In this section you will learn the basic concepts behind multi-label classification.
Classification aims to assign classes/labels to objects. Objects usually represent things we come across in daily life: photos, audio recordings, text documents, videos, but can also include complicated biological systems.
Objects are usually represented by their selected features (its count denoted as n_features
in the documentation). Features are the characteristics of objects that distinguish them from others. For example text documents can be represented by words that are present in them.
The output of classification for a given object is either a class or a set of classes. Traditional classification, usually due to computational limits, aimed at solving only single-label scenarios in which at most one class had been assigned to an object.
One can identify two types of single-label classification problems:
0
or 1
In multi-label classification one can assign more than one label/class out of the available n_labels
to a given object.
Madjarov et al. divide approaches to multi-label classification into three categories, you should select a scikit-multilearn base class according to the philosophy behind your classifier:
scikit-multilearn
in the future they will be placed in skmultilearn.adapt
skmultilearn.problem_transformation
RAkEL
or label space partitioning classifiers, are now available from skmultilearn.ensemble
A single-label classifier is a function that given an object represented as a feature vector of length n_features
assigns a class (a number, or None). A multi-label classifier outputs a set of assigned labels, either in a form of a list of assigned labels or as a binary vector in which a 1
or 0
on i
-th position indicates if an i
-th label is assigned or not.
To learn a classifier we use a training set that provides n_samples
of sampled objects represented by n_features
with evidence concerning which labels out of n_labels
are assigned to each of the object. The quality of the classifier is tested on a test set that follows the same format.
To train a classification model we need data about a phenomenon that the classifier is supposed to generalise. Such data usually comes in two parts:
X
and which consists of n_samples
that are represented using n_features
n_samples
objects - an output space - which we will denote as y
. y
provides information about which, out of n_labels
that are available, are actually assigned to each of n_samples
objectsscikit-multilearn expects on input:
X
to be a matrix of shape (n_samples, n_features)
y
to be a matrix of shape (n_samples, n_labels)
Let's load up a data set to see this in practice:
In [5]:
from skmultilearn.dataset import load_dataset
X, y, _, _ = load_dataset('emotions', 'train')
In [7]:
X, y
Out[7]:
We can see that in the case of emotions data the values are:
By matrix scikit-multilearn understands following the A[i,j]
element accessing scheme. Sparse matrices should be used instead of dense ones, especially for the output space. Scikit-multilearn will internally convert dense representations to sparse representations that are most suitable to a given classification procedure. Scikit-multilearn will output
X
can store any type of data a given classification method can handle is allowed, but nominal encoding is always helpful. Nominal encoding is enabled by default when loading data with :meth:skmultilearn.dataset.Dataset.load_arff_to_numpy
helper, which also returns sparse representations of X
and y
loaded from ARFF data file.
y
is expected to be a binary integer
indicator matrix of shape. In the binary indicator matrix each matrix element A[i,j]
should be either 1
if label j
is assigned to an object no i
, and 0
if not.
We highly recommend for every multi-label output space to be stored in sparse matrices and expect scikit-multilearn classifiers to operate only on sparse binary label indicator matrices internally. This is also the format of predicted label assignments. Sparse representation is employed as default because it is very rare for a real-world output space y
to be dense. Usually, the number of labels assigned per instance is just a small portion of all labels. The average percentage of labels assigned per object is called label density
and in established data sets it tends to be small <http://mulan.sourceforge.net/datasets-mlc.html>
_.
The problem transformation approach to multi-label classification converts multi-label problems to single-label problems: single-class or multi-class. Then those problems are solved using base classifiers. Scikit-multilearn maintains compatibility with scikit-learn data format for single-label classifiers ,which expect:
X
to have an (n_samples, n_features)
shape and be one of the following:
array-like
of array-likes
, which usually means a nested array, where i
-th row and j
-th column are adressed as X[i][j]
, in many cases the classifiers expect array-like
to be an np.array
np.matrix
y
to be a one-dimensional array-like
of shape (n_samples,)
with one class value per sample, which is a natural representation of a single-label problem
The data set is stored in sparse matrices for efficiency. However not all scikit-learn classifiers support matrix input and sparse representations. For this reason, every scikit-multilearn classifier that follows a problem transformation approach admits a require_dense
parameter in the constructor. As these scikit-multilearn classifiers transform the multi-label problem to a set of single-label problems and solve them using scikit-learn base classifiers - the require_dense
parameter allows control over which format of the transformed input and output space passed to the base classifier.
The parameter require_dense
expects a two-element list: [bool or None, bool or None]
which control the input and output space formats respectively. If None - the base classifier will receive a dense representation if it does not inherit :class:skmultilearn.base.MLClassifierBase
, otherwise the representation forwarded will be sparse. The dense representation for X
is a numpy.matrix
, while for y
it is a numpy.array of int
(scikit-learn's required format of the output space).
Scikit-learn's expected format is described in the scikit-learn docs and assumes that:
X
is provided either as a numpy.matrix
, a sparse.matrix
or as array likes of arrays likes
(vectors) of features, i.e. the array of row vectors that consist of input features (same length, i.e. feature/attribute count), ex. a two-object set with each row being a small 1px x 1px image with RGB channels (three int8
values describing red, blue, green colors per pixel): [[128,10,10,20,30,128], [10,155,30,10,155,10]]
- scikit-multilearn will expect a matrix representation and will forward a matrix representation to the base classifiery
is expected to be provided as an array of array likesSome scikit-learn classifiers support the sparse representation of X
especially for textual data, to have it forwarded as such to the scikit-learn classifier one needs to pass require_dense = [False, None]
to the scikit-multilearn classifier's constructor. If you are sure that the base classifier you use will be able to handle a sparse matrix representation of y
- pass require_dense = [None, False]
. Pass require_dense = [False, False]
if both X
and y
are supported in sparse representation.
In [ ]: