残余物
生物发光
计算机科学
图形
断层摄影术
人工智能
计算机视觉
算法
理论计算机科学
物理
生物
光学
生态学
作者
Wei De,Yizhe Zhao,Shuangchen Li,Heng Zhang,Beilei Wang,Xiaowei He,Jingjing Yu,Huangjian Yi,Xuelei He,Hongbo Guo
出处
期刊:IEEE transactions on computational imaging
日期:2025-01-01
卷期号:11: 790-802
标识
DOI:10.1109/tci.2025.3572727
摘要
For bioluminescence tomography reconstruction, regularization algorithms and deep learning frameworks have been widely studied and achieved impressive results. However, the parameter selection of the regularization algorithm and the poor interpretability of deep learning methods have become the key factors that affect the reconstruction results and hinder its applicability. To mitigate the effects of this problem, in this paper, we proposed a novel residual graph model learning network (RGMLN) for bioluminescence tomography reconstruction by combining the advantages of regularization method and deep learning. RGMLN is based on the inference process of the thresholding iterative shrinkage algorithm. The difference is that the penalty term of the regularization method was replaced by a learnable nonlinear mapping between the residual and source distributions to ensure the interpretability of network. Meanwhile, considering the non-Euclidean property of the finite element mesh, a graph convolution operation based on Laplacian graph theory was conducted to aggregate features of mesh nodes using the topological information of the tetrahedral mesh. Lastly, based on residual learning and auto-encoder strategies, gradient descent and prox mapping modules were designed to structure the modeldriven RGMLN method to take advantage of both the interpretability of iterative techniques and the flexibility of learning methods. Both numerical and in vivo experiments confirmed that the proposed network has excellent positioning accuracy and can be applied to different meshes and wavelengths
科研通智能强力驱动
Strongly Powered by AbleSci AI