5 steps in hypothesis testing

Hypothesis Testing: A Complete Guide for Beginners

In this blog, we’ll explain statistical hypothesis testing from the basics to more advanced ideas, making it easy to understand even for 10th-grade students.

By the end of this blog, you’ll be able to understand hypothesis testing and how it’s used in research.

What is a Hypothesis?

Table of Contents

A hypothesis is a statement that can be tested. It’s like a guess you make after observing something, and you want to see if that guess holds when you collect more data.

For example:

• “Eating more vegetables improves health.”
• “Students who study regularly perform better in exams.”

These statements are testable because we can gather data to check if they are true or false.

What is Hypothesis Testing?

Hypothesis testing is a statistical process that helps us make decisions based on data. Suppose you collect data from an experiment or survey. Hypothesis testing helps you decide whether the results are significant or could have happened by chance.

For example, if you believe a new teaching method helps students score better, hypothesis testing can help you decide if the improvement is real or just a random fluctuation.

Null and Alternative Hypothesis

Hypothesis testing usually involves two competing hypotheses:

• Example: “There is no difference in exam scores between students using the new method and those who don’t.”
• Example: “Students using the new method perform better in exams than those who don’t.”

Key Terms in Hypothesis Testing

Before diving into the details, let’s understand some important terms used in hypothesis testing:

1. Test Statistic

The test statistic is a number calculated from your data that is compared against a known distribution (like the normal distribution) to test the null hypothesis. It tells you how much your sample data differs from what’s expected under the null hypothesis.

The p-value is the probability of observing the sample data or something more extreme, assuming the null hypothesis is true. A smaller p-value suggests that the null hypothesis is less likely to be true. In many studies, a p-value of 0.05 or less is considered statistically significant.

3. Significance Level (α)

The significance level is the threshold at which you decide to reject the null hypothesis. Commonly, this level is set at 5% (α = 0.05), meaning there’s a 5% chance of rejecting the null hypothesis even when it is true.

4. Critical Value

The critical value is the boundary that defines the region where we reject the null hypothesis. It is calculated based on the significance level and tells us how extreme the test statistic needs to be to reject the null hypothesis.

5. Type I and Type II Errors

• Type I Error (False Positive): Rejecting the null hypothesis when it’s true.
• Type II Error (False Negative): Failing to reject the null hypothesis when it’s false.

In simpler terms:

• Type I error is like thinking something has changed when it hasn’t.
• Type II error is like thinking nothing has changed when it actually has.

Types of Hypothesis Testing

1. one-tailed test.

A one-tailed test checks for an effect in a single direction. For example, if you are only interested in testing whether students who study 2 hours daily score higher than those who don’t, that’s a one-tailed test.

2. Two-Tailed Test

A two-tailed test checks for an effect in both directions. This means you’re testing if the scores are different , regardless of whether they are higher or lower. For example, “Do students who study 2 hours daily score differently than those who don’t?” That’s a two-tailed test.

Steps in Hypothesis Testing

Step 1: define hypotheses.

Start by defining the:

• Null Hypothesis (H₀): The status quo or no change.
• Alternative Hypothesis (H₁): The hypothesis you believe in, suggesting that something has changed.

Step 2: Set the Significance Level (α)

Next, set the significance level, typically 0.05 . This means you’re willing to accept a 5% risk of incorrectly rejecting the null hypothesis.

Step 3: Collect and Analyze Data

Conduct your experiment or survey and collect data. Then, analyze this data to calculate the test statistic. The formula you use depends on the type of test you’re conducting (e.g., Z-test, T-test).

Step 4: Calculate the P-value or Critical Value

Compare the test statistic to a standard distribution (such as the normal distribution). If you calculate a p-value , compare it to the significance level. If the p-value is less than the significance level, reject the null hypothesis.

Alternatively, you can compare your test statistic to a critical value from statistical tables to determine if you should reject the null hypothesis.

Step 5: Make a Decision

Based on your calculations:

• If the p-value is less than the significance level (e.g., p < 0.05), reject the null hypothesis.
• If the p-value is greater than the significance level, do not reject the null hypothesis.

Step 6: Interpret the Results

Finally, interpret the results in context. If you reject the null hypothesis, you have evidence to support the alternative hypothesis. If not, the data does not provide enough evidence to reject the null.

P-Value and Significance

The p-value is a key part of hypothesis testing. It tells us the likelihood of getting results as extreme as the observed data, assuming the null hypothesis is true. In simple terms:

• A low p-value (≤ 0.05) suggests strong evidence against the null hypothesis, so you reject it.
• A high p-value (> 0.05) means the data is consistent with the null hypothesis, and you don’t reject it.

Here’s a table to summarize:

Common Hypothesis Tests

There are different types of hypothesis tests depending on the data and what you are testing for.

Example of Hypothesis Testing

Let’s say a nutritionist claims that a new diet increases the average weight loss for people by 5 kg in a month.

• Null Hypothesis (H₀): The average weight loss is not 5 kg (no difference).
• Alternative Hypothesis (H₁): The average weight loss is greater than 5 kg.

Suppose we collect data from 30 people and find that the average weight loss is 5.5 kg. Now we follow these steps:

• Significance level : Set α = 0.05 (5%).
• Calculate the test statistic: Using the T-test formula.
• Find the p-value : Calculate the p-value for the test statistic.
• Make a decision : Compare the p-value to the significance level.

If the p-value is less than 0.05, we reject the null hypothesis and conclude that the new diet results in more than 5 kg of weight loss.

Statistical hypothesis testing is an essential method in statistics for making informed decisions based on data. By understanding the basics of null and alternative hypotheses, test statistics, p-values, and the steps in hypothesis testing, you can analyze experiments and surveys effectively.

Hypothesis testing is a powerful tool for everything from scientific research to everyday decisions, and mastering it can lead to better data analysis and decision-making.

Also Read: Step-by-step guide to hypothesis testing in statistics

What is the difference between the null hypothesis and the alternative hypothesis?

The null hypothesis (H₀) is the default assumption that there is no effect or no difference. It’s what we try to disprove. The alternative hypothesis (H₁) is what you want to prove. It suggests that there is a significant effect or difference.

What is the difference between a one-tailed test and a two-tailed test?

A one-tailed test looks for evidence of an effect in one direction (either greater or smaller). A two-tailed test checks for evidence of an effect in both directions (whether greater or smaller), making it a more conservative test.

Can we always reject the null hypothesis if the p-value is less than 0.05?

Yes, if the p-value is less than 0.05 , we typically reject the null hypothesis. However, this does not guarantee that the alternative hypothesis is true; it simply indicates that the data provide strong evidence against it.

Related Posts

Step by Step Guide on The Best Way to Finance Car

The Best Way on How to Get Fund For Business to Grow it Efficiently

Leave a comment cancel reply.

Your email address will not be published. Required fields are marked *

User Preferences

Content preview.

Arcu felis bibendum ut tristique et egestas quis:

• Ut enim ad minim veniam, quis nostrud exercitation ullamco laboris
• Duis aute irure dolor in reprehenderit in voluptate
• Excepteur sint occaecat cupidatat non proident

Keyboard Shortcuts

11.2.1 - five step hypothesis testing procedure.

The examples on the following pages use the five step hypothesis testing procedure outlined below. This is the same procedure that we used to conduct a hypothesis test for a single mean, single proportion, difference in two means, and difference in two proportions.

When conducting a chi-square goodness-of-fit test, it makes the most sense to write the hypotheses first. The hypotheses will depend on the research question. The null hypothesis will always contain the equalities and the alternative hypothesis will be that at least one population proportion is not as specified in the null.

In order to use the chi-square distribution to approximate the sampling distribution, all expected counts must be at least five.

Expected Count

Where \(n\) is the total sample size and \(p_i\) is the hypothesized population proportion in the "ith" group.

To check this assumption, compute all expected counts and confirm that each is at least five.

In Step 1 you already computed the expected counts. Use this formula to compute the chi-square test statistic:

Chi-Square Test Statistic

\(\chi^2=\sum \dfrac{(O-E)^2}{E}\)

Where \(O\) is the observed count for each cell and \(E\) is the expected count for each cell.

Construct a chi-square distribution with degrees of freedom equal to the number of groups minus one. The p-value is the area under that distribution to the right of the test statistic that was computed in Step 2. You can find this area by constructing a probability distribution plot in Minitab. 

Unless otherwise stated, use the standard 0.05 alpha level.

\(p \leq \alpha\) reject the null hypothesis.

\(p > \alpha\) fail to reject the null hypothesis.

Go back to the original research question and address it directly. If you rejected the null hypothesis, then there is convincing evidence that at least one of the population proportions is not as stated in the null hypothesis. If you failed to reject the null hypothesis, then there is not enough evidence that any of the population proportions are different from what is stated in the null hypothesis.