Revision as of 18:24, 2 March 2011

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Expected Failure Time Plot

When a reliability life test is planned it is useful to visualize the expected outcome of the experiment. The Expected Failure Time Plot (introduced by ReliaSoft in Weibull++ 8)provides such visual.

Background & Calculations

Using the cumulative binomial, for a defined sample size, one can compute a rank (Median Rank if at 50% probability) for each ordered failure. As an example and for a sample size of 6 the 5%, 50% and 95% ranks would be as follows:

Table 1: 5%, 50% and 95% Ranks for a sample size of 6.
Order Number	5%	50%	95%
1	0.85%	10.91%	39.30%
2	6.29%	26.45%	58.18%
3	15.32%	42.14%	72.87%
4	27.13%	57.86%	84.68%
5	41.82%	73.55%	93.71%
6	60.70%	89.09%	99.15%

Furthermore, consider that for the units to be tested the underlying reliability model assumption is given by a Weibull distribution with $β = 2$ , and $η = 100$ hr. Then the median time to failure of the first unit on test can be determined by solving the Weibull reliability equation for t, at each probability,

or

then for 0.85%,

and so forths as shown in the table below:

Failure Order Number	Lowest Expected Time-to-failure (hr)	Median Expected Time-to-failure (hr)	Highest Expected Time-to-failure (hr)
1	9.25	33.99	70.66
2	25.48	55.42	93.37
3	40.77	73.97	114.21
4	56.26	92.96	136.98
5	73.60	115.33	166.34
6	96.64	148.84	218.32

<a _fcknotitle="true" href="Category:Weibull++">Weibull++</a> <a _fcknotitle="true" href="Category:Test_Design">Test_Design</a> <a _fcknotitle="true" href="Category:Special_Tools">Special_Tools</a>

@@ Line 1: / Line 1: @@
-{{UConstruction}}
+<p><span class="fck_mw_template">{{UConstruction}}</span>
-=Expected Failure Time Plot=
+</p>
+<h1>Expected Failure Time Plot</h1>
+<p>When a reliability life test is planned it is useful to visualize the expected outcome of the experiment. The Expected Failure Time Plot (introduced by ReliaSoft in Weibull++ 8)provides such visual.
+</p>
+<h2> Background &amp; Calculations  </h2>
+<p>Using the cumulative binomial, for a defined sample size, one can compute a rank (Median Rank if at 50% probability) for each ordered failure. As an example and for a sample size of 6 the 5%, 50% and 95% ranks would be as follows:
+</p><p><br />
+</p>
+<table border="1" cellspacing="1" cellpadding="1" width="400" align="center">
+<caption> Table 1: 5%, 50% and 95% Ranks for a sample size of 6.&nbsp;
+</caption>
+<tr>
+<th bgcolor="#cccccc" valign="middle" scope="col" align="center"> Order Number
+</th><th bgcolor="#cccccc" valign="middle" scope="col" align="center"> 5%
+</th><th bgcolor="#cccccc" valign="middle" scope="col" align="center"> 50%
+</th><th bgcolor="#cccccc" valign="middle" scope="col" align="center"> 95%
+</th></tr>
+<tr>
+<td valign="middle" align="center"> 1
+</td><td valign="middle" align="center"> 0.85%
+</td><td valign="middle" align="center"> 10.91%
+</td><td valign="middle" align="center"> 39.30%
+</td></tr>
+<tr>
+<td valign="middle" align="center"> 2
+</td><td valign="middle" align="center"> 6.29%
+</td><td valign="middle" align="center"> 26.45%
+</td><td valign="middle" align="center"> 58.18%
+</td></tr>
+<tr>
+<td valign="middle" align="center"> 3
+</td><td valign="middle" align="center"> 15.32%
+</td><td valign="middle" align="center"> 42.14%
+</td><td valign="middle" align="center"> 72.87%
+</td></tr>
+<tr>
+<td valign="middle" align="center"> 4
+</td><td valign="middle" align="center"> 27.13%
+</td><td valign="middle" align="center"> 57.86%
+</td><td valign="middle" align="center"> 84.68%
+</td></tr>
+<tr>
+<td valign="middle" align="center"> 5
+</td><td valign="middle" align="center"> 41.82%
+</td><td valign="middle" align="center"> 73.55%
+</td><td valign="middle" align="center"> 93.71%
+</td></tr>
+<tr>
+<td valign="middle" align="center"> 6
+</td><td valign="middle" align="center"> 60.70%
+</td><td valign="middle" align="center">
+<p>89.09%
+</p>
+</td><td valign="middle" align="center">
+<p>99.15%
+</p>
+</td></tr></table>
+<p><br />
+</p><p>Furthermore, consider that for the units to be tested the underlying reliability model assumption is given by a Weibull distribution with <span class="texhtml">&beta; = 2</span>, and <span class="texhtml">&eta; = 100</span> hr.  Then the median time to failure of the first unit on test can be determined by solving the Weibull reliability equation for t, at each probability,
+</p><p>or
+</p><p><img _fckfakelement="true" _fck_mw_math="R(t)=e^{\big({t \over \eta}\big)^\beta}" src="/images/math/9/b/2/9b21aed609d5cefddaae485bbfbc3a2f.png" />
+</p><p>then for 0.85%,
+</p><p><br /><img _fckfakelement="true" _fck_mw_math="1-0.0085=e^{\big({t \over 100}\big)^2}" src="/images/math/d/b/e/dbe99885cf4bd0ea65638a820287544a.png" />
+</p><p>and so forths as shown in the table below:
+</p><p><br />
+</p>
+<table border="1" cellspacing="1" cellpadding="1" width="400" align="center">
-When a reliability life test is planned it is useful to visualize the expected outcome of the experiment. The Expected Failure Time Plot (introduced by ReliaSoft in Weibull++ 8)provides such visual.
+<tr>
+<th bgcolor="#cccccc" scope="col"> Failure Order Number
-== Background &amp; Calculations  ==
+</th><th bgcolor="#cccccc" scope="col"> Lowest Expected Time-to-failure (hr)
+</th><th bgcolor="#cccccc" scope="col"> Median Expected Time-to-failure (hr)
-Using the cumulative binomial, for a defined sample size, one can compute a rank (Median Rank if at 50% probability) for each ordered failure. As an example and for a sample size of 6 the 5%, 50% and 95% ranks would be as follows:
+</th><th bgcolor="#cccccc" scope="col"> Highest Expected Time-to-failure (hr)
+</th></tr>
-<br>
+<tr>
+<td valign="middle" align="center"> 1
-{| border="1" cellspacing="1" cellpadding="1" width="400" align="center"
+</td><td valign="middle" align="center"> 9.25
-|+ Table 1: 5%, 50% and 95% Ranks for a sample size of 6.&nbsp;
+</td><td valign="middle" align="center"> 33.99
-|-
+</td><td valign="middle" align="center"> 70.66
-! bgcolor="#cccccc" valign="middle" scope="col" align="center" | Order Number
+</td></tr>
-! bgcolor="#cccccc" valign="middle" scope="col" align="center" | 5%
+<tr>
-! bgcolor="#cccccc" valign="middle" scope="col" align="center" | 50%
+<td valign="middle" align="center"> 2
-! bgcolor="#cccccc" valign="middle" scope="col" align="center" | 95%
+</td><td valign="middle" align="center"> 25.48
-|-
+</td><td valign="middle" align="center"> 55.42
-| valign="middle" align="center" | 1
+</td><td valign="middle" align="center"> 93.37
-| valign="middle" align="center" | 0.85%
+</td></tr>
-| valign="middle" align="center" | 10.91%
+<tr>
-| valign="middle" align="center" | 39.30%
+<td valign="middle" align="center"> 3
-|-
+</td><td valign="middle" align="center"> 40.77
-| valign="middle" align="center" | 2
+</td><td valign="middle" align="center"> 73.97
-| valign="middle" align="center" | 6.29%
+</td><td valign="middle" align="center"> 114.21
-| valign="middle" align="center" | 26.45%
+</td></tr>
-| valign="middle" align="center" | 58.18%
+<tr>
-|-
+<td valign="middle" align="center"> 4
-| valign="middle" align="center" | 3
+</td><td valign="middle" align="center"> 56.26
-| valign="middle" align="center" | 15.32%
+</td><td valign="middle" align="center"> 92.96
-| valign="middle" align="center" | 42.14%
+</td><td valign="middle" align="center"> 136.98
-| valign="middle" align="center" | 72.87%
+</td></tr>
-|-
+<tr>
-| valign="middle" align="center" | 4
+<td valign="middle" align="center"> 5
-| valign="middle" align="center" | 27.13%
+</td><td valign="middle" align="center"> 73.60
-| valign="middle" align="center" | 57.86%
+</td><td valign="middle" align="center"> 115.33
-| valign="middle" align="center" | 84.68%
+</td><td valign="middle" align="center"> 166.34
-|-
+</td></tr>
-| valign="middle" align="center" | 5
+<tr>
-| valign="middle" align="center" | 41.82%
+<td valign="middle" align="center"> 6
-| valign="middle" align="center" | 73.55%
+</td><td valign="middle" align="center">
-| valign="middle" align="center" | 93.71%
+<p>96.64
-|-
+</p>
-| valign="middle" align="center" | 6
+</td><td valign="middle" align="center"> 148.84
-| valign="middle" align="center" | 60.70%
+</td><td valign="middle" align="center"> 218.32
-| valign="middle" align="center" |
+</td></tr></table>
-.09%
+<p><br /><br />
+</p><p><br />
-| valign="middle" align="center" |
+</p><p><br />
-.15%
+</p><p><br />
+</p><p><br /><br />
-|}
+</p><a _fcknotitle="true" href="Category:Weibull++">Weibull++</a> <a _fcknotitle="true" href="Category:Test_Design">Test_Design</a> <a _fcknotitle="true" href="Category:Special_Tools">Special_Tools</a>
-<br>
-Furthermore, consider that for the units to be tested the underlying reliability model assumption is given by a Weibull distribution with <math>\beta = 2</math>, and <math>\eta = 100</math> hr.
-Then the median time to failure of the first unit on test can be determined by solving the Weibull reliability equation for t, at each probability,
-or
-<math>R(t)=e^{\big({t \over \eta}\big)^\beta}</math>
-then for 0.85%,
-<br><math>1-0.0085=e^{\big({t \over 100}\big)^2}</math>
-and so forths as shown in the table below:
-<br>
-{| border="1" cellspacing="1" cellpadding="1" width="400" align="center"
-|-
-! bgcolor="#cccccc" scope="col" | Failure Order Number
-! bgcolor="#cccccc" scope="col" | Lowest Expected Time-to-failure (hr)
-! bgcolor="#cccccc" scope="col" | Median Expected Time-to-failure (hr)
-! bgcolor="#cccccc" scope="col" | Highest Expected Time-to-failure (hr)
-|-
-| valign="middle" align="center" | 1
-| valign="middle" align="center" | 9.25
-| valign="middle" align="center" | 33.99
-| valign="middle" align="center" | 70.66
-|-
-| valign="middle" align="center" | 2
-| valign="middle" align="center" | 25.48
-| valign="middle" align="center" | 55.42
-| valign="middle" align="center" | 93.37
-|-
-| valign="middle" align="center" | 3
-| valign="middle" align="center" | 40.77
-| valign="middle" align="center" | 73.97
-| valign="middle" align="center" | 114.21
-|-
-| valign="middle" align="center" | 4
-| valign="middle" align="center" | 56.26
-| valign="middle" align="center" | 92.96
-| valign="middle" align="center" | 136.98
-|-
-| valign="middle" align="center" | 5
-| valign="middle" align="center" | 73.60
-| valign="middle" align="center" | 115.33
-| valign="middle" align="center" | 166.34
-|-
-| valign="middle" align="center" | 6
-| valign="middle" align="center" |
-.64
-| valign="middle" align="center" | 148.84
-| valign="middle" align="center" | 218.32
-|}
-<br><br>
-<br>
-<br>
-<br><br>
-[[Category:Weibull++]] [[Category:Test_Design]] [[Category:Special_Tools]]

Expected Failure Time Plot: Difference between revisions

Revision as of 18:24, 2 March 2011

Expected Failure Time Plot

Background & Calculations

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Expected Failure Time Plot: Difference between revisions

Revision as of 18:24, 2 March 2011

Expected Failure Time Plot

Background & Calculations

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