Marcelo Menezes
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Digital Library
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- S. V. G. de Magalhães. 2017. Exact and Parallel Intersection of 3D Triangular Meshes. Ph.D. thesis. Rensselaer Polytechnic Institute, Troy, NY.Google Scholar
- M. de Matos Menezes, S. V. Gomes Magalhães, W. Randolph Franklin, Matheus Aguilar de Oliveira, and Rodrigo E. O. Bauer Chichorro. 2019. Accelerating the exact evaluation of geometric predicates with GPUs. In Suzanne Shontz, Joaquim Peiró, and Ryan Viertel (Eds.), 28th International Meshing Roundtable, Buffalo, NY. DOI: .Google ScholarCross Ref
- S. Pion and A. Fabri. April. 2011. A generic lazy evaluation scheme for exact geometric computations. Sci. Comput. Program. 76, 4, 307–323. DOI: .Google ScholarDigital Library
- The CGAL Project. 2016. CGAL User and Reference Manual (4.8 ed.). Retrieved October 19, 2017, from http://doc.cgal.org/4.8/Manual/packages.html.Google Scholar
- L. C. Villa Real, B. Silva, D. S. Meliksetian, and K. Sacchi. 2019. Large-scale 3D geospatial processing made possible. In Proceedings of the 27th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems, SIGSPATIAL’19. ACM, New York, NY, 199–208. DOI: .Google ScholarDigital Library
- N. Whitehead and A. Fit-Florea. 2011. Precision & performance: Floating point and IEEE 754 compliance for NVIDIA§ GPUs. rn (A+ B) 21, 1, 18749–19424.Google Scholar
Index Terms
- Employing GPUs to Accelerate Exact Geometric Predicates for 3D Geospatial Processing
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Graphical abstractDisplay Omitted
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