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\[ R-squared (Likelihood ratio) = 1 - \frac{ln(L[m])}{ln(L[0] } \] |
$$ \mbox{R-squared (Likelihood ratio)} = 1 - \frac{ln(L[m])}{ln(L[0] } $$ |
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Ths statistical significance of the predictors may be jointly assessed using twice the change in log-likelihoods equal to 2 (L(m) - L(0)) which is approximately chi-square(p) if the predictors jointly have no influence on group membership. This term is routinely computed for binary logistic regressions and in SPSS is the chi-square statistic produced immediately after the predictors are added to the model under 'Block 1 Method=Enter'. For example running a logistic regression to assess the joint importance of two predictors p1 and p2 | Ths statistical significance of the predictors may be ''jointly'' assessed using twice the change in log-likelihoods which equals 2 (L(m) - L(0)) which is approximately chi-square(p) if the predictors ''jointly'' have no influence on group membership. This term is routinely computed for binary logistic regressions. In SPSS this term is denoted by the chi-square statistic produced immediately after the predictors are added to the model under the heading 'Block 1 Method=Enter'. For example running a logistic regression in SPSS to assess the joint importance of two predictors p1 and p2 with the syntax below |
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we obtain in the output | we obtain the likelihood ratio chi-square in the output which is of form: |
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which is a chi-square(2) = 3.96, p=0.14 indicating that together the two predictors, p1 and p2, do not have a statistically significant association with group, y. | This may be expressed as chi-square(2) = 3.96, p = 0.14 indicating that together the two predictors, p1 and p2, do not have a statistically significant association with group, y. |
How do I summarise a fit for a logistic regression model?
Menard (2000) compares various R-squared measures for binary logistic regressions and concludes that the log-likelihood ratio chi-square is the most appropriate.
$$ \mbox{R-squared (Likelihood ratio)} = 1 - \frac{ln(L[m])}{ln(L[0] } $$
where L(m) and L(0) are the log likelihoods for the model with predictors and intercept only models respectively.
Ths statistical significance of the predictors may be jointly assessed using twice the change in log-likelihoods which equals 2 (L(m) - L(0)) which is approximately chi-square(p) if the predictors jointly have no influence on group membership. This term is routinely computed for binary logistic regressions. In SPSS this term is denoted by the chi-square statistic produced immediately after the predictors are added to the model under the heading 'Block 1 Method=Enter'. For example running a logistic regression in SPSS to assess the joint importance of two predictors p1 and p2 with the syntax below
LOGISTIC REGRESSION y /METHOD = ENTER p1 p2 /CRITERIA = PIN(.05) POUT(.10) ITERATE(20) CUT(.5) .
we obtain the likelihood ratio chi-square in the output which is of form:
BLOCK 1: METHOD-ENTER Omnibus Tests of Model Coefficients Chi-square df Sig. Step 1 Step 3.958 2 .138 Block 3.958 2 .138 Model 3.958 2 .138
This may be expressed as chi-square(2) = 3.96, p = 0.14 indicating that together the two predictors, p1 and p2, do not have a statistically significant association with group, y.
Reference
Menard, S. (2000) Coefficients of determination for multiple logistic regression analysis. American Statistician, 54, 17-24.