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I'm using fixed effects logistic regression in R, using the glm function. I've done some reading about interpreting interaction terms in generalized linear models. When using the log odds, the model is linear and the interaction term(s) can be interpreted in the same way as OLS regression. When the coefficients are exponentiated into odds ratios, this is no longer the case. Since my audience are more familiar with odds ratios, i'd like to report my results using that metric.

Is there a pre-cooked way of calculating interaction terms as odds ratios using R? If, not, can anyone walk me through how this should be done?

Edit 1: I'm providing a reproducible example below.


dat <- data.frame(
    Y = factor(round(runif(60))),
    x1 = rnorm(60, 10, 3),
    sex = sample(c("male", "female"), size = 60, prob = c(.4, .6), replace = TRUE),
    population = sample(c("France", "Kenya", "Thailand"), size = 60, prob = c(.3, .45, .25), replace = TRUE)

fm1 <- glm(Y ~ x1 + sex * population, family = binomial(link = "logit"), data = dat)

# odds ratios

Edit 2: additional clarification.

The motivation behind my question comes from the following explanation of logistic regression interactions from the UCLA statistics site:

My understanding, from reading this, is that the interpretation of interaction terms that have been transformed into either odds ratios or probabilities is not the same as for the same terms in log odds units. I guess I'm trying to understand if I just need to change my interpretation of the interaction term when converting to odds ratios, or whether I need to do some calculation in addition to the exponentiation?

share|improve this question
Please consider including a small reproducible example so we can better understand and more easily answer your question. – Ben Bolker Jun 23 '14 at 1:42
You're asking how to exponentiate the coefficients? – rawr Jun 23 '14 at 2:05
@rawr No, my understanding is that exponentiated coefficients for interaction terms cannot be interpreted in the same way as interaction terms in OLS (whereas those in the log odds can). I'm trying to calculate interaction terms in odds ratios the correct way. – Chris Jun 23 '14 at 2:14
p/q = product of exp(beta_i), where the betas are the coefficients of the linear predictor eta (this does not depend on whether the betas come from an interaction term or not). – James King Jun 23 '14 at 2:22
@user3114046, so are you saying that this isn't an issue? The exponentiated interaction term in the above model would provide the effect of the difference-in-difference in the odds between sex and population? – Chris Jun 23 '14 at 2:29
up vote 1 down vote accepted

If you are talking about the interpretation of the glm() output and remain on the log-odds scale than it is exactly analogous to how you would interpret the output from lm(). In both cases it is better to talk about predictions rather than trying to separately interpret the coefficients. When you ask for a "pre-cooked way of calculating interaction terms as odds ratios using R", it is not clear what you are really requesting. Do you know of such a "pre-cooked way of calculating interaction terms" for lm() model output?

The UCLA tutorial is saying that you should ask for a method of looking at probabilities and in R regressions functions the answer is "predict":


This is the set of sum of the linear predictors, i.e the sum of the Intercept and the coefficients for persons with the unique combinations of categorical features at the sample mean for x1 in this dataset:

> data.frame( expand.grid(sex=unique(dat$sex), population=unique(dat$population)), x1=mean(dat$x1))
     sex population       x1
1 female      Kenya 9.380473
2   male      Kenya 9.380473
3 female     France 9.380473
4   male     France 9.380473
5 female   Thailand 9.380473
6   male   Thailand 9.380473
> predict( fm1, newdata=data.frame( expand.grid(sex=unique(dat$sex), population=unique(dat$population)), x1=mean(dat$x1)))
         1          2          3          4          5          6 
-0.1548962  0.4757249 -0.5963092 -0.3471242  0.8477717  0.2029501 

Those could be exponentiated if odds ratios are desired, but you should then know what is in the denominator for the odds ratios. And these are the probabilities (obtained with type='response'):

> predict( fm1, newdata=data.frame( expand.grid(sex=unique(dat$sex), population=unique(dat$population)), x1=mean(dat$x1)), type="response")
        1         2         3         4         5         6 
0.4613532 0.6167379 0.3551885 0.4140800 0.7000995 0.5505641 
share|improve this answer
Thanks, that definitely helps. I guess i'm still confused as to how I would know what the denominator is for the odds ratios in your above example (if the first set of predicted values were exponentiated)? If I use exp(coef(fm1)), the 1.46 coefficient for sexmale:populationKenya tells me (I think) that there is 46% difference in the difference of the odds between males-females in France and Kenya. I don't get the same value from the odds-ratio predictions (1.61 - 0.86) - (0.71 - 0.55) = 0.59 – Chris Jun 24 '14 at 1:30
Right. The baseline (for coefficients) is the mean value of x1 within the composite factor reference category or categories, in this case female:France due to teh lexical default ordering of factor levels. – 42- Jun 24 '14 at 1:37
It makes sense to me that female:France would be the default baseline. I'm still not clear how that baseline [exp(-0.596) = 0.551] relates to the other odds-ratios? Do I have to perform some sort of conversion? – Chris Jun 24 '14 at 2:11
You should eitehr post an edit that contains sufficient specifics that we can know what you are talking about. The "baseline" I am talking about would be the (Intercept) and it is the log(odds) of a "TRUE" value among the female Kenyans when the x1 value is 0. (Possibly this is not a useful number, depending on what the range of 'x1' really refers to.) I'm kind of tired of this private tutoring session on what should have been discussed in your classes and annoyed that the effort has not been regarded as useful. Perhaps you should talk to one of your instructors? – 42- Jun 24 '14 at 3:15
There's no need to get upset. I'm not in college, so don't have instructors to turn to. Your efforts are regarded as useful, and I thank you for them again here. If you don't want to answer questions, perhaps you should think about closing your account? – Chris Jun 24 '14 at 3:37

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