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Binary Logistic Regression

Binary Logistic Regression “To be or not to be, that is the question..”(William Shakespeare, “Hamlet”). Binary Logistic Regression. Also known as “logistic” or sometimes “logit” regression Foundation from which more complex models derived

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Binary Logistic Regression

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  1. Binary Logistic Regression“To be or not to be, that is the question..”(William Shakespeare, “Hamlet”)

  2. Binary Logistic Regression • Also known as “logistic” or sometimes “logit” regression • Foundation from which more complex models derived • e.g., multinomial regression and ordinal logistic regression

  3. Dichotomous Variables • Two categories indicating whether an event has occurred or some characteristic is present • Sometimes called “binary” or “binomial” variables

  4. Dichotomous DVs • Placed in foster care or not • Diagnosed with a disease or not • Abused or not • Pregnant or not • Service provided or not

  5. Single (Dichotomous) IV Example • DV = continue fostering, 0 = no, 1 = yes • Customary to code category of interest 1 and the other category 0 • IV = married, 0 = not married, 1 = married • N = 131 foster families • Are two-parent families more likely to continue fostering than one-parent families?

  6. Crosstabulation • Table 2.1 • Relationship between marital status and continuation is statistically significant [2(1, N = 131) = 5.65, p = .017] • A higher percentage of two-parent families (62.20%) than single-parent families (40.82%) planned to continue fostering

  7. Strength & Direction of Relationships • Different ways to quantify the relationship between IV(s) and DV • Probabilities • Odds • Odds Ratio (OR) • Also abbreviated as eB, Exp(B) (on SPSS output), or exp(B) • % change

  8. Roadmap to Computations

  9. Probabilities • Percentages in Table 2.1 as probabilities (e.g., 62.20% as .6220) • p • Probability that event will occur (continue) • e.g., probability that one-parent families plan to continue is .4082 • 1 – p • Probability that event will not occur (notcontinue) • e.g., probability that one-parent families do not plan to continue is .5918 (1 - .4082)

  10. Odds • Ratio of probability that event will occur to probability that it will not • e.g., odds of continuation for one-parent families are .69 (.4082 / .5918) • Can range from 0 to positive infinity

  11. Probabilities and Odds • Table 2.2 • Odds = 1 • Both outcomes equally likely • Odds > 1 • Probability that event will occur greater than probability that it will not • Odds < 1 • Probability that event will occur less than probability that it will not

  12. Odds Ratio (OR) • Odds of the event for one value of the IV (two-parent families) divided by the odds for a different value of the IV, usually a value one unit lower (one-parent families) • e.g., odds of continuing for two-parent families more than double the odds for one-parent families • OR = 1.6455 / .6898 = 2.39

  13. OR (cont’d) • Plays a central role in quantifying the strength and direction of relationships between IVs and DVs in binary, multinomial, and ordinal logistic regression • OR < 1 indicates a negative relationship • OR > 1 indicates a positive relationship • OR = 1 indicates no linear relationship

  14. ORs > 1 • e.g., OR of 2.39 • A one-unit increase in the independent variable increases the odds of continuing by a factor of 2.39 • The odds of continuing are 2.39 times higher for two-parent compared to one-parent families

  15. ORs < 1 • e.g., OR = .50 • A one-unit increase in the independent variable decreases the odds of continuing by a factor of .50 • The odds that two-parent families will continue are .50 (or one-half) of the odds that one-parent families will continue

  16. ORs < 1 (cont’d) • Compute reciprocal (i.e., 1 / .50 = 2.00) • Express relationship as opposite event of interest (e.g., discontinuing) • A one-unit increase in the independent variable increases the odds of discontinuing by a factor of 2.00 • The odds that two-parent families will discontinue are 2.00 times (or twice) the odds of one-parent families

  17. OR to Percentage Change • % change = 100(OR – 1) • Alternative way to express OR • e.g., A one-unit increase in the independent variable increases the odds of continuing by 139.00% • 100(2.39 – 1) = 139.00 • e.g., A one-unit increase in the independent variable decreases the odds of continuing by 50.00% • 100(.50 – 1) = -50.00

  18. Comparing OR > 1 and OR < 1 • Compute reciprocal of one of the ORs • e.g., OR of 2.00 and an OR of .50 • Reciprocal of .50 is 2.00 (1 / .50 = 2.00) • ORs are equal in size (but not in direction of the relationship)

  19. Qualitative Descriptors for OR • Table 2.3 • Use cautiously with IVs that aren’t dichotomous

  20. Question & Answer • Are two-parent families more likely to continue fostering than one-parent families? • Yes. The odds of continuing are 2.39 times (139%) higher for two-parent compared to one-parent families. The probability of continuing is .41 for one-parent families and .62 for two-parent families.

  21. Binary Logistic Regression Example • DV = continue fostering, 0 = no, 1 = yes • Customary to code category of interest 1 and the other category 0 • IV = married, 0 = not married, 1 = married • N = 131 foster families • Are two-parent families more likely to continue fostering than one-parent families?

  22. Statistical Significance • Table 2.4 • Relationship between marital status and continuation is statistically significant (Wald 2 = 5.544, p = .019)

  23. Direction of Relationship • B = slope • Positive slope, positive relationship • OR > 1 • Negative slope, negative relationship • OR < 1 • 0 slope, no linear relationship • OR = 1

  24. Direction/Strength of Relationship • Positive relationship between marital status and continuation • Two-parent families more likely to continue • B = .869 • Exp(B) = OR = 2.385 • % change = 100(2.385 - 1) = 139% • The odds of continuing are 2.39 times (139%) higher for two-parent compared to one-parent families

  25. Roadmap to Computations

  26. Binary Logistic Regression Model • ln(π/ (1 - π)) = α + 1X1 + 1X2 + … kXk, or • ln(π / (1 - π)) =  • π is the probability of the event •  (eta) is the abbreviation for the linear predictor (right hand side of this equation) • k = number of independent variables

  27. Logit Link • ln(π / (1 - π)) • Log of the odds that the DV equals 1 (event occurs) • Connects (i.e., links) DV to linear combination of IVs

  28. Estimated Logits (L) ln(p / 1 - p) = a + B1X1 + B1X2 + … BkXk • ln(p / 1 – p) • Log of the odds that the DV equals 1 (event occurs) • Estimated logit, L • Does not have intuitive or substantive meaning • Useful for examining curvilinear relationships and interaction effects • Primarily useful for estimating probabilities, odds, and ORs

  29. Estimated Logits (L) L(Continue) = a + BMarriedXMarried L(Continue) = -.372 + (.869)(XMarried) • a = intercept • B = slope

  30. Logit to Odds • If L = 0: • Odds = eL = e0 = 1.00 • If L = .50: • Odds = eL = e.50 = 1.65 • If L = 1.00: • Odds = eL = e1.00 = 2.72

  31. Logits to Odds (cont’d) • Table 2.4 • One-parent families • L(Continue) = -.372 = -.372 + (.869)(0) • Odds of continuing = e-.372 = .69 • Two-parent families • L(Continue) = .497 = -.372 + (.869)(1) • Odds of continuing = e.497 = 1.65

  32. Odds to OR • OR = 1.65 / .69 = 2.39, or • e.869 = 2.39, labeled Exp(B) • Table 2.4

  33. OR to Percentage Change • % change = 100(OR – 1) • e.g., A one-unit increase in the independent variable increases the odds of continuing by 139.00% • 100(2.39 – 1) = 139.00 • e.g., A one-unit increase in the independent variable decreases the odds of continuing by 50.00% • 100(.50 – 1) = -50.00

  34. Logits to Probabilities • One-parent families, L(Continue) = -.372 • Two-parent families, L(Continue) = .497

  35. Question & Answer • Are two-parent families more likely to continue fostering than one-parent families? • Yes. The odds of continuing are 2.39 times (139%) higher for two-parent compared to one-parent families. The probability of continuing is .41 for one-parent families and .62 for two-parent families.

  36. Single (Quantitative) IV Example • DV = continue fostering, 0 = no, 1 = yes • Customary to code category of interest 1 and other category 0 • IV = number of resources • N = 131 foster families • Are foster families with more resources more likely to continue fostering?

  37. Statistical Significance • Table 2.5 • Relationship between resources and continuation is statistically significant (Wald 2 = 4.924, p = .026) • H0:  = 0,  0,  ≤ 0, same as • H0: OR = 1, OR 1, OR ≤ 1 • Likelihood ratio 2 better than Wald

  38. Direction/Strength of Relationship • Positive relationship between resources and continuation • Families with more resources are more likely to continue • B = .212 • Exp(B) = OR = 1.237 • % change = 100(1.237 – 1) = 24% • The odds of continuing are 1.24 times (24%) higher for each additional resource

  39. Estimated Logits L(Continue) = -1.227 + (.212)(X)

  40. Figures • Resources.xls

  41. Effect of Resources on Continuation (Logits)

  42. Effect of Resources on Continuation (Odds)

  43. Effect of Resources on Continuation (Probabilities)

  44. Question & Answer • Are foster families with more resources more likely to continue fostering? • Yes. The odds of continuing are 1.24 times (24%) higher for each additional resource. The probability of continuing is .31 for families with two resources, .51 for families with 6 resources, and .71 for families with 10 resources.

  45. Relationship of Linear Predictor to Logits, Odds & p • Relationship between linear predictor and logits is linear • Relationship between linear predictor and odds is non-linear • Relationship between linear predictor and p is non-linear • Challenge is to summarize changes in odds and probabilities associated with changes in IVs in the most meaningful and parsimonious way

  46. Logit as Function of Linear Predictor

  47. Odds as Function of Linear Predictor

  48. Probabilities as Function of Linear Predictor

  49. IVs to z-scores • z-scores (standard scores) • Only the IV (not DV)--semi-standardized slopes • One-unit increase in the IV refers to a one-standard-deviation increase • OR interpreted as expected change in the odds associated with a one standard deviation increase in the IV • Conversion to z-scores changes intercept, slope, and OR, but not associated test statistics • Table 2.6 (compare to Table 2.5)

  50. Figures • zResources.xls

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