Author :
Maji, Subhrajyoti ; Berg, Alexander C. ; Malik, Jagannath
Author_Institution :
Toyota Technol. Inst. at Chicago, Chicago, IL, USA
Abstract :
We show that a class of nonlinear kernel SVMs admits approximate classifiers with runtime and memory complexity that is independent of the number of support vectors. This class of kernels, which we refer to as additive kernels, includes widely used kernels for histogram-based image comparison like intersection and chi-squared kernels. Additive kernel SVMs can offer significant improvements in accuracy over linear SVMs on a wide variety of tasks while having the same runtime, making them practical for large-scale recognition or real-time detection tasks. We present experiments on a variety of datasets, including the INRIA person, Daimler-Chrysler pedestrians, UIUC Cars, Caltech-101, MNIST, and USPS digits, to demonstrate the effectiveness of our method for efficient evaluation of SVMs with additive kernels. Since its introduction, our method has become integral to various state-of-the-art systems for PASCAL VOC object detection/image classification, ImageNet Challenge, TRECVID, etc. The techniques we propose can also be applied to settings where evaluation of weighted additive kernels is required, which include kernelized versions of PCA, LDA, regression, k-means, as well as speeding up the inner loop of SVM classifier training algorithms.
Keywords :
approximation theory; computational complexity; image classification; support vector machines; Caltech-101; Daimler- Chrysler pedestrians; INRIA person; LDA kernels; MNIST; PCA kernels; SVM classifier training algorithms; UIUC Cars; USPS digits; additive kernel SVM; approximate classifiers; chi-squared kernels; histogram-based image comparison; intersection kernels; k-means kernels; large- scale recognition tasks; memory complexity; nonlinear kernel SVM; real-time detection tasks; regression kernels; runtime complexity; support vector machines; weighted additive kernels; Additives; Complexity theory; Histograms; Kernel; Piecewise linear approximation; Support vector machines; Training; Image classification; additive kernels; efficient classifiers; support vector machines; Algorithms; Artificial Intelligence; Computer Simulation; Decision Support Techniques; Image Interpretation, Computer-Assisted; Models, Theoretical; Pattern Recognition, Automated; Support Vector Machines;
