# How to compute the success ratio in a classification task with multi-label assignments

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.

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To measure success, you need to define it. Choose an error tolerance you are willing to accept (perhaps zero), and count how many predictions (have Hamming distances that) fall below it to get your percentage.

If your training matrices are sparse (mostly zeros), this may be a misleading measure since a model that always predicts the zero matrix will do well. Here you may want to look at precision and recall. These form a natural tradeoff and so it's usually not possible to maximize both simultaneously. To combine them into a single metric, consider the f-score. Again, if your training data is not sparse, then the simple accuracy percentage is probably best.

Finally, if you are measuring accuracy in order to select from amongst several possible models (called validation), then beware of reusing your training data for this step. Instead, partition your data into training data, and cross-validation data. The trouble is your models are already biased towards the data they were trained on; just because they do well on that doesn't mean they will generalize to what they might see in a real application. See the cross-validation wiki entry for more details.

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+1 Precision and recall is a good way to go in my case. I already plan to do cross-validation to find the good parameters on the validation data before test. –  petrichor Jan 13 '12 at 8:27

One solution is, you can convert 4 non-mutually-exclusive binary classes into 16 mutually exclusive classes and construct the confusion matrix. If you have enough number of frames and small enough number of binary classes, this is the most appropriate solution.

Another simpler approach is to calculate recall and precision for each of the classes separately.

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Unfortunately, I have got 88 classes. It looks unfeasible to compute 2^88 mutually exclusive classes. But precision and recall calculations will help. –  petrichor Jan 13 '12 at 11:25