Logistic Distribution Example: Difference between revisions
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[math]\displaystyle{ \overset{{}}{\mathop{\text{Times-to-Failure Data with Suspensions}}}\, }[/math]
[math]\displaystyle{ \begin{matrix}
\text{Data Point Index} & \text{State F or S} & \text{State End Time} \\
\text{1} & \text{F} & \text{8} \\
\text{2} & \text{F} & \text{10} \\
\text{3} & \text{F} & \text{15} \\
\text{4} & \text{F} & \text{17} \\
\text{5} & \text{F} & \text{19} \\
\text{6} & \text{F} & \text{26} \\
\text{7} & \text{F} & \text{27} \\
\text{8} & \text{S} & \text{28} \\
\text{9} & \text{S} & \text{28} \\
\text{10} & \text{S} & \text{28} \\
\end{matrix} }[/math]
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{ | <noinclude>{{Banner Weibull Examples}} | ||
''This example appears in the [[The_Logistic_Distribution#General_Example|Life Data Analysis Reference book]]''.</noinclude> | |||
< | |||
<center><math>\overset{{}}{\mathop{\text{ | The lifetime of a mechanical valve is known to follow a logistic distribution. Ten units were tested for 28 months and the following months-to-failure data was collected. | ||
<center><math>\overset{{}}{\mathop{\text{Times-to-Failure Data with Suspensions}}}\,</math></center> | |||
<center><math>\begin{matrix} | <center><math>\begin{matrix} | ||
\text{Data Point Index} & \text{State F or S} & \text{State End Time} \\ | \text{Data Point Index} & \text{State F or S} & \text{State End Time} \\ | ||
| Line 20: | Line 20: | ||
\end{matrix}</math></center> | \end{matrix}</math></center> | ||
* Determine the valve's design life if specifications call for a reliability goal of 0.90. | |||
* The valve is to be used in a pumping device that requires 1 month of continuous operation. What is the probability of the pump failing due to the valve? | |||
Enter the data set in a Weibull++ standard folio, as follows: | |||
[[Image:Logistic Distribution Exmaple 1 Data.png|thumb|center|400px| ]] | [[Image:Logistic Distribution Exmaple 1 Data.png|thumb|center|400px| ]] | ||
| Line 34: | Line 36: | ||
\end{align}</math> | \end{align}</math> | ||
The valve's design life, along with 90% two sided confidence bounds, can be obtained using the QCP as follows: | |||
[[Image:Logistic Distribution Exmaple 1 QCP Reliable Life.png|thumb|center|400px| ]] | [[Image:Logistic Distribution Exmaple 1 QCP Reliable Life.png|thumb|center|400px| ]] | ||
The probability, along with 90% two sided confidence bounds, that the pump fails due to a valve failure during the first month is obtained as follows: | |||
[[Image:Logistic Distribution Exmaple 1 QCP Reliability.png|thumb|center|400px| ]] | [[Image:Logistic Distribution Exmaple 1 QCP Reliability.png|thumb|center|400px| ]] | ||
Revision as of 09:35, 23 July 2012
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This example appears in the Life Data Analysis Reference book.
The lifetime of a mechanical valve is known to follow a logistic distribution. Ten units were tested for 28 months and the following months-to-failure data was collected.
- Determine the valve's design life if specifications call for a reliability goal of 0.90.
- The valve is to be used in a pumping device that requires 1 month of continuous operation. What is the probability of the pump failing due to the valve?
Enter the data set in a Weibull++ standard folio, as follows:
The computed parameters for maximum likelihood are:
- [math]\displaystyle{ \begin{align} & \widehat{\mu }= & 22.34 \\ & \hat{\sigma }= & 6.15 \end{align} }[/math]
The valve's design life, along with 90% two sided confidence bounds, can be obtained using the QCP as follows:
The probability, along with 90% two sided confidence bounds, that the pump fails due to a valve failure during the first month is obtained as follows:
