A Two-Stage Combined Classifier in Scale Space Texture Classification
This work addresses texture classification in computer vision, offering an incremental improvement for handling multiscale properties in small datasets.
The paper tackled the problem of multiscale texture classification for small image patches by studying ways to combine features across scales, finding that a two-stage combined classifier outperformed combining feature spaces and support vector machines, especially for small sample sizes.
Textures often show multiscale properties and hence multiscale techniques are considered useful for texture analysis. Scale-space theory as a biologically motivated approach may be used to construct multiscale textures. In this paper various ways are studied to combine features on different scales for texture classification of small image patches. We use the N-jet of derivatives up to the second order at different scales to generate distinct pattern representations (DPR) of feature subsets. Each feature subset in the DPR is given to a base classifier (BC) of a two-stage combined classifier. The decisions made by these BCs are combined in two stages over scales and derivatives. Various combining systems and their significances and differences are discussed. The learning curves are used to evaluate the performances. We found for small sample sizes combining classifiers performs significantly better than combining feature spaces (CFS). It is also shown that combining classifiers performs better than the support vector machine on CFS in multiscale texture classification.