Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have a data set with response variable ADA, and independent variables LEV, ROA, and ROAL. The data is called dt. I used the following code to get coefficients for latent classes.

m1 <- stepFlexmix(ADA ~ LEV+ROA+ROAL,data=dt,control= list(verbose=0), 
k=1:5,nrep= 10);  

m1 <- getModel(m1, "BIC");

All was fine until I read the following from

model Object of FLXM of list of FLXM objects. Default is the object returned by calling FLXMRglm().

Which I think says that default model call is generalized linear model, while I am interested in linear model. How can I use linear model rather than GLM? I searched for it for quite a while, bit could't get it except this example from, which I couldn't make sense of:

data("NPreg", package = "flexmix")

## mixture of two linear regression models. Note that control parameters
## can be specified as named list and abbreviated if unique.
ex1 <- flexmix(yn~x+I(x^2), data=NPreg, k=2,
                   control=list(verb=5, iter=100))


## now we fit a model with one Gaussian response and one Poisson
## response. Note that the formulas inside the call to FLXMRglm are
## relative to the overall model formula.
ex2 <- flexmix(yn~x, data=NPreg, k=2,
                          FLXMRglm(yp~., family="poisson")))

Someone please let me know how to use linear regression instead of GLM. Or am I already using LM and just got confused because of the "default model line"? Please explain. Thanks.

share|improve this question
The generalized linear model includes OLS regression as a special case. Ie, when you run lm(y~x), you are running a GLiM, even though we don't typically think of it that way. It appears from the example that using the identity link and a Normal distribution for the response is the default, although the rest of the documentation doesn't make that overwhelmingly clear to me. In other words, if you just leave off the family="poisson" part, I think you'll be OK. – gung Nov 11 '13 at 21:42
Thanks. I also did a numerical analysis. I believe that my results might help someone in the future. Hence, posted the results here. – Sumit Nov 12 '13 at 9:59
Congrats, that's a great way to figure things out; I do it a lot myself. Why not post that as your own answer, rather than an edit? Then you can accept it & this thread won't look unfinished. If you want a fuller sense of GLiM & the relationships between things like logistic regression & linear regression, I have an answer on Cross Validated (stats.SE) that might be helpful--although written in a different context: difference-between-logit-and-probit-models. – gung Nov 12 '13 at 14:31
Hey thanks for the suggestion. Posted my answer. I looked at your post and it is very nice. Thanks for such a great post. – Sumit Nov 13 '13 at 14:43
up vote 1 down vote accepted

I did a numerical analysis to understand if

m1 <- stepFlexmix(ADA ~ LEV+ROA+ROAL,data=dt,control= list(verbose=0)

does produce results from linear regression. To do the experiment, I ran the following code and found that yes the estimated parameters are indeed from linear regression. Experiment helped me to allay my reservations.

  x1 <- c(1:200);
  x2 <- x1*x1;
  x3 <- x1*x2;
  e1 <- rnorm(200,0,1);
  e2 <- rnorm(200,0,1);
  y1 <- 5+12*x1+20*x2+30*x3+e1;
  y2 <- 18+5*x1+10*x2+15*x3+e2;
  y <- c(y1,y2)
  x11 <- c(x1,x1)
  x22 <- c(x2,x2)
  x33 <- c(x3,x3)
  d <- data.frame(y,x11,x22,x33)

  m <- stepFlexmix(y ~ x11+x22+x33, data =d, control = list(verbose=0), k=1:5, nrep = 10);
  m <- getModel(m, "BIC");
  plotEll(m, data = d)
  m.refit <- refit(m);
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.