Template:Characteristics of the exponential distribution alta: Difference between revisions

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[[Image:ALTA4pdf.png|center|200px]] <br>  
[[Image:ALTA4pdf.png|center|400px]] <br>  


:*The scale parameter is <math>\tfrac{1}{\lambda }</math> .  
:*The scale parameter is <math>\tfrac{1}{\lambda }</math> .  
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:*This ''pdf'' can be thought of as a special case of the Weibull ''pdf'' with <span class="texhtml">β = 1</span>.
:*This ''pdf'' can be thought of as a special case of the Weibull ''pdf'' with <span class="texhtml">β = 1</span>.


<br> [[Image:ALTA4reliabilityvstimeplot.png|center|200px]] <br>
<br> [[Image:ALTA4reliabilityvstimeplot.png|center|400px]] <br>


==== Effects of <span class="texhtml">λ</span> on the Reliability Function  ====
==== Effects of <span class="texhtml">λ</span> on the Reliability Function  ====

Revision as of 09:56, 25 June 2012

Characteristics

The characteristics of the 1-parameter exponential distribution can be exemplified by examining its parameter, lambda (λ) and the effect lambda has on the pdf, reliability and failure rate functions.

Effects of λ on the pdf



  • The scale parameter is [math]\displaystyle{ \tfrac{1}{\lambda } }[/math] .
  • As λ is decreased in value, the distribution is stretched out to the right, and as λ is increased, the distribution is pushed toward the origin.
  • This distribution has no shape parameter, as it has only one shape (i.e., the exponential). Its only parameter is the failure rate, λ .
  • The distribution starts at T = 0 at the level of f(T = 0) = λ. It decreases thereafter exponentially and monotonically as T increases, and it is convex.
  • As [math]\displaystyle{ T\to \infty }[/math] , [math]\displaystyle{ f(T)\to 0 }[/math].
  • This pdf can be thought of as a special case of the Weibull pdf with β = 1.


ALTA4reliabilityvstimeplot.png


Effects of λ on the Reliability Function

  • The 1-parameter exponential reliability function starts at the value of 1 at T = 0 . It decreases thereafter monotonically and is convex.
  • As [math]\displaystyle{ T\to \infty }[/math] , [math]\displaystyle{ R(T\to \infty )\to 0 }[/math].

Effects of λ on the Failure Rate Function

The failure rate function for the exponential distribution is constant and equal to the parameter λ .


ALTA4FRvsTP.png