Extended support vector interval regression networks for interval input-output data
Information Sciences: an International Journal
Support vector machines for interval discriminant analysis
Neurocomputing
A hybrid wavelet analysis and support vector machines in forecasting development of manufacturing
Expert Systems with Applications: An International Journal
Asymmetrical interval regression using extended ε -SVM with robust algorithm
Fuzzy Sets and Systems
Interval Regression Analysis with Soft-Margin Reduced Support Vector Machine
IEA/AIE '09 Proceedings of the 22nd International Conference on Industrial, Engineering and Other Applications of Applied Intelligent Systems: Next-Generation Applied Intelligence
IEEE Transactions on Fuzzy Systems
Fuzzy regression models using the least-squares method based on the concept of distance
IEEE Transactions on Fuzzy Systems
Building confidence-interval-based fuzzy random regression models
IEEE Transactions on Fuzzy Systems
A locally recurrent fuzzy neural network with support vector regression for dynamic-system modeling
IEEE Transactions on Fuzzy Systems
Conservative and aggressive rough SVR modeling
Theoretical Computer Science
Interval regression by tolerance analysis approach
Fuzzy Sets and Systems
Interval regression analysis using support vector machine and quantile regression
FSKD'05 Proceedings of the Second international conference on Fuzzy Systems and Knowledge Discovery - Volume Part I
A reduced support vector machine approach for interval regression analysis
Information Sciences: an International Journal
Semidefinite Programming-Based Method for Implementing Linear Fitting to Interval-Valued Data
International Journal of Fuzzy System Applications
| Hi-index | 0.00 |
Support vector machines (SVMs) have been very successful in pattern recognition and function estimation problems for crisp data. This paper proposes a new method to evaluate interval linear and nonlinear regression models combining the possibility and necessity estimation formulation with the principle of quadratic loss SVM. This version of SVM utilizes quadratic loss function, unlike the traditional SVM. For data sets with crisp inputs and interval outputs, the possibility and necessity models have been recently utilized, which are based on quadratic programming approach giving more diverse spread coefficients than a linear programming one. The quadratic loss SVM also uses quadratic programming approach whose another advantage in interval regression analysis is to be able to integrate both the property of central tendency in least squares and the possibilistic property in fuzzy regression. However, this is not a computationally expensive way. The quadratic loss SVM allows us to perform interval nonlinear regression analysis by constructing an interval linear regression function in a high dimensional feature space. The proposed algorithm is a very attractive approach to modeling nonlinear interval data, and is model-free method in the sense that we do not have to assume the underlying model function for interval nonlinear regression model with crisp inputs and interval output. Experimental results are then presented which indicate the performance of this algorithm.