Examples of chi-square distribution in the following topics:
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- Define the Chi Square distribution in terms of squared normal deviates
- The Chi Square distribution is the distribution of the sum of squared standard normal deviates.
- The mean of a Chi Square distribution is its degrees of freedom.
- The Chi Square distribution is very important because many test statistics are approximately distributed as Chi Square.
- Chi Square distributions with 2, 4, and 6 degrees of freedom
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- For instance, Figure 6.9(b) shows the upper tail of a chi-square distribution with 2 degrees of freedom.
- Figure 6.9(d) shows a cutoff of 11.7 on a chi-square distribution with 7 degrees of freedom.
- Figure 6.9(e) shows a cutoff of 10 on a chi-square distribution with 4 degrees of freedom.
- Figure 6.9(f) shows a cutoff of 9.21 with a chi-square distribution with 3 df.
- (a) Chi-square distribution with 3 degrees of freedom, area above 6.25 shaded.
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- The chi-square distribution is used to construct confidence intervals for a population variance.
- A chi-square distribution can be used to construct a confidence interval for this variance.
- The chi-square distribution with a $k$ degree of freedom is the distribution of a sum of the squares of $k$ independent standard normal random variables.
- In fact, the chi-square distribution enters all analyses of variance problems via its role in the $F$-distribution, which is the distribution of the ratio of two independent chi-squared random variables, each divided by their respective degrees of freedom.
- The chi-square distribution is a family of curves, each determined by the degrees of freedom.
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- This is where the chi-square distribution becomes useful.
- How many degrees of freedom should be associated with the chi-square distribution used for ?
- The chi-square distribution and p-value are shown in Figure 6.10.
- Degrees of freedom: We only apply the chi-square technique when the table is associated with a chi-square distribution with 2 or more degrees of freedom.
- The p-value for the juror hypothesis test is shaded in the chi-square distribution with df = 3.
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- where df = degrees of freedom depend on how chi-square is being used.
- (If you want to practice calculating chi-square probabilities then use df = n−1.
- For the χ2 distribution, the population mean is µ = df and the population standard deviation is $\sigma = \sqrt{2 \cdot df}$.
- The random variable for a chi-square distribution with k degrees of freedom is the sum of k independent, squared standard normal variables.
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- In short, we simulate a new sample based on the purported bin probabilities, then compute a chi-square test statistic $X^2_{sim}$.
- We do this many times (e.g. 10,000 times), and then examine the distribution of these simulated chi-square test statistics.
- Since the minimum bin count condition was satisfied, the chi-square distribution is an excellent approximation of the null distribution, meaning the results should be very similar.
- Figure 6.21 shows the simulated null distribution using 100,000 simulated values with an overlaid curve of the chi-square distribution.
- The precise null distribution for the juror example from Section 6.3 is shown as a histogram of simulated $X^2_{sim}$ statistics, and the theoretical chi-square distribution is also shown.
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- In short, we create a randomized contingency table, then compute a chi-square test statistic.
- We repeat this many times using a computer, and then we examine the distribution of these simulated test statistics.
- When the minimum threshold is met, the simulated null distribution will very closely resemble the chi-square distribution.
- As before, we use the upper tail of the null distribution to calculate the p-value.
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- The chi-square test is used to determine if a distribution of observed frequencies differs from the theoretical expected frequencies.
- The chi-square ($\chi^2$) test is a nonparametric statistical technique used to determine if a distribution of observed frequencies differs from the theoretical expected frequencies.
- Second, we use the chi-square distribution.
- We may observe data that give us a high test-statistic just by chance, but the chi-square distribution shows us how likely it is.
- The approximation to the chi-squared distribution breaks down if expected frequencies are too low.
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- Areas in the chi-square table always refer to the right tail.