There are N different classes that can be observed in my problem and my task is to detect which ones occurred at time t (of T frames). I created `actualLabels`

and `predictedLabels`

binary matrices of size NxT. I observed the data and filled `actualLabels`

by hand. `actualLabels(n,t)`

is 1 if the instance at time t involves nth class, otherwise it is 0. This serves as my ground truth data. Then, I run my algorithm on the data and predict the observed classes. The labels are found automatically and stored in `predictedLabels`

.

My question is that how can I compute a success value using these matrices? Is there a popular way to do this?

**Example case:** Let there be 4 classes and T=5. Let the data be

```
actualLabels = 0 0 0 0 1
1 1 0 1 0
0 1 0 0 1
0 0 0 0 1
predictedLabels = 0 0 0 0 1
0 0 1 1 0
0 1 0 0 0
0 1 0 0 0
```

It seems to be not possible to compute a conventional confusion matrix from multi-class assignment. Instead I computed a distance in each pair. Since I have binary vectors to compare, Hamming distance seems to be nice (similar to edit distance). The problem now is that I can report the distances between predicted and actual label vectors, but not the success percentage.

A confusion matrix conveys lots of information. I would like to see a similar table that helps me to see where the mistakes occur a lot, the overall success, etc.

**Details:** I have some wav data and I want to do polyphonic pitch tracking. At each time bin, there can be any number of notes played together which forms the labels I want to predict.

**Note:** There are some metrics for multi-label classification in Wikipedia. I would be happy to learn any other metric or plot.