For x1=34,n1=50,x2=52,x_1=34,n_1=50,x_2=52, & n2=75n_2=75, test the claim that p1<p2p_1<p_2 for α=0.01\alpha=0.01 using...(B) Confidence Interval

C-level = 0.99, not enough evidence to suggest p1p2p_1.

For x 1 = 34 , n 1 = 50 , x 2 = 52 , x_1=34,n_1=50,x_2=52, & n 2 = 75 n_2=75 , test the claim that p 1 < p 2 p_1<p_2 for α = 0.01 \alpha=0.01 using... (B) Confidence Interval

Welcome back. For this problem, we have the same values for x one, n one, x two, and n two, and we still wanna test the claim that p one is less than p two for alpha equals 0.01. But this time, we wanna do it using a confidence interval. As a reminder, the confidence interval will be for the difference between the two proportions, so p one minus p two. Now if it is true that p one is less than p two, then that would mean that p one minus p two would be negative because a smaller number minus a larger number is negative. So if our confidence interval only included negative values, that would be enough evidence to suggest that p one is less than p two. So we'll be paying attention to whether our confidence interval is entirely negative or whether it includes zero and some positives. So let's make that confidence interval. We'll start by clicking on the stat button, scrolling to the right to the test menu, and we want option b, so let's scroll down to it. Once there, we can click enter, and that's step one all set. You'll notice that the values we've already entered in for x one, n one, x two, and n two are already there, so that's all set. We will need to adjust our confidence level or c level. As a reminder, alpha is 0.01, and our c level is going to be one minus our alpha value, which in this case is one minus point zero one, which is point nine nine. So we should change that point nine five to a point nine nine. Once that's all set, we can scroll down to calculate and click enter. That's step two, all set. And we'll see our confidence interval appear in the viewing window. It goes from approximately negative 0.23 to about 0.21. Now I can see here that this is not just negatives. It goes from a negative to a positive. So this confidence interval includes positives and zero. This means that we do not have enough evidence. To suggest that p one is less than p two. Great work.

For x1=34,n1=50,x2=52,$$x_1=34$$,$$n_1=50$$,$$x_2=52$$, & n2=75n_2=75, test the claim that p1p2p_1 for α=0.01\alpha=0.01 using...(B) Confidence Interval

C-level = 0.99, not enough evidence to suggest p1p2p_1.

C-level = 1, we reject the H0H_0 since there is enough evidence to suggest p1p2p_1.

C-level = 0.99, we fail to reject the H0H_0

Table of contents

Skip topic navigation

1. Introduction to Statistics53m

Intro to Stats
22m

Intro to Collecting Data
8m

Sampling Methods
23m

2. Describing Data with Tables and Graphs2h 2m

Visualizing Qualitative vs. Quantitative Data
4m

Frequency Distributions
35m

Histograms
7m

Histograms w/ Graphing CalculatorBonus
13m

Bar Graphs and Pareto Charts
11m

Pie Charts
9m

Frequency Polygons
10m

Dot Plots
6m

Stemplots (Stem-and-Leaf Plots)
14m

Time-Series Graph
9m

3. Describing Data Numerically2h 8m

Mean
9m

Median
20m

Mode
7m

Standard Deviation
16m

Interpreting Standard Deviation
20m

Percentiles & Quartiles
14m

5-Number Summary Using a TI-84Bonus
10m

Boxplots
8m

Descriptive Statistics-ExcelBonus
11m

Boxplots-ExcelBonus
8m

4. Probability2h 27m

Basic Concepts of Probability
7m

Complements
6m

Addition Rule
17m

Multiplication Rule: Independent Events
11m

Introduction to Contingency Tables
17m

Multiplication Rule: Dependent Events
23m

Bayes' Theorem
13m

Fundamental Counting Principle
8m

Counting
41m

5. Binomial Distribution & Discrete Random Variables3h 28m

Discrete Random Variables
38m

Binomial Distribution
1h 17m

Finding Binomial Probabilities-ExcelBonus
17m

Poisson Distribution
45m

Finding Poisson Probabilities-ExcelBonus
15m

Hypergeometric Distribution
14m

6. Normal Distribution & Continuous Random Variables2h 21m

Uniform Distribution
19m

Standard Normal Distribution
39m

Probabilities & Z-Scores w/ Graphing CalculatorBonus
19m

Non-Standard Normal Distribution
30m

Finding Probabilities, Z Values, and X Values with the Normal Distribution-ExcelBonus
32m

7. Sampling Distributions & Confidence Intervals: Mean3h 37m

Sampling Distribution of the Sample Mean and Central Limit Theorem
19m

Distribution of Sample Mean - ExcelBonus
23m

Introduction to Confidence Intervals
22m

Confidence Intervals for Population Mean
1h 26m

Determining the Minimum Sample Size Required
12m

Finding Probabilities and T Critical Values - ExcelBonus
28m

Confidence Intervals for Population Means - ExcelBonus
25m

8. Sampling Distributions & Confidence Intervals: Proportion2h 20m

Sampling Distribution of Sample Proportion
35m

Confidence Intervals for Population Proportion
45m

Confidence Intervals for Population Proportion - ExcelBonus
12m

Chi Square Distribution
20m

Confidence Intervals for Population Variance
26m

9. Hypothesis Testing for One Sample5h 15m

Steps in Hypothesis Testing
1h 13m

Performing Hypothesis Tests: Means
1h 1m

Hypothesis Testing: Means - ExcelBonus
42m

Performing Hypothesis Tests: Proportions
39m

Hypothesis Testing: Proportions - ExcelBonus
27m

Performing Hypothesis Tests: Variance
12m

Critical Values and Rejection Regions
29m

Link Between Confidence Intervals and Hypothesis Testing
12m

Type I & Type II Errors
16m

10. Hypothesis Testing for Two Samples5h 35m

Two Proportions
1h 12m

Two Proportions Hypothesis Test - ExcelBonus
28m

Two Means - Unknown, Unequal Variance
1h 2m

Two Means - Unknown Variances Hypothesis Test - ExcelBonus
12m

Two Means - Unknown, Equal Variance
15m

Two Means - Unknown, Equal Variances Hypothesis Test - ExcelBonus
9m

Two Means - Known Variance
12m

Two Means - Sigma Known Hypothesis Test - ExcelBonus
21m

Two Means - Matched Pairs (Dependent Samples)
42m

Matched Pairs Hypothesis Test - ExcelBonus
12m

Two Variances and F Distribution
29m

Two Variances - Graphing CalculatorBonus
15m

11. Correlation1h 24m

Scatterplots & Intro to Correlation
26m

Correlation Coefficient
21m

Creating Scatterplots and FInding Correlation Coefficient - ExcelBonus
6m

Hypothesis Tests for Correlation Coefficient Using TI-85Bonus
17m

Inferences for the Correlation Coefficient - ExcelBonus
11m

12. Regression3h 42m

Linear Regression & Least Squares Method
26m

Residuals
12m

Coefficient of Determination
12m

Regression Line Equation and Coefficient of Determination - ExcelBonus
8m

Finding Residuals and Creating Residual Plots - ExcelBonus
11m

Inferences for Slope
32m

Enabling Data Analysis ToolpakBonus
1m

Regression Readout of the Data Analysis Toolpak - ExcelBonus
21m

Prediction Intervals
13m

Prediction Intervals - ExcelBonus
19m

Multiple Regression - ExcelBonus
29m

Quadratic Regression
23m

Quadratic Regression - ExcelBonus
10m

13. Chi-Square Tests & Goodness of Fit2h 31m

Goodness of Fit Test
50m

Goodness of FIt Test Using TI-84Bonus
18m

Goodness of Fit Test - ExcelBonus
10m

Contingency Tables
13m

Independence Tests
14m

Homogeneity Tests
11m

Using Matrices on a TI-84Bonus
6m

Independence Test Using TI-84Bonus
12m

Independence Tests - ExcelBonus
13m

14. ANOVA2h 33m

Introduction to ANOVA
35m

One-Way ANOVA - ExcelBonus
12m

Multiple Comparisons: Tukey Test
14m

Multiple Comparisons: Tukey-Kramer Test
15m

Multiple Comparisons: Bonferoni Test
24m

Two-Way ANOVA
32m

Two-Way ANOVA - ExcelBonus
18m

10. Hypothesis Testing for Two Samples

Two Proportions

Statistics for Business

10. Hypothesis Testing for Two Samples

Two Proportions

Previous problem

Struggling with Statistics for Business?

Join thousands of students who trust us to help them ace their exams!

Multiple Choice

For $x_{1} = 34, n_{1} = 50, x_{2} = 52,$ & $n sub 2 equals 75$ , test the claim that $p sub 1 is less than p sub 2$ for $alpha equals 0.01$ using...
(B) Confidence Interval

C-level = 0.99, not enough evidence to suggest $p sub 1 is less than p sub 2$ .

C-level = 1, we reject the $H sub 0$ since there is enough evidence to suggest $p sub 1 is less than p sub 2$ .

C-level = 0.99, we fail to reject the $H sub 0$

The confidence interval does not include zero, we fail to reject $H sub 0$ .

0 Comments

Previous problem

Verified step by step guidance

Identify the sample proportions for each group: calculate

{\(\hat{p}\)}_{1} = \frac{34}{50}

and

{\(\hat{p}\)}_{2} = \frac{52}{75}

Calculate the difference between the sample proportions:

\(\hat{p}\)_1 - \(\hat{p}\)_2

Determine the standard error (SE) of the difference between two proportions using the formula:

SE = \(\sqrt{\frac{\hat{p}\)_1(1 - \(\hat{p}\)_1)}{n_1} + \(\frac{\hat{p}\)_2(1 - \(\hat{p}\)_2)}{n_2}}

Find the critical z-value for a 99% confidence level (since $ \alpha = 0.01 $) from the standard normal distribution table, corresponding to the one-tailed test for the claim