Simple Linear Regression lm function R

I've read some tutorial about the lm() function in R and I am a little bit confuse about how this function deal with continuous or discrete predictors. In https://www.r-bloggers.com/r-tutorial-series-simple-linear-regression/, for continuous labels, the coefficients represent the intercept and the slope of the linear regression.

This is clear, but if now I have a category of gender, where values are 0 or 1, how does the lm() function work. Does the function apply a logistic regression or is it still possible to use the function in this way.

• The formula for adding another variable would be `ROLL ~ UNEM + gender`, although you probably want to make gender a factor since you're treating it as having discrete levels. For logistic regression, you use `glm` with `family = binomial`. – camille Apr 23 '18 at 14:25
• Also, the next entry in the R Tutorial series that you're reading is on multiple linear regression, so that teaches you how to work with multiple predictor variables. – camille Apr 23 '18 at 14:26
• – Terru_theTerror Apr 23 '18 at 14:40
• Adding to camille's comment, logistic regression is used to predict a binary/categorical outcome, so it is not what you want here. – avid_useR Apr 23 '18 at 14:41
• @Babas My understanding is that you want `gender` to be a "predictor" not an "outcome" variable. For the former, you would just add `+ gender` to your `lm` to include it as a predictor. For the latter, you will need `glm` and have `gender` as the "Y" variable as described by alistaire. – avid_useR Apr 23 '18 at 15:42

Your the answer you are looking for is unclear from your question. Yes, you can use the `lm` function with a categorical variables. The resultant equation is the sum of two linear fits.

It is best to illustrate with an example. Using made up data:

``````x<-seq(1:10)
y1<-x+rnorm(10, 0, 0.1)
y2<-(10-x)+4+rnorm(10, 0, 0.1)
f<-rep(c("A", "B"), each=10)
df<-data.frame(x=c(x,x), y=c(y1, y2), f)

#Model 1
summary(lm(y1~x))

#Model 2
model<-lm(y~x*f, data=df)
summary(model)

#Model 3
summary(lm(y2~x))
``````

After running the code above and comparing the Model 1 and 2, you can see how the intercept and the x slope are the same. This is because the when it is factor A (i.e. 0 or absence), fb and x:fb are 0 and drops out. When the factor is B then fb and x:fb are actual values and are additive to the model.

If you add the intercept and fb together and add the x slope to x:fb the result will the slope and intercept of model 3.

I hope this helps and did not cloud your understanding.