Segmentation over detection by coupled global and local sparse representations

Abstract

Motivated by the rising performances of object detection algorithms, we investigate how to further precisely segment out objects within the output bounding boxes. The task is formulated as a unified optimization problem, pursuing a unique latent object mask in non-parametric manner. For a given test image, the objects are first detected by detectors. Then for each detected bounding box, the objects of the same category along with their object masks are extracted from the training set. The latent mask of the object within the bounding box is inferred based on three objectives: 1) the latent mask should be coherent, subject to sparse errors caused by within-category diversities, with the global bounding-box-level mask inferred by sparse representation over the bounding boxes of the same category within the training set; 2) the latent mask should be coherent with local patch-level mask inferred by sparse representation of the individual patch over all spatially nearby (handling local deformations) patches of the same category in the training set; and 3) mask property within each sufficiently small super-pixel should be consistent. All these three objectives are integrated into a unified optimization problem, and finally the sparse representation coefficients and the latent mask are alternately optimized based on Lasso optimization and smooth approximation followed by Accelerated Proximal Gradient method, respectively. Extensive experiments on the Pascal VOC object segmentation datasets, VOC2007 and VOC2010, show that our proposed algorithm achieves competitive results with the state-of-the-art learning based algorithms, and is superior over other detection based object segmentation algorithms. © 2012 Springer-Verlag.