A central issue in computational intelligence is the training phase of a learning machine. In classification problems, in particular, Support Vector Machines are one of the most effective tools. In this work an analog low-complexity circuital implementation is proposed to address the learning stage of SVMs. The circuit is a co-content minimization network based on a suitable SVM formulation embedding bias removal. Moreover the circuit complexity (i.e. the density of the kernel matrix) is effectively controlled by resorting to a proper kernel function. Experimental evidence shows the effectiveness of the proposed approac
Recently two kinds of reduction techniques which aimed at saving training time for SVM problems with...
In this chapter we introduce basic concepts and ideas of the Support Vector Machines (SVM). In the f...
Training a Support Vector Machine (SVM) requires the solution of a quadratic programming problem (QP...
A sparse, positive-definite kernel function is adopted as the basis for the formulation of a simple ...
We propose here a VLSI friendly algorithm for the implementation of the learning phase of Support Ve...
Support Vector Machines are gaining more and more acceptance thanks to their success in many real-wo...
In this paper, we propose a digital architecture for support vector machine (SVM) learning and discu...
In this paper we propose some very simple algorithms and architectures for a digital VLSI implementa...
Training Support Vector Machines (SVMs) requires efficient architectures, endowed with agile memory ...
The chapter deals with the use of the support vector machine (SVM) algorithm as a possible design me...
A learning algorithm for radial basis function support vector machines (RBF-SVM) that can be easily ...
Support Vector Machines (SVM) have been used for creating fast and efficient models for quickly pred...
Support Vector Machines (SVMs) have proven to be highly eective for learning many real world dataset...
This masters thesis deals with algorithms for learning SVM classifiers on hardware systems and their...
Abstract. The tutorial starts with an overview of the concepts of VC dimension and structural risk m...
Recently two kinds of reduction techniques which aimed at saving training time for SVM problems with...
In this chapter we introduce basic concepts and ideas of the Support Vector Machines (SVM). In the f...
Training a Support Vector Machine (SVM) requires the solution of a quadratic programming problem (QP...
A sparse, positive-definite kernel function is adopted as the basis for the formulation of a simple ...
We propose here a VLSI friendly algorithm for the implementation of the learning phase of Support Ve...
Support Vector Machines are gaining more and more acceptance thanks to their success in many real-wo...
In this paper, we propose a digital architecture for support vector machine (SVM) learning and discu...
In this paper we propose some very simple algorithms and architectures for a digital VLSI implementa...
Training Support Vector Machines (SVMs) requires efficient architectures, endowed with agile memory ...
The chapter deals with the use of the support vector machine (SVM) algorithm as a possible design me...
A learning algorithm for radial basis function support vector machines (RBF-SVM) that can be easily ...
Support Vector Machines (SVM) have been used for creating fast and efficient models for quickly pred...
Support Vector Machines (SVMs) have proven to be highly eective for learning many real world dataset...
This masters thesis deals with algorithms for learning SVM classifiers on hardware systems and their...
Abstract. The tutorial starts with an overview of the concepts of VC dimension and structural risk m...
Recently two kinds of reduction techniques which aimed at saving training time for SVM problems with...
In this chapter we introduce basic concepts and ideas of the Support Vector Machines (SVM). In the f...
Training a Support Vector Machine (SVM) requires the solution of a quadratic programming problem (QP...