CHAPTER 15

CHAPTER 15 NONPARAMETRIC STATISTICS

Learning Objectives • Determine situations where nonparametric procedures are better alternatives to the parametric tests • Understand the assumptions of nonparametric tests • Use one- and two-sample nonparametric tests • Use nonparametric alternatives to the single-factor ANOVA

Nonparametric vs. Parametric • Used an assumption that we are working with random samples from normal populations • Called parametric methods • Based on a particular parametric family of distributions • Describe procedures called nonparametric methods • Make no assumptions about the population distribution other than that it is continuous

Why Nonparametric Procedures • Distributions are not close to normal • Data need not be quantitative but can be categorical (such as yes or no, defective or non defective) or rank data • Are usually very quick and easy to perform • Provides considerable improvement over the normal-theory parametric methods • Not utilize all the information provided by the sample • Requirement of a larger sample size

Which One? • Which one to choose? • If both methods are applicable to a particular problem • Use the more efficient parametric procedure • Otherwise, use the non parametric procedure

SIGN TEST • Used to test hypotheses about the median of a continuous distribution • Mean of a normal distribution equals the median • Sign test can be used to test hypotheses about the mean of a normal distribution • Used the t-test in Chapter 9 • Sign test is appropriate for samples from any continuous distribution • Counterpart of the t-test

Description of the Test • Use the following differences • Xi is ith the sample observation and is the specified median value • Number of plus signs is a value of a binomial random variable that has the parameter p=1/2 • Reject the if the proportion of plus signs is significantly different from 1/2

Using P-value • Use the P-value • If r+< n/2 the P-value • If r+ > n/2 the P-value • If the P-value is less than the significance level , we will reject H0 and conclude that H1 is true

The Normal Approximation • Binomial distribution has well approximately a normal distribution when n >10 and p=0.5 • Mean=np and the variance=np(1-p) • Test statistics • Critical region can be chosen from the table of the standard normal distribution

Sign Test for Paired Samples • Applied to paired observations drawn from two continuous populations • Define the paired difference as • Test the hypothesis that the two populations have a common median • Equivalent to • Done by applying the sign test to the n observed differences

Example • Ten samples were taken from a plating bath used in an electronics manufacturing process, and the bath pH was determined. • The sample pH values are 7.91, 7.85, 6.82, 8.01, 7.46, 6.95, 7.05, 7.35, 7.25, 7.42 • Manufacturing engineering believes that pH has a median value of 7.0. Do the sample data indicate that this statement is correct? Use the sign test with =0.05 to investigate this hypothesis. Find the P-value for this test

Calculate the differences • Use the general procedure covered in Chapter 8 • Parameter of interest is the median of the distribution of pH • The • The • =0.05

Solution - Cont • Data and the observed plus signs 5. Test statistic is the observed number of plus differences r+=8 6. Reject H0 if the P-value corresponding to r=8 is less than or equal to = 0.05

Solution-Cont. 7. Since r >n/2=5, we calculate the P-value by using the binomial formula with n=10 and p=0.5 • Hence, the P-value = 2P(R+8|p=0.5) • Since P=0.109 is not less than = 0.05, we cannot reject the null hypothesis 8. Observed number of plus signs r = 8 was not large or enough to indicate that median pH is different from 7.0

Using Table • Table of critical values for the sign test • Appendix Table VII is for two-sided and one-sided alternative hypothesis • Let R=min (R+, R-) • Reject H0 • If r-≤ critical value; if (>) used for H1 • If r+≤ critical value; if (<) used for H1 • If r≤ critical value; if (≠) used for H1

Wilcoxon Signed-rank Test • Sign test uses only the plus and minus signs of the differences • Does not take into consideration the size or magnitude of these differences • Uses both direction (sign) and magnitude • In case of symmetric and continuous distributions • Test H0 as µ=µ0

Description of the Test • Compute the following quantities Xi- 0 • Xi is ith the sample observation i and 0is the specified median or mean value • Rank the absolute differences in ascending order • Give the ranks the signs • W+ be the sum of the positive ranks and W- be the sum of the negative ranks, and let W min(W+,W- ) • Table VIII contains critical values of W • Reject H0 • If w-≤ critical value; if (>) used for H1 • If w+≤ critical value; if (<) used for H1 • If w≤ critical value; if (≠) used for H1

Large-Sample Approximation • Large sample size (n>20) • has approximately a normal distribution • Mean and variance • Test statistics • Appropriate critical region can be chosen from a table of the standard normal distribution

Paired Observations • Applied to paired observations drawn from two continuous and symmetric populations • Define the paired difference as • Test the hypothesis that the two populations have a common mean • Equivalent to testing that the mean of the differences

Description of the Test • Differences are first ranked in ascending order of their absolute values • Ranks are given the signs of the differences • Ties are assigned average ranks • W+ be the sum of the positive ranks and W- be the sum of the negative ranks, and let W min(W+,W- ) • Table VIII contains critical values of W • Reject H0 • If w-≤ critical value; if (>) used for H1 • If w+≤ critical value; if (<) used for H1 • If w≤ critical value; if (≠) used for H1

Example • Consider the data in the previous example and assume that the distribution of pH is symmetric and continuous. • Use the Wilcoxon signed-rank test with =0.05 to test the following hypothesis H0: µ=7 vs. H1: µ≠7

Solution 1. Parameter of interest is the mean of the pH 2. H0: µ=7 3. H1: µ≠7 4. α=0.05 5. Test statistic w=min (w+, w-) 6. Reject H0 if w<w*0.05=8 from Table VIII

Solution – Cont. 7. Signed rank • Determine the minimum value of the following • w+ = ( 1.5 + 4 + 5 + 6 + 7 + 8 + 9 + 10)= 50.5 • w – = ( 1.5 + 3) = 4.5 • Test statistic is w = min (50.5,4.5)

Solution-Cont. 8. Since w=4.5 is less than the critical value w0.05 =8 • Reject the null hypothesis

WILCOXON RANK-SUM TEST • Statistical inference for two samples • Wilcox on rank-sum test is a non parametric alternative • Two independent continuous populations X1 and X2 with means 1 and 2 • Wish to test the following hypotheses • n1 and n2 are sample size

Description of the Test • Arrange all n1+n2 observations in ascending order of magnitude and assign ranks to them • Ties are assigned average rank • W1 be the sum of the ranks in the smaller sample (1), and define W2 to be the sum of the ranks in the other sample • Also can be found • Table IX contains the critical value of the rank sums for two significance levels • Reject H0 • If w2≤ critical value; if (>) used for H1 • If w1≤ critical value; if (<) used for H1 • If either w1 or w2≤ critical value; if (≠) used for H1

Large-Sample Approximation • When both n1 and n2 are moderately large • Distribution of w1 can be well approximated by the normal distribution with the following mean and variance • Test statistic • Appropriate critical region can be chosen from the table

Kruskal-Wallis Test • Recall the single-factor analysis of variance model • Error terms ijwere with mean zero and variance • Kruskal-Wallis test is a nonparametric alternative • Error terms ijare assumed to be from the same continuous distribution

Description of the Test • Compute the total number of observations • Rank all N observations from smallest to largest • Assign the smallest observation rank 1, the next smallest rank 2, . . . , and the largest observation rank N • Rij be the rank of observation Yij • Ri. denote the total and the. average of the niranks

Test Statistic • Calculate • H has approximately a chi-square distribution with a-1 degrees of freedom • Reject H0 if the observed value h is greater than the critical value, or • Critical region can be chosen from the Chi-square distribution table depending on whether the test is a two-tailed, upper-tail, or lower-tail test

Ties in the Kruskal-Wallis Test • Observations are tied, assign an average rank • use the following test statistic • niis the number of observations in the ith treatment • N is the total number of observations • S2 is just the variance of the ranks

Example 15-7 • Montgomery (2001) presented data from an experiment in which five different levels of cotton content in a synthetic fiber were tested to determine whether cotton content has any effect on fiber tensile strength. The sample data and ranks from this experiment are shown in following Table • Does cotton percentage affect breaking strength? Use α=0.01

Solution • Rank all observations from smallest to largest • Assign average rank (1 + 2 +3)/3 = 2 • Perform the same calculations for the other tied observations

Solution-Cont. • Data and Ranks for the Tensile Testing Experiment • There is a fairly large number of ties • Use the equation that was defined for the tied observations

Solution-Cont. • Thus • Test statistic • Since h> 13.28, we would reject the null hypothesis • Conclude that treatments differ • Same conclusion is given by the usual analysis of variance

Next Agenda • Introduces statistical quality control • Fundamentals of statistical process control

CHAPTER 15

CHAPTER 15

Presentation Transcript

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

CHAPTER 15

Chapter 15

Chapter 15

chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15:

Chapter 15-

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15

Chapter 15