A Comparative Study of $$\text {L}_1$$ L 1 and $$\text {L}_2$$ L 2 Norms in Support Vector Data Descriptions

The Support Vector Data Description ( $$\text {L}_1$$ L 1 SVDD) is a non-parametric one-class classification algorithm that utilizes the $$\text {L}_1$$ L 1 norm in its objective function. An alternative formulation of SVDD, called $$\text {L}_2$$ L 2 SVDD, uses a $$\text {L}_2$$ L 2 norm in its objective function and has not been extensively studied. $$\text {L}_1$$ L 1 SVDD and $$\text {L}_2$$ L 2 SVDD are formulated as distinct quadratic programming (QP) problems and can be solved with a QP-solver. The $$\text {L}_2$$ L 2 SVDD and $$\text {L}_1$$ L 1 SVDD’s ability to detect small and large shifts in data generated from multivariate normal, multivariate t, and multivariate Laplace distributions is evaluated. Similar comparisons are made using real-world datasets taken from various applications including oncology, activity recognition, marine biology, and agriculture. In both the simulated and real-world examples, $$\text {L}_2$$ L 2 SVDD and $$\text {L}_1$$ L 1 SVDD perform similarly, though, in some cases, one outperforms the other. We propose an extension of the SMO algorithm for $$\text {L}_2$$ L 2 SVDD, and we compare the runtimes of four algorithms: $$\text {L}_2$$ L 2 SVDD (SMO), $$\text {L}_2$$ L 2 SVDD (QP), $$\text {L}_1$$ L 1 SVDD (SMO), and $$\text {L}_1$$ L 1 SVDD (QP). The runtimes favor $$\text {L}_1$$ L 1 SVDD (QP) versus $$\text {L}_2$$ L 2 SVDD (QP), sometimes substantially; however using SMO reduces the difference in runtimes considerably, making $$\text {L}_2$$ L 2 SVDD (SMO) feasible for practical applications. We also present gradient descent and stochastic gradient descent algorithms for linear versions of both the $$\text {L}_1$$ L 1 SVDD and $$\text {L}_2$$ L 2 SVDD. Examples using simulated and real-world data show that both methods perform similarly. Finally, we apply the $$\text {L}_1$$ L 1 SVDD and $$\text {L}_2$$ L 2 SVDD to a real-world dataset that involves monitoring machine failures in a manufacturing process.