Abstract
Parsimony, including sparsity and low-rank, has shown great importance for data mining in social networks, particularly in tasks such as segmentation and recognition. Traditionally, such modeling approaches rely on an iterative algorithm that minimizes an objective function with convex l1-norm or nuclear norm constraints. However, the obtained results by convex optimization are usually suboptimal to solutions of original sparse or low-rank problems. In this paper, a novel robust subspace segmentation algorithm has been proposed by integrating lp-norm and Schatten p-norm constraints. Our so-obtained affinity graph can better capture local geometrical structure and the global information of the data. As a consequence, our algorithm is more generative, discriminative and robust. An efficient linearized alternating direction method is derived to realize our model. Extensive segmentation experiments are conducted on public datasets. The proposed algorithm is revealed to be more effective and robust compared to five existing algorithms.
Highlights
High dimensionality research for data mining is an essential topic in modern imaging applications, such as social networks and the Internet of Things (IoT)
Segmentation Results on COIL20 Database. When it comes to the evaluation using second dataset COIL20 [49], the proposed lp SpSS is comes to thealgorithms
We evaluate the robustness of each model on the more challenging Extended Yale B face dataset
Summary
High dimensionality research for data mining is an essential topic in modern imaging applications, such as social networks and the Internet of Things (IoT). It is worth noting that data of high dimension is often supposed to reside in several subspaces of lower dimension. Moving motions in videos [2] and hand-written digits [3] can be approximated by multiple low-dimensional subspaces. These characteristics enable effective segmentation, recognition, and classification to be carried out. This section is divided into three parts. The background of two algorithms, SSC and LRR, will be discussed in Sections 2.2 and 2.3, respectively. Given X, the goal of subspace segmentation is to partition the data points into the underlying low-dimensional subspaces
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
