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 http://rss.acs.unt.edu/Rdoc/library/flexmix/html/flexmix.html

```
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 http://www.inside-r.org/packages/cran/flexmix/docs/flexmix, 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))
ex1
summary(ex1)
plot(ex1)
## 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,
model=list(FLXMRglm(yn~.+I(x^2)),
FLXMRglm(yp~., family="poisson")))
plot(ex2)
```

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.

generalized linear modelincludes 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