SCENARIO 18-10 Below is the number of defective items from a production line over twenty consecutive morning shifts. \[\begin{array} { | r | r | | r | r | } \hline \text { Day } & \text { Nonconformances } & \text { Day } & \text { Nonconformances } \\ \hline 1 & 26 & 11 & 22 \\ \hline 2 & 27 & 12 & 26 \\ \hline 3 & 23 & 13 & 21 \\ \hline 4 & 21 & 14 & 22 \\ \hline 5 & 26 & 15 & 19 \\ \hline 6 & 20 & 16 & 17 \\ \hline 7 & 35 & 17 & 21 \\ \hline 8 & 30 & 18 & 18 \\ \hline 9 & 21 & 19 & 16 \\ \hline 10 & 25 & 20 & 17 \\ \hline \end{array}\] -Referring to Scenario 18-10, a c chart is to be constructed for the number of defective items. The upper control limits is ________.

The answer of SCENARIO 18-10 Below is the number of defective...

SCENARIO 18-4 A factory supervisor is concerned that the time it takes workers to complete an important production task (measured in seconds) is too erratic and adversely affects expected profits. The supervisor proceeds by randomly sampling 5 individuals per hour for a period of 10 hours. The sample mean and range for each hour are listed below. \[\begin{array} {ccc} \underline {\text { Hour }} & \underline { \bar { X } } & \underline { R } \\ 1 & 18.4 & 25 \\ 2 & 16.9 & 27 \\ 3 & 23.0 & 30 \\ 4 & 21.2 & 23 \\ 5 & 21.0 & 24 \\ 6 & 24.0 & 25 \\ 7 & 19.3 & 12 \\ 8 & 15.8 & 14 \\ 9 & 20.0 & 13 \\ 10 & 23.0 & 11 \end{array}\] She also decides that lower and upper specification limit for the critical-to-quality variable should be 10 and 30 seconds, respectively. -Referring to Scenario 18-4, suppose the sample mean and range data were based on 6 observations per hour instead of 5. How would this change affect the lower and upper control Limits of an R chart?

A) LCL would increase; UCL would decrease. B) LCL would remain the same; UCL would decrease. C) Both LCL and UCL would remain the same. D) LCL would decrease; UCL would increase. A) LCL would increase; UCL would decrease. B) LCL would remain the same; UCL would decrease. C) Both LCL and UCL would remain the same. D) LCL would decrease; UCL would increase.

SCENARIO 18-10 Below is the number of defective items from a production line over twenty consecutive morning shifts. \[\begin{array} { | r | r | | r | r | } \hline \text { Day } & \text { Nonconformances } & \text { Day } & \text { Nonconformances } \\ \hline 1 & 26 & 11 & 22 \\ \hline 2 & 27 & 12 & 26 \\ \hline 3 & 23 & 13 & 21 \\ \hline 4 & 21 & 14 & 22 \\ \hline 5 & 26 & 15 & 19 \\ \hline 6 & 20 & 16 & 17 \\ \hline 7 & 35 & 17 & 21 \\ \hline 8 & 30 & 18 & 18 \\ \hline 9 & 21 & 19 & 16 \\ \hline 10 & 25 & 20 & 17 \\ \hline \end{array}\] -Referring to Scenario 18-10, a c chart is to be constructed for the number of defective items. The center line of this c chart is located at __________.

The answer of SCENARIO 18-10 Below is the number of defective...

SCENARIO 18-3 A quality control analyst for a light bulb manufacturer is concerned that the time it takes to produce a batch of light bulbs is too erratic. Accordingly, the analyst randomly surveys 10 production periods each day for 14 days and records the sample mean and range for each day. $\begin{array}{ccc} \underline{\text { Day } }& \underline{\bar{X} \text { (in minutes) }} & \underline{\text {R}}\\ 1 & 58.5 & 5.1 \\ 2 & 47.6 & 7.8 \\ 3 & 64.3 & 6.1 \\ 4 & 60.6 & 5.7 \\ 5 & 63.7 & 6.2 \\ 6 & 57.5 & 6.0 \\ 7 & 55.0 & 5.4 \\ 8 & 54.9 & 6.1 \\ 9 & 55.0 & 5.9 \\ 10 & 62.7 & 5.0 \\ 11 & 61.9 & 7.1 \\ 12 & 60.0 & 6.5 \\ 13 & 58.3 & 5.9 \\ 14 & 52.0 & 5.2 \end{array}$ -Referring to Scenario 18-3, suppose the analyst constructs an R chart to see if the variability in production times is in-control. What is the lower control limit for this R chart?

A) 4.84 B) 3.37 C) 2.98 D) 1.34 A) 4.84 B) 3.37 C) 2.98 D) 1.34

SCENARIO 18-3 A quality control analyst for a light bulb manufacturer is concerned that the time it takes to produce a batch of light bulbs is too erratic. Accordingly, the analyst randomly surveys 10 production periods each day for 14 days and records the sample mean and range for each day. $\begin{array}{ccc} \underline{\text { Day } }& \underline{\bar{X} \text { (in minutes) }} & \underline{\text {R}}\\ 1 & 58.5 & 5.1 \\ 2 & 47.6 & 7.8 \\ 3 & 64.3 & 6.1 \\ 4 & 60.6 & 5.7 \\ 5 & 63.7 & 6.2 \\ 6 & 57.5 & 6.0 \\ 7 & 55.0 & 5.4 \\ 8 & 54.9 & 6.1 \\ 9 & 55.0 & 5.9 \\ 10 & 62.7 & 5.0 \\ 11 & 61.9 & 7.1 \\ 12 & 60.0 & 6.5 \\ 13 & 58.3 & 5.9 \\ 14 & 52.0 & 5.2 \end{array}$ -Referring to Scenario 18-3, suppose the analyst constructs an X chart to see if the production process is in-control. What is the upper control limit (UCL) for this chart?

A) 62.15 B) 60.95 C) 59.85 D) 58.75 A) 62.15 B) 60.95 C) 59.85 D) 58.75

SCENARIO 18-9 The manufacturer of canned food constructed control charts and analyzed several quality characteristics. One characteristic of interest is the weight of the filled cans. The lower specification limit for weight is 2.95 pounds. The table below provides the range and mean of the weights of five cans tested every fifteen minutes during a day's production. $\begin{array}{|r|r|r||r|r|r|} \hline {\text { Number }} & {\text { XBar }} &{\text { Range }} & {\text { Number }} & {\text { XBar }} & \text { Range } \\ \hline 1 & 3.05072 & 0.0215 & 16 & 3.04646 & 0.073 \\ \hline 2 & 3.01228 & 0.087 & 17 & 3.03868 & 0.0696 \\ \hline 3 & 3.03558 & 0.0851 & 18 & 3.03338 & 0.0329 \\ \hline 4 & 3.01014 & 0.0674 & 19 & 3.03322 & 0.0455 \\ \hline 5 & 3.00858 & 0.0983 & 20 & 3.05078 & 0.0215 \\ \hline 6 & 3.02704 & 0.0527 & 21 & 3.04808 & 0.0396 \\ \hline 7 & 3.04268 & 0.0508 & 22 & 3.05348 & 0.0581 \\ \hline 8 & 3.01052 & 0.0791 & 23 & 3.05516 & 0.0682 \\ \hline 9 & 3.03464 & 0.0663 & 24 & 3.03426 & 0.0325 \\ \hline 10 & 3.02034 & 0.0538 & 25 & 3.0516 & 0.0641 \\ \hline 11 & 3.03764 & 0.0584 & 26 & 3.05562 & 0.0809 \\ \hline 12 & 3.0409 & 0.0434 & 27 & 3.04402 & 0.0374 \\ \hline 13 & 3.0519 & 0.0762 & 28 & 3.06458 & 0.0284 \\ \hline 14 & 3.03994 & 0.0833 & 29 & 3.0544 & 0.0738 \\ \hline 15 & 3.03788 & 0.0601 & & & \\ \hline \end{array}$ -Referring to Scenario 18-9, an R chart is to be constructed for the weight. The lower control limit for this data set is ________.

The answer of SCENARIO 18-9 The manufacturer of canned food constructed...

SCENARIO 18-8 Recently, a university switched to a new type of computer-based registration. The registrar is concerned with the amount of time students are spending on the computer registering under the new system. She decides to randomly select 8 students on each of the 12 days of the registration and determine the time each spends on the computer registering. The range, mean, and standard deviation of the times required to register are in the table that follows. \[\begin{array} { r l r l } \underline { \text { Day } } & \text { Range } & \underline { \text { Mean } } & \underline { \text { Std.Dev. } } \\ 1 & 10 & 5.250 & 3.4949 \\ 2 & 31 & 15.250 & 10.3060 \\ 3 & 13 & 20.375 & 4.9262 \\ 4 & 21 & 22.875 & 8.3911 \\ 5 & 35 & 8.500 & 11.3767 \\ 6 & 18 & 7.875 & 6.9372 \\ 7 & 25 & 11.250 & 8.5815 \\ 8 & 30 & 7.875 & 9.5235 \\ 9 & 17 & 10.250 & 6.3640 \\ 10 & 22 & 9.500 & 7.8740 \\ 11 & 27 & 7.875 & 8.7086 \\ 12 & 26 & 12.875 & 9.3723 \end{array}\] -Referring to Scenario 18-8, an $\bar { X }$ chart is to be used for the time required to register. The lower control limit for this data set is ________, while the upper control limit is ________.

The answer of SCENARIO 18-8 Recently, a university switched to a...

SCENARIO 18-3 A quality control analyst for a light bulb manufacturer is concerned that the time it takes to produce a batch of light bulbs is too erratic. Accordingly, the analyst randomly surveys 10 production periods each day for 14 days and records the sample mean and range for each day. $\begin{array}{ccc} \underline{\text { Day } }& \underline{\bar{X} \text { (in minutes) }} & \underline{\text {R}}\\ 1 & 58.5 & 5.1 \\ 2 & 47.6 & 7.8 \\ 3 & 64.3 & 6.1 \\ 4 & 60.6 & 5.7 \\ 5 & 63.7 & 6.2 \\ 6 & 57.5 & 6.0 \\ 7 & 55.0 & 5.4 \\ 8 & 54.9 & 6.1 \\ 9 & 55.0 & 5.9 \\ 10 & 62.7 & 5.0 \\ 11 & 61.9 & 7.1 \\ 12 & 60.0 & 6.5 \\ 13 & 58.3 & 5.9 \\ 14 & 52.0 & 5.2 \end{array}$ -Referring to Scenario 18-3, suppose the analyst constructs an \[\bar { X }\] chart to see if the production process is in-control. What is the center line for this chart?

A) 64.3 B) 59.5 C) 58.0 D) 57.1 A) 64.3 B) 59.5 C) 58.0 D) 57.1

SCENARIO 18-2 A political pollster randomly selects a sample of 100 voters each day for 8 successive days and asks how many will vote for the incumbent. The pollster wishes to construct a p chart to see if the percentage favoring the incumbent candidate is too erratic. \[\begin{array} { c c } \begin{array} { c } \text { Sample } \\ \underline{\text { (Day) }} \end{array} & \begin{array} { c } \text { Number Favoring } \\ \underline{\text { Incumbent Candidate }} \end{array} \\ 1 & 57 \\ 2 & 57 \\ 3 & 53 \\ 4 & 51 \\ 5 & 55 \\ 6 & 60 \\ 7 & 56 \\ 8 & 59 \end{array}\] -Referring to Scenario 18-2, what is the numerical value of the upper control limit for the p chart?

A) 0.92 B) 0.89 C) 0.71 D) 0.62 A) 0.92 B) 0.89 C) 0.71 D) 0.62

SCENARIO 18-4 A factory supervisor is concerned that the time it takes workers to complete an important production task (measured in seconds) is too erratic and adversely affects expected profits. The supervisor proceeds by randomly sampling 5 individuals per hour for a period of 10 hours. The sample mean and range for each hour are listed below. \[\begin{array} {ccc} \underline {\text { Hour }} & \underline { \bar { X } } & \underline { R } \\ 1 & 18.4 & 25 \\ 2 & 16.9 & 27 \\ 3 & 23.0 & 30 \\ 4 & 21.2 & 23 \\ 5 & 21.0 & 24 \\ 6 & 24.0 & 25 \\ 7 & 19.3 & 12 \\ 8 & 15.8 & 14 \\ 9 & 20.0 & 13 \\ 10 & 23.0 & 11 \end{array}\] She also decides that lower and upper specification limit for the critical-to-quality variable should be 10 and 30 seconds, respectively. -Referring to Scenario 18-4, suppose the supervisor constructs an $\bar { X }$ chart to see if the process is in-control. Which expression best describes this chart?

A) Decreasing trend B) In-control C) Increasing trend D) Individual outliers A) Decreasing trend B) In-control C) Increasing trend D) Individual outliers