Day 13: STA205 - Introduction to Statistical Methods

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Announcements:
- Return of Exam 1
  - Unadjusted mean: 82.75
  - SD: 26.88
  - Curve: Add 15 points to your score.
  - Furthermore, if you'll come see me, to discuss the exam and the points you've missed, I'll give you back 30% of the remaining points you missed. You should check out the key before coming to see me.
  - Key
Any questions over your homework problems, or the exam?
Section 5.1: Sampling distributions and the normal curve (why is the normal distribution so important?)
- Here's the key thing: the sampling distribution is approximately normal for a large sample size n ("large" generally taken as $n\ge{30}$ ).
- See Figure 5.5, p. 172
- This result is encapsulated in The Central Limit Theorem (p. 167), and in the graphs of Figure 5.3, p. 168.
- Last time we did example problem: #6, p. 178
  - A couple of key points, for parts a and b:
    - You can't assume that the underlying distribution of the amount of coffee in an individual cup is normal.
    - All we know is its mean and standard deviation.
    - We can assume that the distribution of the sample mean is normally distributed, because we have a sample of more than 30.
    - We can deduce the parameters of the sampling distribution of the sample mean from the parameters of the underlying distribution of the amount of coffee in an individual cup.
    - Then we carry out the problem using the usual Z-Table tricks.
  - For part c, we should understand that, as , the sampling distribution of the sample mean will
    - become more and more normal (by the Central Limit Theorem), and
    - become tighter and tighter and tighter about the mean (smaller variance), as indicated by the standard error of the mean: ${\sigma_{\bar{x}}=\frac{\sigma}{\sqrt{n}}}$ It gets smaller and smaller and smaller.
- Revisit #6 from the exam
Section 5.2: The Sampling distribution of the Sample Proportion
- Definition: Consider a sample of qualitative data for which one category, or attribute, is of interest. To describe such a sample, we will use the proportion of the sample having the attribute of interest. This statistic is denoted by the letter p.
- Properties of the sampling distribution of the sample proportion:
  - The mean of the sampling distribution of p, denoted ${\mu_p}$ , is equal to the mean of the population ${\pi}$
  - The standard deviation of the sampling distribution of p, denoted ${\sigma_p}$ , is ${\sigma_p=\sqrt{\frac{\pi(1-\pi)}{n}}}$ where n is the sample size.
  - Here's the key thing: the sampling distribution for p is approximately normal for a large sample size n ("large" generally taken as greater than or equal to n=30 at the very least, but in this case it depends as well on the value of ${\pi}$ ) as well.
  - Our choice of n to ensure normality is made so that three standard errors from the estimated ${\mu_p}$ are completely contained inside the interval [0,1]: ${0<\mu_p-3\sigma_p}$ and ${\mu_p+3\sigma_p<1}$
  - See p. 186 for the strategy
  - See Figure 5.7 and 5.8, p. 182-183
- Calculating probabilities for p involves computing Z-scores, as usual
- Exercise #8, p. 189
Section 5.3: Using conjectured values of the population mean to make inferences:
- Check out p. 196 for strategy, first; then
- Exercise #5, p. 202

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