constrained to take place within an interval defined by a minimum and maximum value.  
 
'''Definition''': Beta distribution is a distribution that models events which are constrained to take place within an interval defined by a minimum and maximum value.  
  
<br />'''Probability density function''': For <math>X\sim Beta(\alpha,\beta)\!</math>, the Beta probability density function is given by
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<br />'''Probability density function''': For <math>X\sim \operatorname{Beta}(\alpha,\beta)\!</math>, the Beta probability density function is given by
  
 
:<math>\frac{x^{\alpha-1}(1-x)^{\beta-1}}{\Beta(\alpha,\beta)}</math>
 
:<math>\frac{x^{\alpha-1}(1-x)^{\beta-1}}{\Beta(\alpha,\beta)}</math>
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*<font size="3"><math>\alpha</math></font> is a positive shape parameter
 
*<font size="3"><math>\alpha</math></font> is a positive shape parameter
 
*<font size="3"><math>\beta</math></font> is a positive shape parameter
 
*<font size="3"><math>\beta</math></font> is a positive shape parameter
*<math>\textstyle\Beta(\alpha,\beta)=\int_0^1 t^{\alpha-1}(1-t)^{\beta-1}dt</math> or
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*<math>\textstyle\Beta(\alpha,\beta)=\int_0^1 t^{\alpha-1}(1-t)^{\beta-1}dt</math> or <br /><math>\textstyle\Beta(\alpha,\beta)=\frac{\Gamma(x)\Gamma(y)}{\Gamma(x+y)}</math>, where <math>\Gamma(k)!=(k-1)!=1 \times 2 \times\ 3 \times\cdots \times (k-1)</math>
:<math>\textstyle\Beta(\alpha,\beta)=\frac{\Gamma(x)\Gamma(y)}{\Gamma(x+y)}</math>, where <math>\Gamma(k)!=(k-1)!=1 \times 2 \times\ 3 \times\cdots \times (k-1)</math>
 
 
*x is a random variable
 
*x is a random variable
  
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*The time it takes to complete a task
 
*The time it takes to complete a task
 
*The proportion of defective items in a shipment
 
*The proportion of defective items in a shipment
 
  
 
===Example===
 
===Example===
Suppose that DVDs in a certain shipment are defective with a Beta distribution with α=2 and β=5. Compute the probability that the shipment has 20% to 30% defective DVDs.
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Suppose that DVDs in a certain shipment are defective with a Beta distribution with <font size="3"><math>\alpha=2</math></font> and <font size="3"><math>\beta=5</math></font>. Compute the probability that the shipment has 20% to 30% defective DVDs.
  
 
We can compute this as follows:   
 
We can compute this as follows:   
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The figure below shows this result using [http://socr.ucla.edu/htmls/dist/Beta_Distribution.html SOCR distributions]
 
The figure below shows this result using [http://socr.ucla.edu/htmls/dist/Beta_Distribution.html SOCR distributions]
 
<center>[[Image:Beta.jpg|600px]]</center>
 
<center>[[Image:Beta.jpg|600px]]</center>
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<hr>
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* SOCR Home page: http://www.socr.ucla.edu
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"{{translate|pageName=http://wiki.socr.umich.edu/index.php/AP_Statistics_Curriculum_2007_Beta}}

Latest revision as of 05:51, 4 April 2023

General Advance-Placement (AP) Statistics Curriculum - Beta Distribution

Beta Distribution

Definition: Beta distribution is a distribution that models events which are constrained to take place within an interval defined by a minimum and maximum value.


Probability density function: For \(X\sim \operatorname{Beta}(\alpha,\beta)\!\), the Beta probability density function is given by

\[\frac{x^{\alpha-1}(1-x)^{\beta-1}}{\Beta(\alpha,\beta)}\]

where

  • \(\alpha\) is a positive shape parameter
  • \(\beta\) is a positive shape parameter
  • \(\textstyle\Beta(\alpha,\beta)=\int_0^1 t^{\alpha-1}(1-t)^{\beta-1}dt\) or
    \(\textstyle\Beta(\alpha,\beta)=\frac{\Gamma(x)\Gamma(y)}{\Gamma(x+y)}\), where \(\Gamma(k)!=(k-1)!=1 \times 2 \times\ 3 \times\cdots \times (k-1)\)
  • x is a random variable


Cumulative density function: Beta cumulative distribution function is given by

\[\frac{\Beta_x(\alpha,\beta)}{\Beta(\alpha,\beta)}\]

where

  • \(\textstyle\Beta_x(\alpha,\beta)=\int_0^x t^{\alpha-1}(1-t)^{\beta-1}dt\)
  • \(\textstyle\Beta(\alpha,\beta)=\int_0^1 t^{\alpha-1}(1-t)^{\beta-1}dt\)


Moment generating function: The Beta moment-generating function is

\[M(t)=1+\sum_{k=1}^\infty (\prod_{r=0}^{k-1}\frac{\alpha+r}{\alpha+\beta+r})\frac{t^k}{k!}\]


Expectation: The expected value of a Beta distributed random variable x is

\[E(X)=\frac{\alpha}{\alpha+\beta}\]


Variance: The Beta variance is

\[Var(X)=\frac{\alpha\beta}{(\alpha+\beta)^2(\alpha+\beta+1)}\]

Applications

The Beta distribution is used in a range of disciplines including rule of succession, Bayesian statistics, and task duration modeling. Examples of events that may be modeled by Beta distribution include:

  • The time it takes to complete a task
  • The proportion of defective items in a shipment

Example

Suppose that DVDs in a certain shipment are defective with a Beta distribution with \(\alpha=2\) and \(\beta=5\). Compute the probability that the shipment has 20% to 30% defective DVDs.

We can compute this as follows:

\[P(0.2\le X\le 0.3)=\sum_{x=0.2}^{0.3}\frac{x^{2-1}(1-x)^{5-1}}{\Beta(2,5)}=0.235185\]

The figure below shows this result using SOCR distributions

Beta.jpg

"-----


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