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ORCIDAmir Vaxman
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2020 – today
- 2025
[c7]Thomas Walker, Octave Mariotti, Amir Vaxman, Hakan Bilen:
Spatially-Adaptive Hash Encodings for Neural Surface Reconstruction. WACV 2025: 2963-2972- [i15]Ioanna Mitropoulou, Amir Vaxman, Olga Diamanti, Benjamin Dillenburger:
Non-planar 3D Printing of Double Shells. CoRR abs/2501.06088 (2025) - 2024
- [j29]Ioanna Mitropoulou
, Amir Vaxman, Olga Diamanti, Benjamin Dillenburger:
Fabrication-aware strip-decomposable quadrilateral meshes. Comput. Aided Des. 168: 103666 (2024) - [j28]Aviv Segall, Jing Ren, Amir Vaxman, Olga Sorkine-Hornung:
Fabric Tessellation: Realizing Freeform Surfaces by Smocking. ACM Trans. Graph. 43(4): 89:1-89:20 (2024) - [i14]Miaowei Wang, Changjian Li, Amir Vaxman:
Canonical Consolidation Fields: Reconstructing Dynamic Shapes from Point Clouds. CoRR abs/2406.18582 (2024) - [i13]Thomas Walker, Salvatore Esposito, Daniel Rebain, Amir Vaxman, Arno Onken, Changjian Li, Oisin Mac Aodha:
CrossSDF: 3D Reconstruction of Thin Structures From Cross-Sections. CoRR abs/2412.04120 (2024) - [i12]Thomas Walker, Octave Mariotti, Amir Vaxman, Hakan Bilen:
Spatially-Adaptive Hash Encodings For Neural Surface Reconstruction. CoRR abs/2412.05179 (2024) - 2023
- [j27]Shir Rorberg, Amir Vaxman, Mirela Ben-Chen:
BPM: Blended Piecewise Möbius Maps. Comput. Graph. Forum 42(5): i-viii (2023) - [j26]Lorenzo Diazzi, Daniele Panozzo, Amir Vaxman, Marco Attene:
Constrained Delaunay Tetrahedrization: A Robust and Practical Approach. ACM Trans. Graph. 42(6): 181:1-181:15 (2023) - [c6]Haim Sawdayee, Amir Vaxman, Amit H. Bermano:
OReX: Object Reconstruction from Planar Cross-sections Using Neural Fields. CVPR 2023: 20854-20862 - [i11]Thomas Walker, Octave Mariotti, Amir Vaxman, Hakan Bilen:
Explicit Neural Surfaces: Learning Continuous Geometry With Deformation Fields. CoRR abs/2306.02956 (2023) - [i10]Shir Rorberg, Amir Vaxman, Mirela Ben-Chen:
BPM: Blended Piecewise Moebius Maps. CoRR abs/2306.12792 (2023) - [i9]Ioanna Mitropoulou, Amir Vaxman, Olga Diamanti, Benjamin Dillenburger:
Fabrication-Aware Strip-Decomposable Quadrilateral Meshes. CoRR abs/2307.14020 (2023) - [i8]Lorenzo Diazzi, Daniele Panozzo, Amir Vaxman, Marco Attene:
Constrained Delaunay Tetrahedrization: A Robust and Practical Approach. CoRR abs/2309.09805 (2023) - 2022
- [j25]Floor Verhoeven, Amir Vaxman, Tim Hoffmann, Olga Sorkine-Hornung:
Dev2PQ: Planar Quadrilateral Strip Remeshing of Developable Surfaces. ACM Trans. Graph. 41(3): 29:1-29:18 (2022) - [j24]Iwan Boksebeld, Amir Vaxman:
High-Order Directional Fields. ACM Trans. Graph. 41(6): 254:1-254:17 (2022) - [i7]Haim Sawdayee, Amir Vaxman, Amit H. Bermano:
OReX: Object Reconstruction from Planner Cross-sections Using Neural Fields. CoRR abs/2211.12886 (2022) - 2021
- [j23]Merel Meekes, Amir Vaxman:
Unconventional patterns on surfaces. ACM Trans. Graph. 40(4): 101:1-101:16 (2021) - [j22]Kacper Pluta, Michal Edelstein, Amir Vaxman, Mirela Ben-Chen:
PH-CPF: planar hexagonal meshing using coordinate power fields. ACM Trans. Graph. 40(4): 156:1-156:19 (2021) - [i6]Floor Verhoeven, Amir Vaxman, Tim Hoffmann, Olga Sorkine-Hornung:
Dev2PQ: Planar Quadrilateral Strip Remeshing of Developable Surfaces. CoRR abs/2103.00239 (2021) - [i5]Marc J. van Kreveld, Frank Staals, Amir Vaxman, Jordi L. Vermeulen:
Approximating the Earth Mover's Distance between sets of geometric objects. CoRR abs/2104.08136 (2021) - [i4]Kacper Pluta, Michal Edelstein, Amir Vaxman, Mirela Ben-Chen:
PH-CPF: Planar Hexagonal Meshing using Coordinate Power Fields. CoRR abs/2105.02507 (2021) - 2020
- [j21]Bram Custers, Amir Vaxman:
Subdivision Directional Fields. ACM Trans. Graph. 39(2): 11:1-11:20 (2020) - [i3]Christian Müller, Amir Vaxman:
Discrete Curvature and Torsion from Cross-Ratios. CoRR abs/2008.13236 (2020)
2010 – 2019
- 2019
- [j20]Mees van de Kerkhof, Tim de Jong, Raphael Parment, Maarten Löffler, Amir Vaxman, Marc J. van Kreveld:
Design and Automated Generation of Japanese Picture Puzzles. Comput. Graph. Forum 38(2): 343-353 (2019) - [j19]Meged Shoham, Amir Vaxman, Mirela Ben-Chen:
Hierarchical Functional Maps between Subdivision Surfaces. Comput. Graph. Forum 38(5): 55-73 (2019) - [j18]Justin Solomon, Amir Vaxman:
Optimal transport-based polar interpolation of directional fields. ACM Trans. Graph. 38(4): 88:1-88:13 (2019) - [j17]Andrew O. Sageman-Furnas, Albert Chern, Mirela Ben-Chen, Amir Vaxman:
Chebyshev nets from commuting PolyVector fields. ACM Trans. Graph. 38(6): 172:1-172:16 (2019) - 2018
- [j16]Amir Vaxman, Christian Müller, Ofir Weber:
Canonical Möbius subdivision. ACM Trans. Graph. 37(6): 227 (2018) - [e2]Olga Diamanti, Amir Vaxman:
39th Annual Conference of the European Association for Computer Graphics, Eurographics 2018 - Short Papers, Delft, The Netherlands, April 16-20, 2018. Eurographics Association 2018 [contents] - [e1]Tao Ju, Amir Vaxman:
16th Eurographics Symposium on Geometry Processing, SGP 2018 - Posters, Paris, France, July 7-11, 2018. Eurographics Association 2018, ISBN 978-3-03868-069-7 [contents] - [i2]Bram Custers, Amir Vaxman:
Subdivision Directional Fields. CoRR abs/1810.06884 (2018) - 2017
- [j15]Justin Solomon, Amir Vaxman, David Bommes:
Boundary Element Octahedral Fields in Volumes. ACM Trans. Graph. 36(3): 28:1-28:16 (2017) - [j14]Amir Vaxman, Christian Müller, Ofir Weber:
Regular meshes from polygonal patterns. ACM Trans. Graph. 36(4): 113:1-113:15 (2017) - [j13]Nico Pietroni, Marco Tarini, Amir Vaxman, Daniele Panozzo, Paolo Cignoni:
Position-based tensegrity design. ACM Trans. Graph. 36(6): 172:1-172:14 (2017) - [c5]Amir Vaxman, Marcel Campen, Olga Diamanti, David Bommes, Klaus Hildebrandt, Mirela Ben-Chen, Daniele Panozzo:
Directional field synthesis, design, and processing. SIGGRAPH Courses 2017: 12:1-12:30 - 2016
- [j12]Amir Vaxman, Marcel Campen, Olga Diamanti, Daniele Panozzo, David Bommes, Klaus Hildebrandt, Mirela Ben-Chen:
Directional Field Synthesis, Design, and Processing. Comput. Graph. Forum 35(2): 545-572 (2016) - [c4]Amir Vaxman, Marcel Campen, Olga Diamanti, David Bommes, Klaus Hildebrandt, Mirela Ben-Chen, Daniele Panozzo:
Directional field synthesis, design, and processing. SIGGRAPH ASIA Courses 2016: 15:1-15:30 - 2015
- [j11]Helmut Pottmann, Michael Eigensatz, Amir Vaxman, Johannes Wallner:
Architectural geometry. Comput. Graph. 47: 145-164 (2015) - [j10]Olga Diamanti, Amir Vaxman, Daniele Panozzo, Olga Sorkine-Hornung:
Integrable PolyVector fields. ACM Trans. Graph. 34(4): 38:1-38:12 (2015) - [j9]Amir Vaxman, Christian Müller, Ofir Weber:
Conformal mesh deformations with Möbius transformations. ACM Trans. Graph. 34(4): 55:1-55:11 (2015) - [j8]Caigui Jiang, Chengcheng Tang, Amir Vaxman, Peter Wonka, Helmut Pottmann:
Polyhedral patterns. ACM Trans. Graph. 34(6): 172:1-172:12 (2015) - 2014
- [j7]Olga Diamanti, Amir Vaxman, Daniele Panozzo, Olga Sorkine-Hornung:
Designing N-PolyVector Fields with Complex Polynomials. Comput. Graph. Forum 33(5): 1-11 (2014) - [j6]Amir Vaxman:
A Projective Framework for Polyhedral Mesh Modelling. Comput. Graph. Forum 33(8): 121-131 (2014) - 2012
- [j5]Amir Vaxman:
Modeling Polyhedral Meshes with Affine Maps. Comput. Graph. Forum 31(5): 1647-1656 (2012) - 2011
- [b1]Amir Vaxman:
General techniques for interpolation reconstruction and morphing of polyhedral surfaces. Technion - Israel Institute of Technology, Israel, 2011 - [j4]Amit Bermano, Amir Vaxman, Craig Gotsman:
Online reconstruction of 3D objects from arbitrary cross-sections. ACM Trans. Graph. 30(5): 113:1-113:11 (2011) - 2010
- [j3]Amir Vaxman, Mirela Ben-Chen, Craig Gotsman:
A multi-resolution approach to heat kernels on discrete surfaces. ACM Trans. Graph. 29(4): 121:1-121:10 (2010)
2000 – 2009
- 2009
- [j2]Gill Barequet, Amir Vaxman:
Reconstruction of Multi-Label Domains from Partial Planar Cross-Sections. Comput. Graph. Forum 28(5): 1327-1337 (2009) - [c3]Gill Barequet, Amir Vaxman:
Straight skeletons of three-dimensional polyhedra. SCG 2009: 100-101 - 2008
- [j1]Gill Barequet, Amir Vaxman:
Nonlinear Interpolation between Slices. Int. J. Shape Model. 14(1): 39-60 (2008) - [c2]Gill Barequet, David Eppstein, Michael T. Goodrich, Amir Vaxman:
Straight Skeletons of Three-Dimensional Polyhedra. ESA 2008: 148-160 - [i1]Gill Barequet, David Eppstein, Michael T. Goodrich, Amir Vaxman:
Straight Skeletons of Three-Dimensional Polyhedra. CoRR abs/0805.0022 (2008) - 2007
- [c1]Gill Barequet, Amir Vaxman:
Nonlinear interpolation between slices. Symposium on Solid and Physical Modeling 2007: 97-107
Coauthor Index
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last updated on 2025-04-24 22:12 CEST by the dblp team
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