logo

SCIENTIA SINICA Informationis, Volume 46, Issue 12: 1769-1773(2016) https://doi.org/10.1360/N112016-00204

Data modeling and interactive virtual surgery of digital human organs

More info
  • ReceivedAug 23, 2016
  • AcceptedAug 30, 2016
  • PublishedNov 29, 2016

Abstract


Funded by

国家自然科学基金重大项目(61190120)


References

[1] Yang C, Li S, Lan Y, et al. Coupling time-varying modal analysis and FEM for real-time cutting simulation of objects with multi-material sub-domains. Comput Aided Geom Des, 2016, 43: 53-67 CrossRef Google Scholar

[2] Li S, Xia Q, Hao A M, et al. Haptics-equiped interactive PCI simulation for patient-specific surgery training and rehearsing. Sci China Inf Sci, 2016, 59: 103101-67 CrossRef Google Scholar

[3] Wang Q Z, Li S, Qin H, et al. Robust multi-modal medical image fusion via anisotropic heat diffusion guided low-rank structural analysis. Inform Fusion, 2015, 26: 103-121 CrossRef Google Scholar

[4] Yang L P, Li S, Hao A M, et al. Realtime two-way coupling of meshless fluids and nonlinear FEM. Comput Graph Forum, 2012, 31: 2037-2046 CrossRef Google Scholar

[5] Yang L P, Li S, Hao A M, et al. Hybrid particle-grid modeling for multi-scale droplet/spray simulation. Comput Graph Forum, 2014, 33: 199-208. Google Scholar

[6] Li S, Qin H, Hao A M. Multi-scale local features based on anisotropic heat diffusion and global eigen-structure. Sci China Inf Sci, 2013, 56: 110901. Google Scholar

[7] Mao Y R, Hou F, Li S, et al. Robust and high-fidelity guidewire simulation with applications in percutaneous coronary intervention system. In: Proceedings of the 19th ACM Symposium on Virtual Reality Software and Technology, Singapore, 2013. 6-8. Google Scholar

[8] Li S, Zhao Q P, Wang S F, et al. Interactive deformation and cutting simulation directly using patient-specific volumetric images. Comput Animat Virt World, 2014, 25: 155-169 CrossRef Google Scholar

[9] Yang C, Li S, Wang L L, et al. Real-time physical deformation and cutting of heterogeneous objects via hybrid coupling of meshless approach and finite element method. Comput Animat Virt World, 2014, 25: 421-433 CrossRef Google Scholar

[10] Li S, Zhao Q P, Wang S F, et al. A novel material-aware feature descriptor for volumetric image registration in diffusion tensor space. In: Proceedings of the 12th European Conference on Computer Vision, Italy, 2012. 502-515. Google Scholar

[11] Li S, Zhao Q P, Wang S F, et al. Multi-scale, multi-level, heterogeneous features extraction and clustering of volumetric medical images. In: Proceedings of the International Conference on Image Processing, Melbourne, 2013. 1418-1422. Google Scholar

[12] Liu X L, Hou F, Hao A M, et al. A parallelized 4D reconstruction algorithm for vascular structures and motions based on energy optimization. Visual Comput, 2015, 31: 1431-1446 CrossRef Google Scholar

[13] Wang W W, Li S, Xia Q, et al. Novel, robust, and efficient guidewire modeling for pci surgery simulator based on heterogeneous and integrated chain-mails. In: Proceedings of 14th International Conference on Computer-Aided Design and Computer Graphics, Xi'an, 2015. 105-112. Google Scholar

[14] Yang L P, Li S, Xia Q, et al. A novel integrated analysis-and-simulation approach for detail enhancement in FLIP fluid interaction. In: Proceedings of the ACM Symposium on Virtual Reality Software and Technology, Beijing, 2015. 103-112. Google Scholar

[15] Xia Q, Li S, Qin H, et al. Modal space subdivision for physically-plausible 4D shape sequence completion from sparse samples. In: Proceedings of the 23rd Pacific Conference on Computer Graphics and Applications, Beijing, 2015. doi: 10.2312/pg.20151275. Google Scholar

[16] Hou F, Qin H, Hao A M. Trivariate biharmonic b-splines. Comput Graph Forum, 2015, 34: 36-47. Google Scholar

[17] Pan J J, Zhao C K, Zhao X, et al. Metaballs-based physical modeling and deformation of organs for virtual surgery. Visual Comput, 2015, 31: 947-957 CrossRef Google Scholar

[18] Pan J J, Bai J X, Zhao X, et al. Real-time haptic manipulation and cutting of hybrid soft tissue models by extended position-based dynamics. J Visual Comput Animat, 2015, 26: 321-335. Google Scholar

[19] Chen C L, Li S, Qin H, et al. Robust salient motion detection in non-stationary videos via novel integrated strategies of spatio-temporal coherency clues and low-rank analysis. Pattern Recogn, 2016, 52: 410-432 CrossRef Google Scholar

[20] An X Y, Li S, Qin H, et al. Automatic non-parametric image parsing via hierarchical semantic voting based on sparse-dense reconstruction and spatial-contextual cues. Neurocomputing, 2016, 201: 92-103 CrossRef Google Scholar

[21] Chen C L, Li S, Qin H, et al. Structure-sensitive saliency detection via multilevel rank analysis in intrinsic feature space. IEEE Trans Imag Process, 2015, 24: 2303-2316 CrossRef Google Scholar

[22] Chen C L, Li S, Qin H, et al. Real-time and robust object tracking in video via low-rank coherency analysis in feature space. Pattern Recogn, 2015, 48: 2885-2905 CrossRef Google Scholar

[23] Wang S F, Li N N, Li S. Multi-scale mesh saliency based on low-rank and sparse analysis in shape feature space. Comput Aided Geom Des, 2015, 35-36: 206-214 CrossRef Google Scholar

[24] Wang Q Z, Li S, Qin H, et al. Super-resolution of multi-observed RGB-D images based on nonlocal regression and total variation. IEEE Trans Imag Process, 2016, 25: 1425-1440 CrossRef Google Scholar

[25] Ma J Z, Li S, Hao A M, et al. Unsupervised co-segmentation of complex image set via bi-harmonic distance governed multi-level deformable graph clustering. In: Proceedings of the IEEE International Symposium on Multimedia, Washington, 2013. 38-45. Google Scholar

[26] Li X Y, Li S, Xia Q, et al. Interactive volumetric segmentation through least-squares optimization of local hessian-constrained implicits. In: Proceedings of the 21st ACM Symposium on Virtual Reality Software and Technology, New York, 2015. 202. Google Scholar

Copyright 2020 Science China Press Co., Ltd. 《中国科学》杂志社有限责任公司 版权所有

京ICP备18024590号-1       京公网安备11010102003388号