论文信息 - Invariants of the Space Point Element Structure and Their Applications

Invariants of the Space Point Element Structure and Their Applications

In this paper, a new geometric structure of projective invariants is proposed. Compared with the traditional invariant calculation method based on 3D reconstruction, this method is comparable in the reliability of invariant calculation. According to this method, the only thing needed to find out is the geometric relationship between 3D points and 2D points, and the invariant can be obtained by using a single frame image. In the method based on 3D reconstruction, the basic matrix of two images is estimated first, and then, the 3D projective invariants are calculated according to the basic matrix. Therefore, in terms of algorithm complexity, the method proposed in this paper is superior to the traditional method. In this paper, we also study the projection transformation from a 3D point to a 2D point in space. According to this relationship, the geometric invariant relationships of other point structures can be easily derived, which have important applications in model-based object recognition. At the same time, the experimental results show that the eight-point structure invariants proposed in this paper can effectively describe the essential characteristics of the 3D structure of the target, without the influence of view, scaling, lighting, and other link factors, and have good stability and reliability.

Guitao Cao | Youzheng Zhang | Yanping Mui

[1] Zhi Zhang,et al. Fast Deep Neural Networks With Knowledge Guided Training and Predicted Regions of Interests for Real-Time Video Object Detection , 2018, IEEE Access.

[2] Huazhong Shu,et al. Translation and scale invariants of Tchebichef moments , 2007, Pattern Recognit..

[3] Tao Wang,et al. L1-Norm Minimization for Multi-dimensional Signals Based on Geometric Algebra , 2019, Advances in Applied Clifford Algebras.

[4] Wenming Cao,et al. Joint Sparse Representation Model for Multi-Channel Image Based on Reduced Geometric Algebra , 2018, IEEE Access.

[5] Junchi Yan,et al. Adaptive Discrete Hypergraph Matching , 2018, IEEE Transactions on Cybernetics.

[6] Zhang Youzheng,et al. Invariants of Space Line Element Structure Based on Projective Geometric Algebra , 2020, IEEE Access.

[7] Zhihai He,et al. A Comprehensive Survey on Geometric Deep Learning , 2020, IEEE Access.

[8] Yan Ke,et al. PCA-SIFT: a more distinctive representation for local image descriptors , 2004, CVPR 2004.

[9] Hui Wei,et al. Line Feature Based Man-Made Object Recognition with Invariance: Line Feature Based Man-Made Object Recognition with Invariance , 2010 .

[10] Zhihai He,et al. Hybrid representation learning for cross-modal retrieval , 2019, Neurocomputing.

[11] Zhihai He,et al. A Review of Hashing Methods for Multimodal Retrieval , 2020, IEEE Access.