Difference between revisions of "Manuals/calci/EXPONDIST"
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| Line 26: | Line 26: | ||
*This function is valid only on the interval [0,infinity]. | *This function is valid only on the interval [0,infinity]. | ||
The Cumulative Distribution Function is : | The Cumulative Distribution Function is : | ||
| − | <math>F(x;\lambda)=1-e^{-\lambda x}, | + | <math>F(x;\lambda)=\begin{cases} |
| − | + | 1-e^{-\lambda x}, & x \ge 0</math> | |
| + | 0 , & x<0 | ||
| + | \end{cases}</math> | ||
or | or | ||
:<math>F(x,\lambda)=1-e^{-\lambda x}.H(x)</math> | :<math>F(x,\lambda)=1-e^{-\lambda x}.H(x)</math> | ||
Revision as of 23:32, 10 December 2013
EXPONDIST(x,lambda,cu)
- is the value of the function
- is the value of the rate parameter
- is the logical value like TRUE or FALSE
is the value of the function
is the value of the rate parameter
is the logical value like TRUE or FALSEDescription
- This function gives the Exponential Distribution. This distribution is used to model the time until something happens in the process.
- This describes the time between events in a Poisson process i.e, a process in which events occur continuously and independently at a constant average rate.
- For e.g Time between successive vehicles arrivals at a workshop.
- In , is the value of the function, is called rate parameter and (cumulative) is the TRUE or FALSE.
- This function will give the Cumulative Distribution Function when is TRUE, otherwise it will give the Probability Density Function , when is FALSE.
- Suppose we are not giving the value, by default it will consider the value is FALSE.
- This function will give the error result when
, 
is called rate parameter and 1. or is non-numeric. 2. or
or 
The Probability Density Function of an Exponential Distribution is: or
or
- where is the rate parameter and is the Heaviside step function
- This function is valid only on the interval [0,infinity].
is the rate parameter and 
is the Heaviside step functionThe Cumulative Distribution Function is : Failed to parse (unknown function "\begin{cases}"): {\displaystyle F(x;\lambda)=\begin{cases} 1-e^{-\lambda x}, & x \ge 0} 0 , & x<0 \end{cases}</math> or
Examples
Question : If jobs arrive at an average of 15 seconds, per minute, what is the probability of waiting 30 seconds, i.e 0.5 min? Here and
per minute, what is the probability of waiting 30 seconds, i.e 0.5 min?
Here 
- =EXPONDIST(0.5,5,TRUE) = 0.917915001
- =EXPONDIST(5,3,TRUE) = 0.999999694
- =EXPONDIST(0.4,2,FALSE) = 0.898657928"