I am working with small sample size data:

```
>dput(dat.demand2050.unique)
c(79, 56, 69, 61, 53, 73, 72, 86, 75, 68, 74.2, 80, 65.6, 60, 54)
```

for which the density distribution looks like this:

I know that the values are from two regimes - low and high - and assuming that the underlying process is normal, I used the `mixtools`

package to fit a bimodal distribution:

```
set.seed(99)
dat.demand2050.mixmdl <- normalmixEM(dat.demand2050.unique, lambda=c(0.3,0.7), mu=c(60,70), k=2)
```

which gives me the following result:

(the solid lines are fitted curves and the dashed line is the original density).

```
# get the parameters of the mixture
dat.demand2050.mixmdl.prop <- dat.demand2050.mixmdl$lambda #mix proportions
dat.demand2050.mixmdl.means <- dat.demand2050.mixmdl$mu #modal means
dat.demand2050.mixmdl.dev <- dat.demand2050.mixmdl$sigma #modal std dev
```

The mixture parameters are:

```
>dat.demand2050.mixmdl.prop #mix proportions
[1] 0.2783939 0.7216061
>dat.demand2050.mixmdl.means #modal means
[1] 56.21150 73.08389
>dat.demand2050.mixmdl.dev #modal std dev
[1] 3.098292 6.413906
```

I have the following questions:

- To generate a new set of values that approximates the underlying distribution, is my approach correct or is there a better workflow?
- If my approach is correct, how can I use this result to generate a set of random values from this mixed distribution?

`sample()`

, but will have to go back to my notes why i did not take that approach..perhaps this part of the discussion should go on CrossValidated.. – avg Jul 29 '13 at 14:33