In this study, the college instructor aims to know whether there are differences in the performance of students among the three classroom environments. We consider the _______________. as the factor variable. Also, the response variable is the _____________. which is in the ___________________. level of measurement. The students were independently and randomly assigned to each of the three classroom environments: Mozart piece, relaxation music, and silence.

 

The p-values obtained from the Shapiro-Wilk test indicate that the assumption of ________________. was ___________________. Further, results obtained from the Levene’s test indicate that the assumption of _______________ was ________________. Considering the variable of interest and the results of the test for the assumptions, the appropriate test procedure to analyze the given data is the ________________

 

The appropriate set of hypotheses to test the given objective is Ho: _____________and Ha: _________________. The test yield a p-value equal to _______________. Thus, we can infer that we have___________________. evidence to say that ___________________.. Given this result, we ______________________. with a posthoc analysis.

 

(Fill out this paragraph if a posthoc analysis is appropriate.)

A posthoc analysis using ______________. was done to determine which of the three classroom environments had a different mean test score. Based on the results of the test, the classroom environments which provided different mean test scores are ____________________.

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R COMMANDER OUTPUT #5.5 Parametric posthoc analysis Linear Hypotheses: Estimate Sstd. Error t value Pr (>|t|) в - A == 0 -3.2667 0.4821 -6.776 <0.000001 C - A == 0 -7.6000 0.4821 -15.766 <0.000001 c - B == 0 -4.3333 0.4821 -8.989 <0.000001 R COMMANDER OUTPUT #5.6 R COMMANDER OUTPUT #5.6 Nonparametric posthoc analysis Comparison of x by group (No adjustment) Nonparametric test data: score by classroom Kruskal-Wallis chi-squared = 37.709, df = 2, p-value = 0.000000006479 Col Mean-| Row Mean | A B 3.017854 0.0013* 6.140495 3.122641 0.0000* 0.0009*

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PROBLEM 5: Can music help you study? The sound waves produced by the music that we hear reach our brain by converting them into electrical signals which then travel to the eighth cranial nerve of our brain. Have you tried listening to music while studying? In the early 1990s, an experiment by Raucher and his colleagues revealed that listening to classical music could improve memory. So, does listening to music help or hinder students' learning? A college instructor wishes to test this so-called "Mozart Effect" on a random sample of 45 students. Each randomly selected student was assigned to study in a classroom under a certain environment (Classrooms A, B, and C). The students were then given a memorization task to be accomplished within 10 minutes. While performing the task, the students in Classroom A listened to a Mozart piece, students in Classroom B listened to relaxation music, and students in Classroom C sat in silence. At the end of the task, the students were given a 20-item test and their scores were recorded. R COMMANDER OUTPUT #5.1 R COMMANDER OUTPUT #5.2 Shapiro-Wilk normality test Levene's Test data: for Homogeneity of Variance Df F value Pr (>F) group 2 0.5473 0.5826 score w = 0.90955, p-value = 0.1333 w = 0.92179, p-value = 0.2051 w = 0.93674, p-value = 0.3431 classroom = A classroom = B classroom = C 42 R COMMANDER OUTPUT #5.3 R COMMANDER OUTPUT #5.4 Parametric test Df Sum Sq Mean Sq F value Pr (>F) sd data:n mean A 18.33333 1.175139 B 15.06667 1.222799 C 10.73333 1.533747 15 classroom 2 436.0 218.02 125.1 <2e-16 15 Residuals 42 73.2 1.74 15