Statistical Quality Control IE 3255 Spring 25 Solution HomeWork #2. (a)stem-and-leaf, No of samples, N = 8 Leaf Unit =. Stem Leaf Frequency 2+ 3-3+ 4-4+ 5-5+ - + 7-8 334 77978 33333242344 585958988995 33242234222232 58987 44 8599 2 2 28 (5) 37 2 2 (b) Frequency distribution of chemical yield class Yield Midpoint Frequency Cumulative Relative Cum. Rel. % Frequency Frequency Frequency 2. x <2.7 3.33.. 2 2.7 x <3.33 3.3.3 3 3.33 x <4. 3.7 4 5.5.3 4 4. x <4.7 4.33 9 4.3.75 5 4.7 x <5.33 5 2 35.23.438 5.33 x <. 5.7 22 57.275.73 7. x <.7.33 2 9.5.83 8.7 x < 7.33 7 7 7.88.95 9 7.33 x <8. 7.7 4 8.5. 8. x < 9. 8.5 8.. Total 8 8 Histogram of Batch Viscosity 25 2 Frequency 5 5 Viscosity
The shape of the histogram is not symmetric, and there appear to be one location of central tendency. The distribution does resemble normal probability distribution. (c)stem-and-leaf, No of samples, N = 8 Leaf Unit =. Stem Leaf Frequency 2+ 3-3+ 4-4+ 5-5+ - + 7-8 334 77789 22333333444 555588889999 22222222333344 57889 44 5899 2 2 28 (5) 37 2 2 Median observation rank is (.5)(N) +.5 = (.5)(8) +.5 = 4.5 X.5 = (4.9 + 4.9)/2 = 4.9 Q observation rank is (.25)(N) +.5 = (.25)(8) +.5 = 2.5 Q = (4.3 + 4.3)/2 = 4.3 Q3 observation rank is (.75)(N) +.5 = (.75)(8) +.5 =.5 Q3 = (5. + 5.5)/2 = 5.55 (d) th percentile observation rank = (.)(N) +.5 = (.)(8) +.5 = 8.5 X. = (3.7 + 3.7)/2 = 3.7 9 th percentile observation rank = (.9)(N) +.5 = (.9)(8) +.5 = 72.5 X.9 = (.4 +.)/2 =.25 (e) Box plot for the chemical process 4.3 4.9 5.55 2. 7. 2
2. Consider the viscosity data in Exercise. Construct a normal probability plot, a lognormal probability plot, and a Weibull probability plot for these data. Based on the plots, which distribution seems to be the best model for the viscosity data? 3
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3. A mechatronic assembly is subjected to a final functional test. Suppose that defects occur at random in these assemblies, and that defects occur according to a Poisson distribution with parameter λ =.2. (a) What is the probability that an assembly will have exactly one defect? (b) What is the probability that an assembly will have one or more defects? (c) Suppose that you improve the process so that the occurrence rate of defects is cut in half to λ =.. What effect does this have on the probability that an assembly will have one or more defects? Solution This is a Poisson distribution with parameter λ =.2, x ~ POI(.2). (a).2 e (.2) Pr{ x = } = p() = =.9! (b).2 e (.2) Pr{ x } = Pr{ x = } = p() =! = -.982 =.98 (c) Poisson distribution with parameter λ =., x ~ POI(.).. e (.) Pr{ x } = Pr{ x = } = p() =! = -.99 =. Cutting the rate at which defects occur reduces the probability of one or more defects approximately half, from.98 to.. 5
4. A production process operates with 2% nonconforming output. Every hour a sample of 5 units of product is taken, and the number of nonconforming units counted. If one or more nonconforming units are found, the process is stopped and the quality control technician must search for the cause of nonconforming production. Evaluate the performance of this decision rule. Solution This is a binomial distribution with parameter p =.2 and n = 5. The process is stopped if x. 5 5 Pr{ x } = Pr{ x < } = Pr{ x = } = (.2) (.2) =.34 =.3 The decision rule means that 3.% of the samples will have one or more nonconforming units, and the process will be stopped to look for a cause. This is a somewhat difficult operating situation. It will cost the company a lot on down time.
5. An inspector is looking for nonconforming welds in the gasoline pipeline between Phoenix and Tucson. The probability that any particular weld will be defective is.. The inspector is determined to keep working until finding three defective welds. If the welds are located ft apart, what is the probability that the inspector will have to walk 5 ft? What is the probability that the inspector will have to walk more than 5 ft?. A population has a mean µ of 44.3 and a standard deviation σ of 2.. (a) Analyze the problem with a sketch of the normal curve. (b) What percentage of the measurements is larger than 4? (a) b. P{x > 4} = - P{x < 4} = - P{x < 4} 4-44.3 = - P{z < } 2. = Φ(.895) =.793 =.2897 = 2.9% 7
7. An electronic component in an automobile has a useful life described by an exponential distribution with failure rate -5 /h. (a) What is the mean time to failure for this component? (b) What is the probability that this component would fail before its expected life. (c) If failure rate is -8 /h,compute the probability that the component would fail before its expected life. (d) Compare results from (b) and (c). Solution (a) This is exponential distribution with parameter λ = -5 Mean time failure rate = /λ = 5 =, hours (b) Probability that this component would fail before its expected life. / λ λt P x = λe dt = e =.32 λ (c) If failure rate, λ = -8, probability that this component would fail before its expected life becomes / λ λt P x = λe dt = e =.32 λ (d) Comparing b and c, one concludes that the probability that a value of an exponential random variable will be less than its mean is.322, regardless of the value of λ. 8