TY - GEN
T1 - A Precise Performance Analysis of Support Vector Regression
AU - Sifaou, Houssem
AU - Kammoun, Abla
AU - Alouini, Mohamed-Slim
N1 - KAUST Repository Item: Exported on 2022-04-29
PY - 2021
Y1 - 2021
N2 - In this paper, we study the hard and soft support vector regression techniques applied to a set of n linear measurements of the form y(i) = beta(T)(*)x(i) + n(i) where beta(*) is an unknown vector, {x(i)}(i=1)(n) are the feature vectors and {n(i)}(i=1)(n) model the noise. Particularly, under some plausible assumptions on the statistical distribution of the data, we characterize the feasibility condition for the hard support vector regression in the regime of high dimensions and, when feasible, derive an asymptotic approximation for its risk. Similarly, we study the test risk for the soft support vector regression as a function of its parameters. Our results are then used to optimally tune the parameters intervening in the design of hard and soft support vector regression algorithms. Based on our analysis, we illustrate that adding more samples may be harmful to the test performance of support vector regression, while it is always beneficial when the parameters are optimally selected. Such a result reminds a similar phenomenon observed in modern learning architectures according to which optimally tuned architectures present a decreasing test performance curve with respect to the number of samples.
AB - In this paper, we study the hard and soft support vector regression techniques applied to a set of n linear measurements of the form y(i) = beta(T)(*)x(i) + n(i) where beta(*) is an unknown vector, {x(i)}(i=1)(n) are the feature vectors and {n(i)}(i=1)(n) model the noise. Particularly, under some plausible assumptions on the statistical distribution of the data, we characterize the feasibility condition for the hard support vector regression in the regime of high dimensions and, when feasible, derive an asymptotic approximation for its risk. Similarly, we study the test risk for the soft support vector regression as a function of its parameters. Our results are then used to optimally tune the parameters intervening in the design of hard and soft support vector regression algorithms. Based on our analysis, we illustrate that adding more samples may be harmful to the test performance of support vector regression, while it is always beneficial when the parameters are optimally selected. Such a result reminds a similar phenomenon observed in modern learning architectures according to which optimally tuned architectures present a decreasing test performance curve with respect to the number of samples.
UR - http://hdl.handle.net/10754/676622
M3 - Conference contribution
BT - 38th International Conference on Machine Learning (ICML)
ER -