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Craig Gotsman
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- affiliation: New Jersey Institute of Technology, Ying Wu College of Computing, USA
- affiliation: Technion - Israel Institute of Technology
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2020 – today
- 2024
- [c48]Craig Gotsman
, Kai Hormann
A Linear Method to Consistently Orient Normals of a 3D Point Cloud. SIGGRAPH (Conference Paper Track) 2024: 55 - 2023
- [j92]Craig Gotsman, Kai Hormann:
Efficient Point-to-Point Resistance Distance Queries in Large Graphs. J. Graph Algorithms Appl. 27(1): 35-44 (2023) - 2022
- [c47]Craig Gotsman
Compressing Geodesic Information for Fast Point-to-Point Geodesic Distance Queries. SIGGRAPH Asia 2022: 4:1-4:9 - 2021
- [j91]Craig Gotsman
On Landmark Distances in Polygons. Comput. Graph. Forum 40(5): 275-287 (2021) - [j90]Renjie Chen, Craig Gotsman:
Efficient fastest-path computations for road maps. Comput. Vis. Media 7(2): 267-281 (2021) - [j89]Cuicui Zheng
A DIRECT-type global optimization algorithm for image registration. J. Glob. Optim. 79(2): 431-445 (2021) - 2020
- [c46]Renjie Chen, Craig Gotsman:
Fast a on road networks using a scalable separator-based heuristic. IWCTS@SIGSPATIAL 2020: 8:1-8:8 - [i12]Craig Gotsman, Kai Hormann:
Secure Data Hiding for Contact Tracing. CoRR abs/2008.06297 (2020) - [i11]Craig Gotsman, Kai Hormann:
Secure Data Hiding for Contact Tracing. IACR Cryptol. ePrint Arch. 2020: 1028 (2020)
2010 – 2019
- 2018
- [j88]Renjie Chen
Path planning with divergence-based distance functions. Comput. Aided Geom. Des. 66: 52-74 (2018) - [j87]Renjie Chen, Craig Gotsman
Efficient Path Generation with Reduced Coordinates. Comput. Graph. Forum 37(5): 37-48 (2018) - [i10]Renjie Chen, Craig Gotsman:
Efficient Fastest-Path Computations in Road Maps. CoRR abs/1810.01776 (2018) - [i9]Renjie Chen, Craig Gotsman:
A Scalable Heuristic for Fastest-Path Computation on Very Large Road Maps. CoRR abs/1812.07441 (2018) - 2017
- [j86]Renjie Chen, Craig Gotsman
Approximating Planar Conformal Maps Using Regular Polygonal Meshes. Comput. Graph. Forum 36(8): 629-642 (2017) - [i8]Renjie Chen, Craig Gotsman, Kai Hormann:
Path Planning with Divergence-Based Distance Functions. CoRR abs/1708.02845 (2017) - [i7]Renjie Chen, Craig Gotsman, Kai Hormann:
Practical Distance Functions for Path-Planning in Planar Domains. CoRR abs/1708.05855 (2017) - 2016
- [j85]Renjie Chen, Craig Gotsman
On pseudo-harmonic barycentric coordinates. Comput. Aided Geom. Des. 44: 15-35 (2016) - [j84]Renjie Chen, Craig Gotsman
Generalized As-Similar-As-Possible Warping with Applications in Digital Photography. Comput. Graph. Forum 35(2): 81-92 (2016) - [j83]Renjie Chen, Craig Gotsman
Complex Transfinite Barycentric Mappings with Similarity Kernels. Comput. Graph. Forum 35(5): 41-53 (2016) - 2015
- [j82]Zohar Levi, Craig Gotsman
Smooth Rotation Enhanced As-Rigid-As-Possible Mesh Animation. IEEE Trans. Vis. Comput. Graph. 21(2): 264-277 (2015) - [j81]Roi Poranne, Renjie Chen
On Linear Spaces of Polyhedral Meshes. IEEE Trans. Vis. Comput. Graph. 21(5): 652-662 (2015) - 2013
- [j80]Roi Poranne, Elena Ovreiu, Craig Gotsman
Interactive Planarization and Optimization of 3D Meshes. Comput. Graph. Forum 32(1): 152-163 (2013) - [j79]Zohar Levi, Craig Gotsman
ArtiSketch: A System for Articulated Sketch Modeling. Comput. Graph. Forum 32(2): 235-244 (2013) - [j78]Steven J. Gortler, Craig Gotsman, Ligang Liu, Dylan Thurston:
On affine rigidity. J. Comput. Geom. 4(1): 160-181 (2013) - [j77]Renjie Chen
Localizing the Delaunay Triangulation and Its Parallel Implementation. Trans. Comput. Sci. 20: 39-55 (2013) - [j76]Zohar Levi, Craig Gotsman
D-Snake: Image Registration by As-Similar-As-Possible Template Deformation. IEEE Trans. Vis. Comput. Graph. 19(2): 331-343 (2013) - [i6]Roi Poranne, Renjie Chen, Craig Gotsman:
On Linear Spaces of Polyhedral Meshes. CoRR abs/1303.4110 (2013) - 2012
- [j75]Yin Xu, Ruizhen Hu, Craig Gotsman
Blue noise sampling of surfaces. Comput. Graph. 36(4): 232-240 (2012) - [j74]Renjie Chen
Parallel Blue-noise Sampling by Constrained Farthest Point Optimization. Comput. Graph. Forum 31(5): 1775-1785 (2012) - [j73]Ofir Weber, Roi Poranne, Craig Gotsman
Biharmonic Coordinates. Comput. Graph. Forum 31(8): 2409-2422 (2012) - [j72]Claudia Kuster, Tiberiu Popa, Jean-Charles Bazin, Craig Gotsman
Gaze correction for home video conferencing. ACM Trans. Graph. 31(6): 174:1-174:6 (2012) - [c45]Renjie Chen
Localizing the Delaunay Triangulation and its Parallel Implementation. ISVD 2012: 24-31 - 2011
- [j71]Yin Xu, Renjie Chen
Embedding a triangular graph within a given boundary. Comput. Aided Geom. Des. 28(6): 349-356 (2011) - [j70]Yin Xu, Ligang Liu, Craig Gotsman
Capacity-Constrained Delaunay Triangulation for point distributions. Comput. Graph. 35(3): 510-516 (2011) - [j69]Ofir Weber, Mirela Ben-Chen, Craig Gotsman
A Complex View of Barycentric Mappings. Comput. Graph. Forum 30(5): 1533-1542 (2011) - [j68]Mirela Ben-Chen, Steven J. Gortler, Craig Gotsman
Distributed computation of virtual coordinates for greedy routing in sensor networks. Discret. Appl. Math. 159(7): 544-560 (2011) - [j67]Thabo Beeler, Fabian Hahn, Derek Bradley, Bernd Bickel
High-quality passive facial performance capture using anchor frames. ACM Trans. Graph. 30(4): 75 (2011) - [j66]Amit Bermano
Online reconstruction of 3D objects from arbitrary cross-sections. ACM Trans. Graph. 30(5): 113:1-113:11 (2011) - [c44]Claudia Kuster, Tiberiu Popa, Christopher Zach, Craig Gotsman
FreeCam: A Hybrid Camera System for Interactive Free-Viewpoint Video. VMV 2011: 17-24 - 2010
- [j65]Renjie Chen
A spectral characterization of the Delaunay triangulation. Comput. Aided Geom. Des. 27(4): 295-300 (2010) - [j64]Lei Zhang, Ligang Liu, Craig Gotsman
Mesh reconstruction by meshless denoising and parameterization. Comput. Graph. 34(3): 198-208 (2010) - [j63]Roi Poranne, Craig Gotsman
3D Surface Reconstruction Using a Generalized Distance Function. Comput. Graph. Forum 29(8): 2479-2491 (2010) - [j62]Ofir Weber, Craig Gotsman
Controllable conformal maps for shape deformation and interpolation. ACM Trans. Graph. 29(4): 78:1-78:11 (2010) - [j61]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) - [j60]Lei Zhang, Ligang Liu, Craig Gotsman
An as-rigid-as-possible approach to sensor network localization. ACM Trans. Sens. Networks 6(4): 35:1-35:21 (2010) - [c43]Renjie Chen
Content-aware image resizing by quadratic programming. CVPR Workshops 2010: 1-8 - [i5]Steven J. Gortler, Craig Gotsman, Ligang Liu, Dylan Thurston:
On affine rigidity. CoRR abs/1011.5553 (2010)
2000 – 2009
- 2009
- [j59]Ofir Weber, Mirela Ben-Chen, Craig Gotsman
Complex Barycentric Coordinates with Applications to Planar Shape Deformation. Comput. Graph. Forum 28(2): 587-597 (2009) - [j58]Zachi Karni, D. Freedman, Craig Gotsman
Energy-Based Image Deformation. Comput. Graph. Forum 28(5): 1257-1268 (2009) - [j57]Mirela Ben-Chen, Ofir Weber, Craig Gotsman
Variational harmonic maps for space deformation. ACM Trans. Graph. 28(3): 34 (2009) - [c42]Mirela Ben-Chen, Ofir Weber, Craig Gotsman
Spatial deformation transfer. Symposium on Computer Animation 2009: 67-74 - 2008
- [j56]Fady Massarwi, Craig Gotsman
Paper-craft from 3D polygonal models using generalized cylinders. Comput. Aided Geom. Des. 25(8): 576-591 (2008) - [j55]Alexander Bogomjakov, Craig Gotsman
Reduced Depth and Visual Hulls of Complex 3D Scenes. Comput. Graph. Forum 27(2): 175-182 (2008) - [j54]Yuri Pekelny, Craig Gotsman
Articulated Object Reconstruction and Markerless Motion Capture from Depth Video. Comput. Graph. Forum 27(2): 399-408 (2008) - [j53]Mirela Ben-Chen, Craig Gotsman
Conformal Flattening by Curvature Prescription and Metric Scaling. Comput. Graph. Forum 27(2): 449-458 (2008) - [j52]Alexander Bogomjakov, Craig Gotsman
Distortion-Free Steganography for Polygonal Meshes. Comput. Graph. Forum 27(2): 637-642 (2008) - [j51]Ligang Liu, Lei Zhang, Yin Xu, Craig Gotsman
A Local/Global Approach to Mesh Parameterization. Comput. Graph. Forum 27(5): 1495-1504 (2008) - [j50]Craig Gotsman
On the Computation of Null Spaces of Sparse Rectangular Matrices. SIAM J. Matrix Anal. Appl. 30(2): 445-463 (2008) - [j49]Tim Winkler, Kai Hormann
Mesh massage. Vis. Comput. 24(7-9): 775-785 (2008) - [c41]Mirela Ben-Chen, Craig Gotsman:
Characterizing Shape Using Conformal Factors. 3DOR@Eurographics 2008: 1-8 - [p4]Pierre Alliez, Giuliana Ucelli, Craig Gotsman
Recent Advances in Remeshing of Surfaces. Shape Analysis and Structuring 2008: 53-82 - 2007
- [j48]Craig Gotsman
Cycle bases of graphs and sampled manifolds. Comput. Aided Geom. Des. 24(8-9): 464-480 (2007) - [j47]Ofir Weber, Olga Sorkine, Yaron Lipman, Craig Gotsman
Context-Aware Skeletal Shape Deformation. Comput. Graph. Forum 26(3): 265-274 (2007) - [c40]Mirela Ben-Chen, Craig Gotsman
Distributed computation of virtual coordinates. SCG 2007: 210-219 - [c39]Fady Massarwi, Craig Gotsman, Gershon Elber:
Papercraft Models using Generalized Cylinders. PG 2007: 148-157 - 2006
- [j46]Steven J. Gortler, Craig Gotsman
Discrete one-forms on meshes and applications to 3D mesh parameterization. Comput. Aided Geom. Des. 23(2): 83-112 (2006) - [j45]Geetika Tewari, Craig Gotsman
Meshing genus-1 point clouds using discrete one-forms. Comput. Graph. 30(6): 917-926 (2006) - [j44]Ian Fischer, Craig Gotsman:
Fast Approximation of High-Order Voronoi Diagrams and Distance Transforms on the GPU. J. Graph. Tools 11(4): 39-60 (2006) - [c38]Gill Barequet, Craig Gotsman, Avishay Sidlesky:
Polygon Reconstruction from Line Cross-Sections. CCCG 2006 - [c37]Mirela Ben-Chen, Craig Gotsman, Steven J. Gortler:
Routing with Guaranteed Delivery on Virtual Coordinates. CCCG 2006 - [c36]Craig Gotsman, Ian Fischer:
Computing Depth Contours with Graphics Hardware. CCCG 2006 - 2005
- [j43]Craig Gotsman
Editorial. Comput. Aided Geom. Des. 22(5): 375 (2005) - [j42]Craig Gotsman
Distributed Graph Layout for Sensor Networks. J. Graph Algorithms Appl. 9(3): 327-346 (2005) - [j41]Mirela Ben-Chen, Craig Gotsman
On the optimality of spectral compression of mesh data. ACM Trans. Graph. 24(1): 60-80 (2005) - [j40]Robert W. Sumner, Matthias Zwicker
Mesh-based inverse kinematics. ACM Trans. Graph. 24(3): 488-495 (2005) - [j39]Oleg Polonsky, Giuseppe Patanè
What's in an image? Vis. Comput. 21(8-10): 840-847 (2005) - [c35]Craig Gotsman
What's in a Mesh? A Survey of 3D Mesh Representation Schemes. SMI 2005: 2 - [c34]Shadi Saba, Irad Yavneh, Craig Gotsman
Practical Spherical Embedding of Manifold Triangle Meshes. SMI 2005: 258-267 - [c33]Zachi Karni, Craig Gotsman
Free-Boundary Linear Parameterization of 3D Meshes in the Presence of Constraints. SMI 2005: 268-277 - [p3]Pierre Alliez, Craig Gotsman:
Recent Advances in Compression of 3D Meshes. Advances in Multiresolution for Geometric Modelling 2005: 3-26 - 2004
- [j38]Zachi Karni, Craig Gotsman
Compression of soft-body animation sequences. Comput. Graph. 28(1): 25-34 (2004) - [j37]Alla Sheffer, Craig Gotsman
Robust Spherical Parameterization of Triangular Meshes. Computing 72(1-2): 185-193 (2004) - [j36]Vitaly Surazhsky, Craig Gotsman
High quality compatible triangulations. Eng. Comput. 20(2): 147-156 (2004) - [j35]Roni Raab, Craig Gotsman
Virtual Woodwork: Making Toys from Geometric Models. Int. J. Shape Model. 10(1): 1-30 (2004) - [j34]Alexander Goldin, Craig Gotsman
Geometric Message-Filtering Protocols for Distributed Multiagent Environments. Presence Teleoperators Virtual Environ. 13(3): 279-295 (2004) - [c32]Craig Gotsman
Geometry Processing - A Personal Perspective. 3DPVT 2004: 67 - [c31]Alexander Bogomjakov, Craig Gotsman
GPU-Assisted Z-Field Simplification. 3DPVT 2004: 673-679 - [c30]Craig Gotsman, Yehuda Koren:
Distributed Graph Layout for Sensor Networks. GD 2004: 273-284 - [c29]Matthias Zwicker, Craig Gotsman:
Meshing Point Clouds Using Spherical Parameterization. PBG 2004: 173-180 - 2003
- [j33]Craig Gotsman
On the Optimality of Valence-based Connectivity Coding. Comput. Graph. Forum 22(1): 99-102 (2003) - [j32]Vitaly Surazhsky, Craig Gotsman
Intrinsic Morphing of Compatible Triangulations. Int. J. Shape Model. 9(2): 191-202 (2003) - [j31]Vladislav Kraevoy, Alla Sheffer, Craig Gotsman
Matchmaker: constructing constrained texture maps. ACM Trans. Graph. 22(3): 326-333 (2003) - [j30]Craig Gotsman
Fundamentals of spherical parameterization for 3D meshes. ACM Trans. Graph. 22(3): 358-363 (2003) - [c28]Oren Sifri, Alla Sheffer, Craig Gotsman:
Geodesic-based Surface Remeshing. IMR 2003: 189-199 - [c27]Vitaly Surazhsky, Pierre Alliez, Craig Gotsman:
Isotropic Remeshing of Surfaces: A Local Parameterization Approach. IMR 2003: 215-224 - [c26]Vitaly Surazhsky, Craig Gotsman:
Explicit Surface Remeshing. Symposium on Geometry Processing 2003: 20-30 - [c25]Craig Gotsman
On Graph Partitioning, Spectral Analysis, and Digital Mesh Processing. Shape Modeling International 2003: 165-174 - [c24]Daniel Brunstein, Gill Barequet, Craig Gotsman:
Animating a Camera for Viewing a Planar Polygon. VMV 2003: 87-94 - 2002
- [j29]Alexander Bogomjakov, Craig Gotsman
Universal Rendering Sequences for Transparent Vertex Caching of Progressive Meshes. Comput. Graph. Forum 21(2): 137-148 (2002) - [c23]Boris Kronrod, Craig Gotsman
Optimized Compression of Triangle Mesh Geometry Using Prediction Trees. 3DPVT 2002: 602-608 - [c22]Alexander Bogomjakov, Craig Gotsman:
AUTO-FOLLOW: getting a piece of the action all the time. SCG 2002: 279-280 - [c21]Vitaly Surazhsky, Craig Gotsman:
High Quality Compatible Triangulations. IMR 2002: 185-192 - [c20]Zachi Karni, Alexander Bogomjakov, Craig Gotsman:
Efficient Compression and Rendering of Multi-Resolution Meshes. IEEE Visualization 2002: 347-354 - [p2]Craig Gotsman, Stefan Gumhold, Leif Kobbelt:
Simplification and Compression of 3D Meshes. Tutorials on Multiresolution in Geometric Modelling 2002: 319-361 - 2001
- [j28]Craig Gotsman
Guaranteed intersection-free polygon morphing. Comput. Graph. 25(1): 67-75 (2001) - [j27]Ilya Eckstein, Vitaly Surazhsky, Craig Gotsman:
Texture Mapping with Hard Constraints. Comput. Graph. Forum 20(3): 95-104 (2001) - [j26]Boris Kronrod, Craig Gotsman
Efficient Coding of Nontriangular Mesh Connectivity. Graph. Model. 63(4): 263-275 (2001) - [j25]Daniel Keren, Margarita Osadchy, Craig Gotsman
Antifaces: A Novel, Fast Method for Image Detection. IEEE Trans. Pattern Anal. Mach. Intell. 23(7): 747-761 (2001) - [j24]Vitaly Surazhsky, Craig Gotsman
Controllable morphing of compatible planar triangulations. ACM Trans. Graph. 20(4): 203-231 (2001) - [c19]Martin Isenburg, Stefan Gumhold, Craig Gotsman:
The connectivity shapes video. SCG 2001: 325-326 - [c18]Zachi Karni, Craig Gotsman:
3D Mesh Compression Using Fixed Spectral Bases. Graphics Interface 2001: 1-8 - [c17]Alexander Bogomjakov, Craig Gotsman:
Universal Rendering Sequences for Transparent Vertex Caching of Progressive Meshes. Graphics Interface 2001: 81-90 - [c16]Vitaly Surazhsky, Craig Gotsman
Morphing Stick Figures Using Optimized Compatible Triangulations. PG 2001: 40-49 - [c15]Martin Isenburg, Stefan Gumhold, Craig Gotsman:
Connectivity Shapes. IEEE Visualization 2001: 135-142 - 2000
- [j23]Amit Reisman, Craig Gotsman
Interactive-Rate Animation Generation by Parallel Progressive Ray-Tracing on Distributed-Memory Machines. J. Parallel Distributed Comput. 60(9): 1074-1102 (2000) - [c14]Daniel Keren, Margarita Osadchy, Craig Gotsman
Anti-Faces for Detection. ECCV (1) 2000: 134-148 - [c13]Boris Kronrod, Craig Gotsman
Efficient Coding of Non-Triangular Mesh Connectivity. PG 2000: 235-242 - [c12]Boris Kronrod, Craig Gotsman
Optimized Triangle Mesh Compression using Prediction Trees. PG 2000: 406-407 - [c11]Zachi Karni, Craig Gotsman:
Spectral compression of mesh geometry. SIGGRAPH 2000: 279-286 - [i4]Boris Kronrod, Craig Gotsman:
Efficient Coding of Non-Triangular Meshes. EuroCG 2000: 24-26 - [i3]Zachi Karni, Craig Gotsman:
Spectral Compression of Mesh Geometry. EuroCG 2000: 27-30 - [i2]Vitaly Surazhsky, Craig Gotsman:
Morphing Planar Triangulations and Polygons using Convex Representations. EuroCG 2000: 31-34 - [i1]Ilya Eckstein, Vitaly Surazhsky, Craig Gotsman:
Compatible Geometries by Convex Representations with Applications to Computer Graphics. EuroCG 2000: 45-46
1990 – 1999
- 1999
- [j22]Craig Gotsman
Optimized occlusion culling using five-dimensional subdivision. Comput. Graph. 23(5): 645-654 (1999) - [j21]Guillermo Savransky, Dan Dimerman, Craig Gotsman
Modeling and Rendering Escher-Like Impossible Scenes. Comput. Graph. Forum 18(2): 173-179 (1999) - [j20]Daniel Keren, Craig Gotsman
Fitting Curves and Surfaces With Constrained Implicit Polynomials. IEEE Trans. Pattern Anal. Mach. Intell. 21(1): 31-41 (1999) - [j19]Nur Arad, Craig Gotsman
Enhancement by image-dependent warping. IEEE Trans. Image Process. 8(8): 1063-1074 (1999) - [j18]Oded Sudarsky, Craig Gotsman
Dynamic Scene Occlusion Culling. IEEE Trans. Vis. Comput. Graph. 5(1): 13-29 (1999) - [c10]Yohai Makbily, Craig Gotsman, Reuven Bar-Yehuda:
Geometric algorithms for message filtering in decentralized virtual environments. SI3D 1999: 39-46 - 1998
- [j17]Craig Gotsman, Daniel Keren:
Tight Fitting of Convex Polyhedral Shapes. Int. J. Shape Model. 4(3-4): 111-126 (1998) - [c9]Costa Touma, Craig Gotsman:
Triangle Mesh Compression. Graphics Interface 1998: 26-34 - 1997
- [j16]Irena Notkin, Craig Gotsman
Parallel Progressive Ray-tracing. Comput. Graph. Forum 16(1): 43-55 (1997) - [c8]Amit Reisman, Craig Gotsman
Parallel progressive rendering of animation sequences at interactive rates on distributed-memory machines. PRS 1997: 39-47 - [c7]Boris Rabinovich, Craig Gotsman:
Visualization of large terrains in resource-limited computing environments. IEEE Visualization 1997: 95-102 - [c6]Oded Sudarsky, Craig Gotsman:
Output-senstitive rendering and communication in dynamic virtual environments. VRST 1997: 217-223 - 1996
- [j15]Oded Sudarsky, Craig Gotsman
Output-Sensitive Visibility Algorithms for Dynamic Scenes with Applications to Virtual Reality. Comput. Graph. Forum 15(3): 249-258 (1996) - [j14]Craig Gotsman
On the metric properties of discrete space-filling curves. IEEE Trans. Image Process. 5(5): 794-797 (1996) - [j13]Reuven Bar-Yehuda, Craig Gotsman
Time/Space Tradeoffs for Polygon Mesh Rendering. ACM Trans. Graph. 15(2): 141-152 (1996) - [c5]Craig Gotsman, Jan P. Allebach:
Bounds and algorithms for dither screens. Human Vision and Electronic Imaging 1996: 483- - 1995
- [j12]Craig Gotsman
Euclidean Voronoi labelling on the multidimensional grid. Pattern Recognit. Lett. 16(4): 409-415 (1995) - [j11]Evgeny Roytman, Craig Gotsman
Dynamic Color Quantization of Video Sequences. IEEE Trans. Vis. Comput. Graph. 1(3): 274-286 (1995) - [j10]Gennady Agranov, Craig Gotsman
Algorithms for rendering realistic terrain image sequences and their parallel implementation. Vis. Comput. 11(9): 455-464 (1995) - [p1]Michael Margaliot, Craig Gotsman:
Approximation of Smooth Surfaces and Adaptive Sampling by Piecewise-linear Interpolants. Computer Graphics 1995: 17-27 - 1994
- [j9]Daniel Cohen, Craig Gotsman
Photorealistic terrain imaging and flight simulation. IEEE Computer Graphics and Applications 14(2): 10-12 (1994) - [j8]Craig Gotsman
Spectral Properties of Threshold Functions. Comb. 14(1): 35-50 (1994) - [j7]Alon Efrat, Craig Gotsman:
Subpixel image registration using circular fiducials. Int. J. Comput. Geom. Appl. 4(4): 403-422 (1994) - [c4]Craig Gotsman, Michael Lindenbaum:
On the metric properties of discrete space-filling curves. ICPR (3) 1994: 98-102 - [c3]Michael Margaliot, Craig Gotsman:
Piecewise-Linear Surface Approximation From Noisy Scattered Samples. IEEE Visualization 1994: 61-68 - 1993
- [j6]Craig Gotsman, Michael Werman:
Recognition of Affine Transformed Planar Curves by Extremal Geometric Properties. Int. J. Comput. Geom. Appl. 3(2): 183-202 (1993) - [j5]Craig Gotsman
On the most robust affine basis. Pattern Recognit. Lett. 14(8): 647-650 (1993) - [j4]Craig Gotsman
Halftoning of image sequences. Vis. Comput. 9(5): 255-266 (1993) - [c2]Alon Efrat, Craig Gotsman:
Subpixel Image Registration Using Circular Fiducials. ISTCS 1993: 49-58 - 1992
- [j3]Craig Gotsman, Nathan Linial:
The Equivalence of Two Problems on the Cube. J. Comb. Theory A 61(1): 142-146 (1992) - 1991
- [j2]Craig Gotsman
A cluster detection algorithm based on percolation theory. Pattern Recognit. Lett. 12(4): 199-202 (1991) - [j1]Craig Gotsman
A note on functions governed by Walsh expressions. IEEE Trans. Inf. Theory 37(3): 694-695 (1991)
1980 – 1989
- 1988
- [c1]Craig Gotsman, Eli Shamir, Daniel Lehmann:
Asynchronous dynamics of random Boolean networks. ICNN 1988: 1-7
Coauthor Index
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