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8.4.1: Project Checkpoint

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    As part of your semester project, you’ve been working with housing or economic data from two different cities or regions. Now that you know how to run a two-sample hypothesis test, it’s time to apply that technique to your own data.

    Research Question:

    Is one city more expensive than the other?

    Think about how this could apply to your dataset:

    • Are you comparing rents, home prices, or another cost-related indicator?
    • Is the cost measure available for both cities in your data?
    • What exactly are you comparing — the mean monthly rent? Average price per square foot?

    Once you have your comparison variable selected, follow the five-step hypothesis testing process with your data.

    Instructions

    1. State your hypotheses clearly
      Use appropriate notation and define what \( \mu_1 \) and \( \mu_2 \) represent in the context of your project.
    2. Compute your sample statistics
      For each city, calculate:
      • Sample mean \( \bar{x}_1, \bar{x}_2 \)
      • Sample standard deviation \( s_1, s_2 \)
      • Sample size \( n_1, n_2 \)
      These will be used in the Welch’s t-test formula:

      \[ T = \frac{\bar{x}_1 - \bar{x}_2}{\sqrt{\frac{s_1^2}{n_1} + \frac{s_2^2}{n_2}}} \]

    3. Choose your significance level (α)
      Most projects will use \( \alpha = 0.05 \), but you should briefly justify your choice.
    4. Calculate the test statistic and p-value
      You can use a statistical tool such as:
      • ****Need link to a tool here****
      • Google Sheets: use =T.TEST() function
      • Excel, R, Python, a graphing calculator, or even AI assistance
    5. Make your conclusion
      Refer back to your hypotheses and use your p-value to decide whether to:
      • Reject the null hypothesis
      • Fail to reject the null hypothesis
      Interpret the result in context: Does your data give strong evidence that one city is more expensive?

    Deliverable

    Add this analysis to your semester project report. Be sure to include:

    • Your clearly written hypotheses (null and alternative)
    • A summary of your sample statistics
    • A brief explanation of the method and tool you used
    • Your calculated test statistic and p-value
    • Your written conclusion — in context of your data
    💡 Tip: Be sure to consider your assumptions! Is it reasonable to treat the two samples as independent? Did either group have extreme variation or small sample size?

    This page titled 8.4.1: Project Checkpoint is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by Mathematics Department.

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