1 / 28

Wednesday, Dec. 2 Chi-square Goodness of Fit Chi-square Test of Independence: Two Variables.

Wednesday, Dec. 2 Chi-square Goodness of Fit Chi-square Test of Independence: Two Variables. Summing up!. gg. yy. yg. yg. yg. yg. yy. yg. gg. gy. 25%. 25% 25% 25%. Pea Color freq Observed freq Expected

obert
Download Presentation

Wednesday, Dec. 2 Chi-square Goodness of Fit Chi-square Test of Independence: Two Variables.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Wednesday, Dec. 2 Chi-square Goodness of Fit Chi-square Test of Independence: Two Variables. Summing up!

  2. gg yy yg yg yg yg yy yg gg gy 25% 25% 25% 25%

  3. Pea Color freq Observed freq Expected Yellow 158 150 Green 42 50 TOTAL 200 200

  4. k 2 (fo - fe)2  = fe i=1 Chi Square Goodness of Fit Pea Color freq Observed freq Expected Yellow 158 150 Green 42 50 TOTAL 200 200 d.f. = k - 1, where k = number of categories of in the variable.

  5. “… the general level of agreement between Mendel’s expectations and his reported results shows that it is closer than would be expected in the best of several thousand repetitions. The data have evidently been sophisticated systematically, and after examining various possibilities, I have no doubt that Mendel was deceived by a gardening assistant, who knew only too well what his principal expected from each trial made…” -- R. A. Fisher

  6. k 2 (fo - fe)2  = fe i=1 Chi Square Goodness of Fit Mendel's Cooking! Pea Color freq Observed freq Expected Yellow 151 150 Green 49 50 TOTAL 200 200 d.f. = k - 1, where k = number of categories of in the variable.

  7. Peas to Kids: Another Example Goodness of Fit At my children’s school science fair last year, where participation was voluntary but strongly encouraged, I counted about 60 boys and 40 girls who had submitted entries. Since I expect a ratio of 50:50 if there were no gender preference for submission, is this observation deviant, beyond chance level?

  8. Boys Girls Expected: 50 50 Observed: 60 40

  9. k 2 (fo - fe)2  = fe i=1 Boys Girls Expected: 50 50 Observed: 60 40

  10. Boys Girls Expected: 50 50 Observed: 60 40 k 2 (fo - fe)2  = fe i=1 For each of k categories, square the difference between the observed and the expected frequency, divide by the expected frequency, and sum over all k categories.

  11. Boys Girls Expected: 50 50 Observed: 60 40 k 2 (fo - fe)2 (60-50)2 (40-50)2  = = 4.00 + = 50 50 fe i=1 For each of k categories, square the difference between the observed and the expected frequency, divide by the expected frequency, and sum over all k categories.

  12. Boys Girls Expected: 50 50 Observed: 60 40 k 2 (fo - fe)2 (60-50)2 (40-50)2  = = 4.00 + = 50 50 fe i=1 For each of k categories, square the difference between the observed and the expected frequency, divide by the expected frequency, and sum over all k categories. This value, chi-square, will be distributed with known probability values, where the degrees of freedom is a function of the number of categories (not n). In this one-variable case, d.f. = k - 1.

  13. Boys Girls Expected: 50 50 Observed: 60 40 k 2 (fo - fe)2 (60-50)2 (40-50)2  = = 4.00 + = 50 50 fe i=1 For each of k categories, square the difference between the observed and the expected frequency, divide by the expected frequency, and sum over all k categories. This value, chi-square, will be distributed with known probability values, where the degrees of freedom is a function of the number of categories (not n). In this one-variable case, d.f. = k - 1. Critical value of chi-square at =.05, d.f.=1 is 3.84, so reject H0.

  14. Chi-square Test of Independence Are two nominal level variables related or independent from each other? Is race related to SES, or are they independent?

  15. White Black 12 15 Hi 3 SES 32 Lo 16 16 47 28 19

  16. The expected frequency of any given cell is Row n x Column n Total n White Black 12 15 Hi 3 SES 32 Lo 16 16 47 28 19

  17. r c 2 (fo - fe)2   = fe r=1 c=1 At d.f. = (r - 1)(c - 1)

  18. Row n x Column n Total n The expected frequency of any given cell is (15x28)/47 (15x19)/47 15 (32x28)/47 (32x19)/47 32 47 28 19

  19. Row n x Column n Total n The expected frequency of any given cell is (15x28)/47 (15x19)/47 15 8.94 6.06 (32x28)/47 (32x19)/47 32 19.06 12.94 47 28 19

  20. r c 2 (fo - fe)2   = fe c=1 r=1 Please calculate: 12 3 15 8.94 6.06 16 16 32 19.06 12.94 47 28 19

  21. Important assumptions: Independent observations. Observations are mutually exclusive. Expected frequencies should be reasonably large: d.f. 1, at least 5 d.f. 2, >2 d.f. >3, if all expected frequencies but one are greater than or equal to 5 and if the one that is not is at least equal to 1.

  22. Univariate Statistics: Interval Mean one-sample t-test Ordinal Median Nominal Mode Chi-squared goodness of fit

  23. Bivariate Statistics Y Nominal Ordinal Interval Nominal2 Rank-sum t-test Kruskal-Wallis H ANOVA Ordinal Spearman rs (rho) Interval Pearson r Regression X

More Related