General FAQs
How are control limits calculated for the different Shewhart control charts?
Mean and Range Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard errors of X-bari and Ri above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that X-bari or Ri exceeds the limits.
The following notation is used for the formulas:
| μ | process mean (expected value of the population of measurements) |
| σ | process standard deviation (standard deviation of the population of measurements) |
| Ri | range of measurements in ith subgroup |
| ni | sample size of ith subgroup |
| N | number of subgroups |
| d2(n) | expected value of the range of n independent normally distributed variables with unit standard deviation |
| d3(n) | standard error of the range of n independent observations from a normal population with unit standard deviation |
| zp | 100pth percentile of the standard normal distribution |
| Dp(n) | 100pth percentile of the distribution of the range of n independent observations from a normal population with unit standard deviation |
 | mean of measurements in ith subgroup |
 | weighted average of subgroup means |
The following tables provide the formulas for the limits:
Mean and Standard Deviation Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard errors of X-bari and si above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that X-bari or si exceeds the limits.
The following notation is used for the formulas:
| μ | process mean (expected value of the population of measurements) |
| σ | process standard deviation (standard deviation of the population of measurements) |
| si | standard deviation of the measurements xi1,...,xini in the
ith subgroup
|
| ni | sample size of ith subgroup |
| N | number of subgroups |
| zp | 100pth percentile of the standard normal distribution |
| c4(n) | expected value of the standard deviation of n independent normally distributed variables with unit standard deviation |
| c5(n) | standard error of the standard deviation of n independent observations from a normal population with unit standard deviation |
| mean of measurements in ith subgroup |
| weighted average of subgroup means |
 | 100pth percentile (0<p<1) of the Χ2 distribution with n degrees of freedom |
The following tables provide the formulas for the limits:
IR Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard errors of Xi and Ri above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that Xi or Ri exceeds the limits.
The following notation is used for the formula:
| μ | process mean (expected value of the population of measurements) |
| σ | process standard deviation (standard deviation of the population of measurements) |
| Xi | the ith individual measurement |
| n | number of consecutive measurements used to calculate the moving ranges (by default, n=2) |
| Ri | moving range computed for the ith subgroup (corresponding to the
ith individual measurement). If i<n, then Ri is assigned
a missing value. Otherwise
Ri = max(Xi,Xi-1,...,Xi-n+1) - min(Xi,Xi-1,...,Xi-n+1) This formula assumes that Xi,Xi-1,...Xi-n+1 are nonmissing. |
| d2(n) | expected value of the range of n independent normally distributed variables with unit standard deviation |
| d3(n) | standard error of the range of n independent observations from a normal population with unit standard deviation |
| zp | 100pth percentile (0<p<1) of the standard normal distribution |
| Dp(n) | 100pth percentile (0<p<1) of the distribution of the range of n independent observations from a normal population with unit standard deviation |
 | mean of the individual measurements, computed as (X1+...+XN)/N, where N is the number of individual measurements |
 | average of the nonmissing moving ranges, computed as
[(Rn+Rn+1...+RN)/(N+1-n)] |
The following tables provide the formulas for the limits:
C Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard error of ci above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that ci exceeds the limits.
The following notation is used for the formula:
| u | expected number of nonconformities per unit produced by the process |
| ui | number of nonconformities per unit in the ith subgroup |
| ci | total number of nonconformities in the ith subgroup |
| ni | number of inspection units in the ith subgroup. Typically ni = 1 and ui = ci for c charts. In general, ui = ci/ni. |
| N | number of subgroups |
 | average number of nonconformities per unit taken across subgroups. The quantity
is computed as a weighted average:
 |
 | has a central Χ2 distribution with ν degrees of freedom |
The lower and upper control limits, LCLC and UCLC respectively, are given by
The upper probaility limit UCLC is calculated by setting
and solving for UCLC.
The lower probability limit LCLC is calculated by setting
and solving for LCLC.
NP Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard error of Xi above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that Xi exceeds the limits.
The following notation is used for the formula:
The lower and upper control limits, LCLC and UCLC respectively, are given by
The upper probaility limit UCLC is calculated by setting
and solving for UCLC.
The lower probability limit LCLC is calculated by setting
and solving for LCLC.
P Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard error of pi above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that pi exceeds the limits.
The notation for the p chart is the same as the notation for the np chart.
The lower and upper control limits, LCLC and UCLC respectively, are given by
The upper probaility limit UCLC is calculated by setting
and solving for UCLC.
The lower probability limit LCLC is calculated by setting
and solving for LCLC.
U Charts:
You can compute the limits in the following ways:
- as a specified multiple (k) of the standard error of ui above and below the central line. The default limits are computed with k=3 (these are referred to as 3σ limits).
- as probability limits defined in terms of α, a specified probability that ui exceeds the limits.
The following notation is used for the formula:
| u | expected number of nonconformities per unit produced by the process |
| ui | number of nonconformities per unit in the ith subgroup. In general, ui=ci/ni. |
| ci | total number of nonconformities in the ith subgroup |
| ni | number of inspection units in the ith subgroup. |
| N | number of subgroups |
| average number of nonconformities per unit taken across subgroups. The quantity
is computed as a weighted average:
|
| has a central Χ2 distribution with ν degrees of freedom |
The lower and upper control limits, LCLC and UCLC respectively, are given by
The upper probaility limit UCLC is calculated by setting
and solving for UCLC.
The lower probability limit LCLC is calculated by setting
and solving for LCLC.
FAQ # 2075
Last Updated: 2005 May 16
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