SVM-based multiple instance classification via DC optimization
Algorithms, 2019•mdpi.com
A multiple instance learning problem consists of categorizing objects, each represented as a
set (bag) of points. Unlike the supervised classification paradigm, where each point of the
training set is labeled, the labels are only associated with bags, while the labels of the points
inside the bags are unknown. We focus on the binary classification case, where the
objective is to discriminate between positive and negative bags using a separating surface.
Adopting a support vector machine setting at the training level, the problem of minimizing the …
set (bag) of points. Unlike the supervised classification paradigm, where each point of the
training set is labeled, the labels are only associated with bags, while the labels of the points
inside the bags are unknown. We focus on the binary classification case, where the
objective is to discriminate between positive and negative bags using a separating surface.
Adopting a support vector machine setting at the training level, the problem of minimizing the …
A multiple instance learning problem consists of categorizing objects, each represented as a set (bag) of points. Unlike the supervised classification paradigm, where each point of the training set is labeled, the labels are only associated with bags, while the labels of the points inside the bags are unknown. We focus on the binary classification case, where the objective is to discriminate between positive and negative bags using a separating surface. Adopting a support vector machine setting at the training level, the problem of minimizing the classification-error function can be formulated as a nonconvex nonsmooth unconstrained program. We propose a difference-of-convex (DC) decomposition of the nonconvex function, which we face using an appropriate nonsmooth DC algorithm. Some of the numerical results on benchmark data sets are reported.
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