Deck 13: Methods for Quality Improvement: Statistical Process Control Available on CD

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24 ounces. The company would like to use control charts to monitor the performance of the machine. The company decides to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty measurement times are selected and the following information is recorded. $$\begin{array} { c c c c c c } \hline \text { Time } & \text { Mean (oz) } & \text { Range (oz) } & \text { Time } & \text { Mean (oz) } & \text { Range (oz) } \\\hline 1 & 23.8 & 1.05 & 11 & 24.5 & 1.21 \\2 & 24.5 & 0.85 & 12 & 24.7 & 0.65 \\3 & 23.9 & 1.12 & 13 & 24.0 & 0.55 \\4 & 24.2 & 0.95 & 14 & 25.5 & 3.21 \\5 & 23.7 & 1.22 & 15 & 24.2 & 1.25 \\6 & 23.5 & 1.42 & 16 & 24.4 & 1.35 \\7 & 24.2 & 1.02 & 17 & 24.5 & 0.98 \\8 & 24.4 & 1.10 & 18 & 25.0 & 1.30 \\9 & 24.1 & 0.75 & 19 & 24.1 & 0.88 \\10 & 24.2 & 0.60 & 20 & 24.2 & 1.01 \\\hline\end{array}$$

-Find the upper and lower control limits for the R-chart.

(Situation D) A walk-in freezer thermostat at a restaurant is set at 5°F. Because of the perishability of the food in the freezer, the restaurant manager has decided to begin monitoring the temperature inside the freezer. The managers used a precision thermometer to take sample temperature readings at five randomly chosen times per day for 10 days. The data are presented below.

$\text { Day }$ $\quad$ $\quad$ $\text { Temperature }\left(^{\circ}\right. \text { F) }$
$\begin{array}{rrrrrr}\hline 1 & 5.22 & 5.29 & 5.11 & 4.95 & 4.78 \\2 & 4.40 & 4.41 & 4.63 & 6.03 & 4.83 \\3 & 5.11 & 5.43 & 4.90 & 4.55 & 5.23 \\4 & 5.65 & 4.24 & 5.09 & 4.82 & 5.50 \\5 & 4.68 & 5.92 & 4.71 & 4.67 & 4.75 \\6 & 5.01 & 5.26 & 6.10 & 5.20 & 5.25 \\7 & 5.20 & 4.99 & 5.15 & 5.96 & 5.35 \\8 & 4.30 & 4.91 & 5.03 & 4.97 & 4.80 \\9 & 5.45 & 5.62 & 6.11 & 5.13 & 4.90 \\10 & 5.06 & 5.13 & 4.95 & 5.59 & 5.80 \\\hline\end{array}$


-Calculate the centerline of the R-chart.

The table below shows the data from samples of size $n=5$ randomly chosen from the outputs of a process on 20 different days.
$\begin{array}{cccccc}\hline \text { Sample } & & & \text { Data } & & \\\hline 1 & 4.5 & 2.1 & 5.4 & 2.7 & 4.5 \\2 & 3.6 & 3.5 & 6.1 & 4.9 & 4.2 \\3 & 5.1 & 6.2 & 2.4 & 3.7 & 5.1 \\4 & 4.9 & 5.4 & 3.5 & 5.4 & 3.7 \\5 & 4.1 & 3.8 & 3.8 & 4.6 & 4.9 \\6 & 3.7 & 4.6 & 4.8 & 4.2 & 5.2 \\7 & 5.6 & 4.7 & 4.1 & 5.1 & 3.1 \\8 & 4.8 & 5.1 & 4.3 & 4.6 & 2.7 \\9 & 6.1 & 4.6 & 4.7 & 3.8 & 4.2 \\10 & 2.4 & 4.8 & 5.6 & 4.1 & 4.8 \\11 & 3.7 & 5.3 & 2.9 & 4.7 & 6.3 \\12 & 4.5 & 3.4 & 3.4 & 5.2 & 4.5 \\13 & 5.2 & 2.7 & 5.1 & 6.2 & 2.9 \\14 & 3.4 & 5.5 & 4.6 & 2.4 & 3.4 \\15 & 4.8 & 3.6 & 4.8 & 4.4 & 4.6 \\16 & 4.1 & 4.6 & 4.9 & 4.9 & 4.3 \\17 & 4.6 & 3.7 & 3.5 & 3.7 & 5.2 \\18 & 5.1 & 4.2 & 5.6 & 4.1 & 5.7 \\19 & 3.7 & 4.8 & 4.9 & 2.3 & 4.5 \\20 & 5.4 & 3.9 & 4.2 & 5.4 & 4.3 \\\hline\end{array}$

a. $\text { Find } D_{3} \text { and } D_{4} \text {. }$
b. $\text { Construct an R-chart. }$
c. $\text { Is the process out of control? Explain. }$

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24
ounces. The company would like to use control charts to monitor the performance of the machine. The company decides
to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty
measurement times are selected and the following information is recorded.
Calculate the centerline for constructing the

The table below shows the data from samples of size $n=5$ randomly chosen from the outputs of a process on 20 different days. Assume the specification limits are USL $=2.1$ and $\mathrm{LSL}=5.7$ .


$\begin{array}{cccccc}\hline \text { Sample } & & {\text { Data }} \\\hline 1 & 4.5 & 2.1 & 5.4 & 2.7 & 4.5 \\2 & 3.6 & 3.5 & 6.1 & 4.9 & 4.2 \\3 & 5.1 & 6.2 & 2.4 & 3.7 & 5.1 \\4 & 4.9 & 5.4 & 3.5 & 5.4 & 3.7 \\5 & 4.1 & 3.8 & 3.8 & 4.6 & 4.9 \\6 & 3.7 & 4.6 & 4.8 & 4.2 & 5.2 \\7 & 5.6 & 4.7 & 4.1 & 5.1 & 3.1 \\8 & 4.8 & 5.1 & 4.3 & 4.6 & 2.7 \\9 & 6.1 & 4.6 & 4.7 & 3.8 & 4.2 \\10 & 2.4 & 4.8 & 5.6 & 4.1 & 4.8 \\11 & 3.7 & 5.3 & 2.9 & 4.7 & 6.3 \\12 & 4.5 & 3.4 & 3.4 & 5.2 & 4.5 \\13 & 5.2 & 2.7 & 5.1 & 6.2 & 2.9 \\14 & 3.4 & 5.5 & 4.6 & 2.4 & 3.4 \\15 & 4.8 & 3.6 & 4.8 & 4.4 & 4.6 \\16 & 4.1 & 4.6 & 4.9 & 4.9 & 4.3 \\17 & 4.6 & 3.7 & 3.5 & 3.7 & 5.2 \\18 & 5.1 & 4.2 & 5.6 & 4.1 & 5.7 \\19 & 3.7 & 4.8 & 4.9 & 2.3 & 4.5 \\20 & 5.4 & 3.9 & 4.2 & 5.4 & 4.3 \\\hline\end{array}$
a. Assuming the process is under control, construct a capability analysis diagram for the process.
b. Find the percentage of data items that fall outside the specification limits.
c. Is the process capable? Support your answer with a numerical measure of capability.

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24 ounces. The company would like to use control charts to monitor the performance of the machine. The company decides to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty measurement times are selected and the following information is recorded. $$\begin{array} { c c c c c c } \hline \text { Time } & \text { Mean (oz) } & \text { Range (oz) } & \text { Time } & \text { Mean (oz) } & \text { Range (oz) } \\\hline 1 & 23.8 & 1.05 & 11 & 24.5 & 1.21 \\2 & 24.5 & 0.85 & 12 & 24.7 & 0.65 \\3 & 23.9 & 1.12 & 13 & 24.0 & 0.55 \\4 & 24.2 & 0.95 & 14 & 25.5 & 3.21 \\5 & 23.7 & 1.22 & 15 & 24.2 & 1.25 \\6 & 23.5 & 1.42 & 16 & 24.4 & 1.35 \\7 & 24.2 & 1.02 & 17 & 24.5 & 0.98 \\8 & 24.4 & 1.10 & 18 & 25.0 & 1.30 \\9 & 24.1 & 0.75 & 19 & 24.1 & 0.88 \\10 & 24.2 & 0.60 & 20 & 24.2 & 1.01\end{array}$$

- $$\text { Create the } \bar { x } \text {-chart and interpret it. }$$

(Situation B) A manufacturing company makes hemostats for hospital emergency rooms. The company is interested in implementing statistical process control procedures in its production operation. The production manager believes that the proportion of defective hemostats generated by the process is about 3%. The company collected one sample of 300 consecutively manufactured hemostats each day for 20 days.
The data are shown below.
$$\begin{array} { c c c c c c } \hline \text { Sample } & \text { Sample Size } & \text { Defectives } & \text { Sample } & \text { Sample Size } & \text { Defectives } \\\hline 1 & 300 & 8 & 11 & 300 & 12 \\2 & 300 & 6 & 12 & 300 & 11 \\3 & 300 & 11 & 13 & 300 & 14 \\4 & 300 & 15 & 14 & 300 & 8 \\5 & 300 & 12 & 15 & 300 & 7 \\6 & 300 & 11 & 16 & 300 & 3 \\7 & 300 & 9 & 17 & 300 & 9 \\8 & 300 & 6 & 18 & 300 & 11 \\9 & 300 & 5 & 19 & 300 & 10 \\10 & 300 & 4 & 20 & 300 & 6 \\\hline\end{array}$$

-Construct the p-chart and interpret it.

The capability index for a process centered on the desired mean is

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24 ounces. The company would like to use control charts to monitor the performance of the machine. The company decides to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty measurement times are selected and the following information is recorded. $$\begin{array} { c c c c c c } \hline \text { Time } & \text { Mean (oz) } & \text { Range (oz) } & \text { Time } & \text { Mean (oz) } & \text { Range (oz) } \\\hline 1 & 23.8 & 1.05 & 11 & 24.5 & 1.21 \\2 & 24.5 & 0.85 & 12 & 24.7 & 0.65 \\3 & 23.9 & 1.12 & 13 & 24.0 & 0.55 \\4 & 24.2 & 0.95 & 14 & 25.5 & 3.21 \\5 & 23.7 & 1.22 & 15 & 24.2 & 1.25 \\6 & 23.5 & 1.42 & 16 & 24.4 & 1.35 \\7 & 24.2 & 1.02 & 17 & 24.5 & 0.98 \\8 & 24.4 & 1.10 & 18 & 25.0 & 1.30 \\9 & 24.1 & 0.75 & 19 & 24.1 & 0.88 \\10 & 24.2 & 0.60 & 20 & 24.2 & 1.01\end{array}$$

-Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

A process is considered capable if

(Situation D) A walk-in freezer thermostat at a restaurant is set at 5°F. Because of the perishability of the food in the freezer, the restaurant manager has decided to begin monitoring the temperature inside the freezer. The managers used a precision thermometer to take sample temperature readings at five randomly chosen times per day for 10 days. The data are presented below.

$\text { Day }$ $\quad$ $\quad$ $\text { Temperature }\left(^{\circ}\right. \text { F) }$
$\begin{array}{rrrrrr}\hline 1 & 5.22 & 5.29 & 5.11 & 4.95 & 4.78 \\2 & 4.40 & 4.41 & 4.63 & 6.03 & 4.83 \\3 & 5.11 & 5.43 & 4.90 & 4.55 & 5.23 \\4 & 5.65 & 4.24 & 5.09 & 4.82 & 5.50 \\5 & 4.68 & 5.92 & 4.71 & 4.67 & 4.75 \\6 & 5.01 & 5.26 & 6.10 & 5.20 & 5.25 \\7 & 5.20 & 4.99 & 5.15 & 5.96 & 5.35 \\8 & 4.30 & 4.91 & 5.03 & 4.97 & 4.80 \\9 & 5.45 & 5.62 & 6.11 & 5.13 & 4.90 \\10 & 5.06 & 5.13 & 4.95 & 5.59 & 5.80 \\\hline\end{array}$


-Calculate the upper and lower control limits for the R-chart.

The quality of a product is indicated by the extent to which it satisfies the needs and preferences of its manufacturer.

(Situation C) Ten samples of $n = 5$ were collected to construct an $\bar { x }$ -chart. The sample means and ranges for the 10 samples are shown below.


$\begin{array}{cccccc}\hline \text { Sample } & \text { Mean } & \text { Range } & \text { Sample } & \text { Mean } & \text { Range } \\\hline 1 & 20.2 & 2.7 & 6 & 20.4 & 1.9 \\2 & 22.4 & 1.8 & 7 & 15.9 & 1.0 \\3 & 21.2 & 1.5 & 8 & 22.3 & 2.1 \\4 & 18.2 & 1.2 & 9 & 20.7 & 1.6 \\5 & 23.2 & 2.4 & 10 & 21.1 & 1.8 \\\hline\end{array}$


-Calculate the upper and lower control limits for the $\bar { X } \text {-chart. }$

With rare exceptions, all items produced by a process are identical.

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24 ounces. The company would like to use control charts to monitor the performance of the machine. The company decides to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty measurement times are selected and the following information is recorded. $$\begin{array} { c c c c c c } \hline \text { Time } & \text { Mean (oz) } & \text { Range (oz) } & \text { Time } & \text { Mean (oz) } & \text { Range (oz) } \\\hline 1 & 23.8 & 1.05 & 11 & 24.5 & 1.21 \\2 & 24.5 & 0.85 & 12 & 24.7 & 0.65 \\3 & 23.9 & 1.12 & 13 & 24.0 & 0.55 \\4 & 24.2 & 0.95 & 14 & 25.5 & 3.21 \\5 & 23.7 & 1.22 & 15 & 24.2 & 1.25 \\6 & 23.5 & 1.42 & 16 & 24.4 & 1.35 \\7 & 24.2 & 1.02 & 17 & 24.5 & 0.98 \\8 & 24.4 & 1.10 & 18 & 25.0 & 1.30 \\9 & 24.1 & 0.75 & 19 & 24.1 & 0.88 \\10 & 24.2 & 0.60 & 20 & 24.2 & 1.01\end{array}$$

-Calculate the upper and lower control limits for the $\bar { x } \text {-chart. }$

(Situation E) A machine at K-Company fills boxes with bran flake cereal. The target weight for the filled boxes is 24 ounces. The company would like to use control charts to monitor the performance of the machine. The company decides to sample and weigh 10 consecutive boxes of cereal at randomly selected times over a two-week period. Twenty measurement times are selected and the following information is recorded. $$\begin{array} { c c c c c c } \hline \text { Time } & \text { Mean (oz) } & \text { Range (oz) } & \text { Time } & \text { Mean (oz) } & \text { Range (oz) } \\\hline 1 & 23.8 & 1.05 & 11 & 24.5 & 1.21 \\2 & 24.5 & 0.85 & 12 & 24.7 & 0.65 \\3 & 23.9 & 1.12 & 13 & 24.0 & 0.55 \\4 & 24.2 & 0.95 & 14 & 25.5 & 3.21 \\5 & 23.7 & 1.22 & 15 & 24.2 & 1.25 \\6 & 23.5 & 1.42 & 16 & 24.4 & 1.35 \\7 & 24.2 & 1.02 & 17 & 24.5 & 0.98 \\8 & 24.4 & 1.10 & 18 & 25.0 & 1.30 \\9 & 24.1 & 0.75 & 19 & 24.1 & 0.88 \\10 & 24.2 & 0.60 & 20 & 24.2 & 1.01\end{array}$$

-Calculate the centerline of the $\mathrm { R } - \text { chart }$

Does the following control chart represent a process that is in control or out of control? If it is out of control, explain how you arrived at this conclusion.

(Situation B) A manufacturing company makes hemostats for hospital emergency rooms. The company is interested in implementing statistical process control procedures in its production operation. The production manager believes that the proportion of defective hemostats generated by the process is about 3%. The company collected one sample of 300 consecutively manufactured hemostats each day for 20 days. The data are shown below. $$\begin{array} { c c c c c c } \hline \text { Sample } & \text { Sample Size } & \text { Defectives } & \text { Sample } & \text { Sample Size } & \text { Defectives } \\\hline 1 & 300 & 8 & 11 & 300 & 12 \\2 & 300 & 6 & 12 & 300 & 11 \\3 & 300 & 11 & 13 & 300 & 14 \\4 & 300 & 15 & 14 & 300 & 8 \\5 & 300 & 12 & 15 & 300 & 7 \\6 & 300 & 11 & 16 & 300 & 3 \\7 & 300 & 9 & 17 & 300 & 9 \\8 & 300 & 6 & 18 & 300 & 11 \\9 & 300 & 5 & 19 & 300 & 10 \\10 & 300 & 4 & 20 & 300 & 6 \\\hline\end{array}$$

-Find the upper and lower control limits for the p-chart.

(Situation D) A walk-in freezer thermostat at a restaurant is set at 5°F. Because of the perishability of the food in the freezer, the restaurant manager has decided to begin monitoring the temperature inside the freezer. The managers used a precision thermometer to take sample temperature readings at five randomly chosen times per day for 10 days. The data are presented below.

$\text { Day }$ $\quad$ $\quad$ $\text { Temperature }\left(^{\circ}\right. \text { F) }$
$\begin{array}{rrrrrr}\hline 1 & 5.22 & 5.29 & 5.11 & 4.95 & 4.78 \\2 & 4.40 & 4.41 & 4.63 & 6.03 & 4.83 \\3 & 5.11 & 5.43 & 4.90 & 4.55 & 5.23 \\4 & 5.65 & 4.24 & 5.09 & 4.82 & 5.50 \\5 & 4.68 & 5.92 & 4.71 & 4.67 & 4.75 \\6 & 5.01 & 5.26 & 6.10 & 5.20 & 5.25 \\7 & 5.20 & 4.99 & 5.15 & 5.96 & 5.35 \\8 & 4.30 & 4.91 & 5.03 & 4.97 & 4.80 \\9 & 5.45 & 5.62 & 6.11 & 5.13 & 4.90 \\10 & 5.06 & 5.13 & 4.95 & 5.59 & 5.80 \\\hline\end{array}$


-Create the R-chart and interpret it.

If all points fall between the control limits, then we may safely conclude that the process is in statistical control.

Control charts are used to help us differentiate between process variation due to common causes and special causes.

(Situation C) Ten samples of $n = 5$ were collected to construct an $\bar { x }$ -chart. The sample means and ranges for the 10 samples are shown below.


$\begin{array}{cccccc}\hline \text { Sample } & \text { Mean } & \text { Range } & \text { Sample } & \text { Mean } & \text { Range } \\\hline 1 & 20.2 & 2.7 & 6 & 20.4 & 1.9 \\2 & 22.4 & 1.8 & 7 & 15.9 & 1.0 \\3 & 21.2 & 1.5 & 8 & 22.3 & 2.1 \\4 & 18.2 & 1.2 & 9 & 20.7 & 1.6 \\5 & 23.2 & 2.4 & 10 & 21.1 & 1.8 \\\hline\end{array}$


-Calculate the centerline for constructing the $\bar { x } \text {-chart. }$

The R-chart is used to detect changes in process variation.

The centerline of a control chart is drawn at the level of the median of the sample.

People, machines, and raw materials can all contribute to the variability in the output of a system.

When n ≤ 6, the R-chart contains only one control limit, the lower control limit.

The table below shows the data from samples of size $n=5$ randomly chosen from the outputs of a process on 20 different days.

$\begin{array}{cccccc}\hline \text { Sample } & & {\text { Data }} \\\hline 1 & 4.5 & 2.1 & 5.4 & 2.7 & 4.5 \\2 & 3.6 & 3.5 & 6.1 & 4.9 & 4.2 \\3 & 5.1 & 6.2 & 2.4 & 3.7 & 5.1 \\4 & 4.9 & 5.4 & 3.5 & 5.4 & 3.7 \\5 & 4.1 & 3.8 & 3.8 & 4.6 & 4.9 \\6 & 3.7 & 4.6 & 4.8 & 4.2 & 5.2 \\7 & 5.6 & 4.7 & 4.1 & 5.1 & 3.1 \\8 & 4.8 & 5.1 & 4.3 & 4.6 & 2.7 \\9 & 6.1 & 4.6 & 4.7 & 3.8 & 4.2 \\10 & 2.4 & 4.8 & 5.6 & 4.1 & 4.8 \\11 & 3.7 & 5.3 & 2.9 & 4.7 & 6.3 \\12 & 4.5 & 3.4 & 3.4 & 5.2 & 4.5 \\13 & 5.2 & 2.7 & 5.1 & 6.2 & 2.9 \\14 & 3.4 & 5.5 & 4.6 & 2.4 & 3.4 \\15 & 4.8 & 3.6 & 4.8 & 4.4 & 4.6 \\16 & 4.1 & 4.6 & 4.9 & 4.9 & 4.3 \\17 & 4.6 & 3.7 & 3.5 & 3.7 & 5.2 \\18 & 5.1 & 4.2 & 5.6 & 4.1 & 5.7 \\19 & 3.7 & 4.8 & 4.9 & 2.3 & 4.5 \\20 & 5.4 & 3.9 & 4.2 & 5.4 & 4.3 \\\hline\end{array}$

a. $\text { Calculate } \bar{x} \text {. }$
b. $\text { Calculate } \bar{R} \text {. }$
c. $\text { Find } d_{2} \text { and } A_{2} \text {. }$
d. $\text { Construct an } \bar{x} \text {-chart. }$
e. $\text { Is the process out of control? Explain. }$

When using a cause-and-effect diagram in process diagnosis, you begin by specifying the cause of interest and then move forward to identify potential effects of this cause.

The elimination of common causes of variation is typically the responsibility of workers, not management.

The p-chart is based on the assumption that the number of defective units in each sample is a binomial random variable.

The variation in the output of processes that are out of control can be entirely attributed to random behavior.

The distribution that describes the output variable of a process may change over time.

Statistical process control consists of monitoring process variation, diagnosing causes of variation, and eliminating those causes.

A process may be in control but still not be capable of producing output that is acceptable to customers.

A process is in control and has a normally distributed output distribution with mean of 1000 and a standard deviation of 100 . The upper and lower specification limits for the process are 1060 and 940 , respectively. Find the $\mathrm { C } _ { \mathrm { p } }$ value of the process. Is the system capable?

If the R-chart indicates that the process variation is in control, then it makes sense to construct and interpret the $\overline { \mathrm { X } }$ chart.

An unbiased estimator for ? can be found by dividing the mean of the ranges, $\overline { \mathrm { R } }$ by an appropriate constant.

Conformance refers to the extent to which a good or service can be adapted for use in new situations.

In constructing a p-chart, it is advisable to use a much smaller sample size than is typically used for $\bar { x } -$ and R-charts.

The diagnosis phase of statistical process control is concerned with tracking down causes of variation.

When constructing an $\bar { x }$ -chart, $\bar{\bar { x }}$ is used as the estimator of $\mu$ .

Performance, reliability, and durability are some of the factors used to evaluate quality.

A process adds value to the inputs of the process.

(Situation B) A manufacturing company makes hemostats for hospital emergency rooms. The company is interested in implementing statistical process control procedures in its production operation. The production manager believes that the proportion of defective hemostats generated by the process is about 3%. The company collected one sample of 300
consecutively manufactured hemostats each day for 20 days. The data are shown below. $$\begin{array} { c c c c c c } \hline \text { Sample } & \text { Sample Size } & \text { Defectives } & \text { Sample } & \text { Sample Size } & \text { Defectives } \\\hline 1 & 300 & 8 & 11 & 300 & 12 \\2 & 300 & 6 & 12 & 300 & 11 \\3 & 300 & 11 & 13 & 300 & 14 \\4 & 300 & 15 & 14 & 300 & 8 \\5 & 300 & 12 & 15 & 300 & 7 \\6 & 300 & 11 & 16 & 300 & 3 \\7 & 300 & 9 & 17 & 300 & 9 \\8 & 300 & 6 & 18 & 300 & 11 \\9 & 300 & 5 & 19 & 300 & 10 \\10 & 300 & 4 & 20 & 300 & 6 \\\hline\end{array}$$

-Calculate the centerline used in constructing a $\mathrm { p } \text {-chart. }$

Capability analysis is used to determine when process variation is unacceptably high.

(Situation D) A walk-in freezer thermostat at a restaurant is set at 5°F. Because of the perishability of the food in the freezer, the restaurant manager has decided to begin monitoring the temperature inside the freezer. The managers used a precision thermometer to take sample temperature readings at five randomly chosen times per day for 10 days. The data
are presented below.

$\text { Day }$ $\quad$ $\quad$ $\text { Temperature }\left(^{\circ}\right. \text { F) }$
$\begin{array}{cccccc}\hline 1 & 5.22 & 5.29 & 5.11 & 4.95 & 4.78 \\2 & 4.40 & 4.41 & 4.63 & 6.03 & 4.83 \\3 & 5.11 & 5.43 & 4.90 & 4.55 & 5.23 \\4 & 5.65 & 4.24 & 5.09 & 4.82 & 5.50 \\5 & 4.68 & 5.92 & 4.71 & 4.67 & 4.75 \\6 & 5.01 & 5.26 & 6.10 & 5.20 & 5.25 \\7 & 5.20 & 4.99 & 5.15 & 5.96 & 5.35 \\8 & 4.30 & 4.91 & 5.03 & 4.97 & 4.80 \\9 & 5.45 & 5.62 & 6.11 & 5.13 & 4.90 \\10 & 5.06 & 5.13 & 4.95 & 5.59 & 5.80 \\\hline\end{array}$

-Calculate the centerline for constructing the $\bar { x }$ chart.

Most processes are naturally in a state of statistical control.

(Situation A) To construct a p-chart for a manufacturing process, 20 samples of size 100 were selected. The results are shown below: $$\begin{array} { c c c c c c } \hline \text { Sample } & \text { Sample Size } & \text { Defectives } & \text { Sample } & \text { Sample Size } & \text { Defectives } \\\hline 1 & 100 & 10 & 11 & 100 & 8 \\2 & 100 & 8 & 12 & 100 & 8 \\3 & 100 & 9 & 13 & 100 & 5 \\4 & 100 & 6 & 14 & 100 & 9 \\5 & 100 & 7 & 15 & 100 & 7 \\6 & 100 & 3 & 16 & 100 & 9 \\7 & 100 & 8 & 17 & 100 & 11 \\8 & 100 & 6 & 18 & 100 & 4 \\9 & 100 & 11 & 19 & 100 & 6 \\10 & 100 & 10 & 20 & 100 & 8 \\\hline\end{array}$$

-Calculate the upper and lower control limits for the p-chart.

The p-chart is typically used to monitor the proportion of units that conform to specification.

Special causes of variation can often be diagnosed and eliminated by workers or their immediate supervisors.

Control charts are the tool of choice for continuously monitoring processes.

A business that operates out-of-control processes risks losing its customers and threatens its own survival.

Control charts may only be used for quantitative quality variables.

A system receives inputs from its environment, transforms those inputs to outputs, and delivers them to its environment.

(Situation A) To construct a p-chart for a manufacturing process, 20 samples of size 100 were selected. The results areshown below:

$$\begin{array} { c c c c c c } \hline \text { Sample } & \text { Sample Size } & \text { Defectives } & \text { Sample } & \text { Sample Size } & \text { Defectives } \\\hline 1 & 100 & 10 & 11 & 100 & 8 \\2 & 100 & 8 & 12 & 100 & 8 \\3 & 100 & 9 & 13 & 100 & 5 \\4 & 100 & 6 & 14 & 100 & 9 \\5 & 100 & 7 & 15 & 100 & 7 \\6 & 100 & 3 & 16 & 100 & 9 \\7 & 100 & 8 & 17 & 100 & 11 \\8 & 100 & 6 & 18 & 100 & 4 \\9 & 100 & 11 & 19 & 100 & 6 \\10 & 100 & 10 & 20 & 100 & 8 \\\hline\end{array}$$

-Calculate the centerline used in constructing a p-chart.

The upper and lower control limits are positioned so that when the process is in control the probability of an individual value of the output variable falling outside the control limits is very large.

If quality is designed into products and process management is used in their production, massinspection of finished products will not be necessary.

If a capability analysis study indicates that an in-control process is not capable, it is usually off-centeredness, rather than variation, that is the culprit.

Control limits and specification limits are essentially the same thing.

Control charts are useful for evaluating the past performance of a process, for monitoring its current performance, and for predicting future performance.