I assume that you have binary observations in the set {0,1}.

You can convert the predicted values in phat variable to [0, 1] range using logit function:

```
phat_new = exp(phat)/(1+exp(phat))
```

Now, you know what the predicted value, phat_new, the true value of observations, val_y_matrix, and the percentage of 1s in your validation data-set, p, are. One way for plotting the ROC is the following:

fix t. This is the cut-off threshold (in [0,1]) for the model. Compute the following:

```
# percentage of 1 observations in the validation set,
p = length(which(val_y_matrix==1))/length(val_y_matrix)
# probability of the model predicting 1 while the true value of the observation is 0,
p_01 = sum(1*(phat_new>=t & val_y_matrix==0))/dim(val_x_matrix)[1]
# probability of the model predicting 1 when the true value of the observation is 1,
p_11 = sum(1*(phat_new>=t & val_y_matrix==1))/dim(val_x_matrix)[1]
# probability of false-positive,
p_fp = p_01/(1-p)
# probability of true-positive,
p_tp = p_11/p
# plot the ROC,
plot(p_fp, p_tp)
```

I wonder if there is a better way for doing this though. If you are using classification trees, for example, you can give the loss matrix as an input to the model and the model that you will get will be different depending on the cost ratio of your loss matrix. This means that by changing the cost ratio, you will get different models and the different models will be different points on the ROC curve.

`ROCR`

package work? If not, what's the specific issue? – smci Mar 8 '14 at 19:41