Information Systems homework help

Information Systems homework help. Show all relevant work; use the equation editor in Microsoft Word when necessary.
1. Chapter 13, numbers 13.6, 13.8, 13.9, and 13.10
2. Chapter 14, numbers 14.11, 14.12, and 14.14
3. Chapter 15, numbers 15.7, 15.8, 15.10 and 15.14
13.6 It’s well established, we’ll assume, that lab rats require an average of 32 trials in a
complex water maze before reaching a learning criterion of three consecutive errorless trials. To determine whether a mildly adverse stimulus has any effect on performance, a sample of seven lab rats were given a mild electrical shock just before
each trial.
(a) Given that X = 34.89 and s = 3.02, test the null hypothesis with t, using the .05 level
of significance.
(b) Construct a 95 percent confidence interval for the true number of trials required to
learn the water maze.
(c) Interpret this confidence interval
13.8 Assume that, on average, healthy young adults dream 90 minutes each night, as
inferred from a number of measures, including rapid eye movement (REM) sleep. An
investigator wishes to determine whether drinking coffee just before going to sleep
affects the amount of dream time. After drinking a standard amount of coffee, dream
time is monitored for each of 28 healthy young adults in a random sample. Results
show a sample mean, X , of 88 minutes and a sample standard deviation, s, of
9 minutes.
(a) Use t to test the null hypothesis at the .05 level of significance.
(b) If appropriate (because the null hypothesis has been rejected), construct a 95 percent confidence interval and interpret this interval.
13.9 In the gas mileage test described in this chapter, would you prefer a smaller or a
larger sample size if you were
(a) the car manufacturer? Why?
(b) a vigorous prosecutor for the federal regulatory agency? Why?
13.10 Even though the population standard deviation is unknown, an investigator uses
z rather than the more appropriate t to test a hypothesis at the .05 level of significance.
(a) Is the true level of significance larger or smaller than .05?
(b) Is the true critical value larger or smaller than that for the critical z?
14.11 To test compliance with authority, a classical experiment in social psychology requires subjects to administer increasingly painful electric shocks to seemingly helpless victims who agonize in an adjacent room.* Each subject earns a score between 0 and 30, depending on the point at which the subject refuses to comply with authority—an investigator, dressed in a white lab coat, who orders the administration of increasingly intense shocks. A score of 0 signifies the subject’s unwillingness to comply at the very outset, and a score of 30 signifies the subject’s willingness to comply completely with the experimenter’s orders.
Ignore the very real ethical issues raised by this type of experiment, and assume that you want to study the effect of a “committee atmosphere” on compliance with authority. In one condition, shocks are administered only after an affirmative decision by the committee, consisting of one real subject and two associates of the investigator, who act as subjects but, in fact, merely go along with the decision of the real subject. In the other condition, shocks are administered only after an affirmative decision by a solitary real subject.
A total of 12 subjects are randomly assigned, in equal numbers, to the committee condition (X1) and to the solitary condition (X2). A compliance score is obtained for each subject. Use t to test the null hypothesis at the .05 level of significance.
Compliance Scores
COMITTEE SOLITARY
2 3
5 8
20 7
15 10
4 14
10 0
14.12 To determine whether training in a series of workshops on creative thinking increases IQ scores, a total of 70 students are randomly divided into treatment and control groups of 35 each. After two months of training, the sample mean IQ ( X1) for the treatment group equals 110, and the sample mean IQ (X2) for the control group equals 108. The estimated standard error equals 1.80.
(a) Using t, test the null hypothesis at the .01 level of significance.
(b) If appropriate (because the null hypothesis has been rejected), estimate the standardized effect size, construct a 99 percent confidence interval for the true population mean difference, and interpret these estimates.
*14.14 An investigator wishes to determine whether alcohol consumption causes a deterioration in the performance of automobile drivers. Before the driving test, subjects drink a glass of orange juice, which, in the case of the treatment group, is laced with two ounces of vodka. Performance is measured by the number of errors made on a driving simulator. A total of 120 volunteer subjects are randomly assigned, in equal numbers, to the two groups. For subjects in the treatment group, the mean number of errors (X₁) equals 26.4, and for subjects in the control group, the mean number of errors ( X₂) equals 18.6. The estimated standard error equals 2.4.
(a) Use t to test the null hypothesis at the .05 level of significance.
(b) Specify the p-value for this test result.
(c) If appropriate, construct a 95 percent confidence interval for the true population
mean difference and interpret this interval.
(d) If the test result is statistically significant, use Cohen’s d to estimate the effect size,
given that the standard deviation, Sp, equals 13.15.
(e) State how these test results might be reported in the literature, given S1 = 13.99 and
S2 = 12.15.
Answers on pages 439 and 440
*15.7 An educational psychologist wants to check the claim that regular physical exercise improves academic achievement. To control for academic aptitude, pairs of college students with similar GPAs are randomly assigned to either a treatment group that attends daily exercise classes or a control group. At the end of the experiment, the following GPAs are reported for the seven pairs of participants:
PAIR
NUMBER GPAs
PHYSICAL EXERCISE
(X1) NO PHYSICAL EXERCISE
(X2)
1 4.00 3.75
2 2.67 2.74
3 3.65 3.42
4 2.11 1.67
5 3.21 3.00
6 3.60 3.25
7 2.80 2.65
15.8 A school psychologist wishes to determine whether a new antismoking film actually
reduces the daily consumption of cigarettes by teenage smokers. The mean daily
cigarette consumption is calculated for each of eight teenage smokers during the
month before and the month after the film presentation, with the following results:
SMOKER NUMBER MEAN DAILY CIGARETTE CONSUMPTION
BEFORE FILM (X1) AFTER FILM (X2)
1 28 26
2 29 27
3 31 32
4 44 44
5 35 35
6 20 16
7 50 47
8 25 23
(Note: When deciding on the form of the alternative hypothesis, H1, remember that a positive difference score (D = X1 − X2 ) reflects a decline in cigarette consumption.)
(a) Using t, test the null hypothesis at the .05 level of significance.
(b) Specify the p-value for this test result.
(c) If appropriate (because the null hypothesis was rejected), construct a 95 percent
confidence interval for the true population mean for all difference scores and
use Cohen’s d to obtain a standardized estimate of the effect size. Interpret
these results.
(d) What might be done to improve the design of this experiment?
*15.10 In a classic study, which predates the existence of the EPO drug, Melvin Williams of Old Dominion University actually injected extra oxygen-bearing red cells into the subjects’ bloodstream just prior to a treadmill test. Twelve long-distance runners were tested in 5-mile runs on treadmills. Essentially, two running times were obtained for each athlete, once in the treatment or blood-doped condition after the injection of two pints of blood and once in the placebo control or non-blood-doped condition after the injection of a comparable amount of a harmless red saline solution. The presentation of the treatment and control conditions was counterbalanced, with half of the subjects unknowingly receiving the treatment first, then the control, and the other half receiving the conditions in reverse order. Since the difference scores, as reported in the New York Times, on May 4, 1980, are calculated by subtracting blood-doped running times from control running times, a positive mean difference signifies that the treatment has a facilitative effect, that is, the athletes’ running times are shorter when blood doped. The 12 athletes had a mean difference running time, D, of 51.33 seconds with a standard deviation, SD , of 66.33 seconds.
(a) Test the null hypothesis at the .05 level of significance.
(b) Specify the p-value for this result.
(c) Would you have arrived at the same decision about the null hypothesis if the difference scores had been reversed by subtracting the control times from the blood-doped times?
(d) If appropriate, construct and interpret a 95 percent confidence interval for the true
effect of blood doping.
(e) Calculate and interpret Cohen’s d for these results.
(f) How might this result be reported in the literature?
(g) Why is it important to counterbalance the presentation of blood-doped and control
conditions?
(h) Comment on the wisdom of testing each subject twice—once under the blood-doped condition and once under the control condition—during a single 24-hour
period. (Williams actually used much longer intervals in his study.)
Answers on pages 442 and 443.
*15.14 In Table 7.4 on page 142, seven of the ten top hitters in the major league baseball in
2014 had lower batting averages in 2015, supporting regression toward the mean.
Treating averages as whole numbers (without decimal points) and subtracting their
batting averages for 2015 from those for 2014 (so that positive difference scores
support regression toward the mean), we have the following ten difference scores:
28, 53, 17, 37, 27, 27, 22, −25, −7, 0.
(a) Test the null hypothesis (that the hypothetical population mean difference equals
zero for all sets of top ten hitters over the years) at the .05 level of significance.
(b) Find the p-value.
(c) Construct a 95 percent confidence interval.
(d) Calculate Cohen’s d.
(e) How might these findings be reported?

Information Systems homework help