Graphical Models is recognized internationally as a highly rated, top tier journal and is focused on the creation, geometric processing, animation, and visualization of graphical models and on their applications in engineering, science, culture, and entertainment. GMOD provides its readers with thoroughly reviewed and carefully selected papers that disseminate exciting innovations, that teach rigorous theoretical foundations, that propose robust and efficient solutions, or that describe ambitious systems or applications in a variety of topics. 

We invite papers in five categories: research (contributions of novel theoretical or practical approaches or solutions), survey (opinionated views of the state-of-the-art and challenges in a specific topic), system (the architecture and implementation details of an innovative architecture for a complete system that supports model/animation design, acquisition, analysis, visualization…), application (description of a novel application of know techniques and evaluation of its impact), or lecture (an elegant and inspiring perspective on previously published results that clarifies them and teaches them in a new way). 

GMOD offers its authors an accelerated review, feedback from experts in the field, immediate online publication of accepted papers, no restriction on color and length (when justified by the content) in the online version, and a broad promotion of published papers. A prestigious group of editors selected from among the premier international researchers in their fields oversees the review process. 

Because timely publication of research results is important for the careers of our authors and for the vitality of the field, GMOD is putting in place its R3 (Rapid Response Review) system, which strives to provide authors with a preliminary decision within an average of one month after submission. 

The following are examples of topics typically covered in GMOD: 

Shape Processing: Analysis of local properties. Averaging and relative convex hulls. Correspondence, registration, matching and retrieval. Detection of ridges, features, patterns, and symmetries. Measures of volume, compactness, or convexity. Morphological operations (offsetting, rounding, tightening). Segmentation. Similarity measures, comparison, variability statistics. 

Points: Analysis. Interpolation. Multi-resolution. Rendering. Segmentation. Separation. 

Curves: Parametric. Implicit. Fitting. Smoothing, Subdivision. Constant length. Extraction. Segmentation. Matching. Comparison. Averaging. Curves on surfaces. Rounding, Offsetting, Regularity. 

Skeletons: Animation and Skinning. Medial axis or curve skeleton (construction, approximation, properties) 

Meshes: Compact data structures. Feature extraction and replication. Feature exaggeration. Levels of Detail. Simplification. Shape measures. Parameterization. Re-sampling. Smoothing. Subdivision. Volume/area preservation. Feature sharpening. 

Surfaces: Implicit. Parametric. Curvature. Hole filling. Geodesics. Intersection. Interpolating. Reconstruction. Sampling. 

Solids: Boolean operations. Boundary representations. CSG. BSP. Non-manifold models. Inhomogeneous models. Non-manifold models and complexes. Offsets. Reconstruction from drawings, images, videos. Repair. Rounding and smoothing. Sweeps. 

Volumes/Images/Video: Matching. Searching. Filtering. Compression. Segmentation. Stitching. Merging. In-painting. Isosurfaces. Rendering. 

Design: Constraint-based. Feature-based. Variational. Direct manipulation. Haptics. Multimodal interfaces. Multiuser interfaces. Pen-based Procedural models and patterns.

Motion: Rigid, affine, steady. Analysis. Capture. Pattern extraction. Synthesis. Constrained. Blending. 

Morphing: Curves. Graphs. Images. Volumes. Meshes. Solids. Surfaces. In-betweening. 

Deformation: Capture/acquisition. Direct manipulation. Free-form,. Image/volume warping. Interpolating meshes. Preservation of local details. 

Animation: Design. Evaluation. Behavioral. Retargeting. Data driven. Humans. Animals. Face. Hand. Gate. Swimming. Constrained. Preserving volume, area, or length. Optimization. 

Simulation: Collision and friction. Articulated and flexible shapes. Physically based behavior. Cloth. Crowds and flocks. Deposition, erosion, and biological growth. Fluid. Hair. Viscoelastic deformations. Sound. 

Rendering: Illustrative (non-photorealistic). Image-based. Artistic. Global Illumination. Occlusion. Perception. Perspective. Acceleration of radiosity./raytracing. Reflectance and Shading Models. Relighting. Silhouettes. Shadows. Texture Mapping. Visibility. 

Hardware Acceleration: Collision and visibility queries. Frame buffer algorithms. GPUs and parallelization. Model Acquisition and Scanning. Ray Casting/Tracing Hardware. 

Model Dissemination: Shared models. Collaborative access. Geometry compression. Progressive/selective refinements. Streaming scenes and animations. Watermarking. 

Tool: Artificial intelligence. Computational geometry. Data structures. Differential geometry. Genetic algorithms. Linear algebra . Machine learning. Mathematical morphology. Numerical accuracy. Numerical analysis. Optimization. Signal Processing. Topology. Wavelets. 

Application: Manufacturing. Robotics. Architecture and urban simulation. Medicine. Biology. Natural phenomena. Cinema. Videogames. Education. Cultural Heritage. Typography. Scientific Computing.

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Editor-in-Chief
Jorg Peters
University of Florida, Gainesville, Florida, United States
Associate Editors
Daniel Aliaga
Purdue University, West Lafayette, Indiana, United States Urban modeling and visualization, procedural modeling, inverse procedural modeling, radiometric compensation, 3D reconstruction, and camera design and calibration.
Hujun Bao
Zhejiang University, Hangzhou, China Shape modeling/editing, realtime rendering, structure from motion, video segmentation and camera-based interaction. Virtual reality. Camera tracking.
Loic Barthe, PhD
Paul Sabatier University, Toulouse, France Sketching, Point-based modeling. Splatting. Subdivision surfaces. Implicit modeling. Voxelization. CSG. Blending. Shadows.
Michael Barton
Basque Center for Applied Mathematics, Bilbao, Spain CNC machining. Curve/surface modeling. Kinematic geometry. Numerical integration. Rationalization.
David Bommes, PhD
University of Bern, Bern, Switzerland Geometry Processing, Mesh Generation, Differential Geometry, Numerical Optimization
Mario Botsch
Bielefeld University, Bielefeld, Germany Mesh Optimization, Shape Deformation, Non-rigid Registration
Frederic Chazal
Inria DataShape, Palaiseau, France http://www-sop.inria.fr/geometrica/index.php?option=com_content&view=article&id=55Applied and computational topology and geometry. Solid modeling foundations. Topological and geometric data analysis. Metric and differential geometry. Statistical and probabilistic approaches in geometric inference, geometric approximation and geometry processing. Clustering. Segmentation. Matching.
Leila De Floriani
University of Maryland at College Park, Baltimore, Maryland, United Stateshttp://www.disi.unige.it/person/DeflorianiL/Triangle meshes. Data structures. Shape segmentation. Morse complexes. Non-manifold representations. Multi-resolution modeling. Terrains. Feature extraction.
Sven Dickinson
University of Toronto, Toronto, Ontario, Canada http://www.cs.toronto.edu/~sven/Object recognition. Shape representation, segmentation, indexing, matching, and tracking. Image abstraction. Perceptual grouping.
Julie Digne
LIRIS - Computer Science Laboratory for Image Processing and Information Systemshttp://perso.liris.cnrs.fr/julie.digne/surface processing: point clouds, denoising, meshing, scan merging and surface segmentation.
Xianfeng David Gu
Stony Brook University, Stony Brook, New York, United Stateshttp://www.cs.sunysb.edu/~gu/Shape parameterization, registration, analysis. Splines. Conformal, discrete differential, and Riemannian geometry. Medical imaging: Brain colon.
Xiaohu Guo
University of Texas at Dallas, Richardson, Texas, United Stateshttp://www.utdallas.edu/~xguo/Deformations. Physical and mesh-less simulation. Compression, streaming. Point-based modeling. GUP support. Registration. Medical apps.
Klaus Hildebrandt
TU Delft, Delft, The Netherlands http://graphics.tudelft.nl/~klaus//Geometric Modeling, Geometry Processing, Computer Graphics
Tao Ju
Washington University in Saint Louis, Saint Louis, Missouri, United Stateshttp://www1.cse.wustl.edu/~taoju/Geometry reconstruction, repair, analysis. Barycentric coordinates. Implicit surfaces. Fractals. Interaction techniques. Biomed applications.
David Levin
University of Toronto, Toronto, Ontario, Canadahttp://diwlevin.webfactional.com/researchdb/#research. /
Andre Lieutier
Solid modeling. Topology. Boolean operations. Sweeps. Minkowski sums. Blending. Numeric accuracy. Computational Geometry.
M. Gopi Meenakshisundaram
University of California Irvine, Irvine, California, United Stateshttp://www.ics.uci.edu/~gopi/Mesh stripification and compression. Surface sampling, approximation, reconstruction. Sketching. Boolean evaluation. Rendering splines.
Dinesh Pai
The University of British Columbia, Vancouver, British Columbia, Canadahttp://people.cs.ubc.ca/~pai/Sensing and control of movements. Simulation of tendons and muscles. Contact and friction. Human eye. Rat/frog locomotion.
Sylvain Petitjean
Inria Research Centre Nancy Grand Est, Villers les Nancy, Francehttp://www.loria.fr/~petitjea/Computational Geometry. Geometric computing. Exact computations for low-degree curved objects. Invariant theory. Intersections of quadrics. Geometric predicates. 3D visibility. Line theory.
Konrad Polthier
Free University Berlin Department of Mathematics and Computer Science, Berlin, Germany http://page.mi.fu-berlin.de/polthier/Mesh representation and compression. Shape optimization. Animation compression. Multilevel PDEs. Differential and discrete geometry. Implicit surfaces. Mesh parameterization. Remeshing. Noise removal.
Helmut Pottmann
TU Wien University, Wien, Austria http://www.geometrie.tuwien.ac.at/pottmann/Surface design and analysis. Curvature. Developable, minimal surfaces. Regular patterns. Offsets. Robust geometry processing. Laguerre surfaces. Collisions. Kinematic geometry. Application to architecture. Shape space. Registration. Feature recognition.
Hong Qin
Stony Brook University, Stony Brook, New York, United Stateshttp://www.cs.sunysb.edu/~qin/Physically-based modeling of curves, surfaces, and solids. Splines. FEM. PDE. Graphic interaction and Virtual environments.
Hanan Samet
University of Maryland at College Park, Baltimore, Maryland, United Stateshttp://www.cs.umd.edu/~hjs/Data structures. Nearest neighbor. Clustering, Web interface for medical diagnosis. Image similarity.
Pedro Sander
Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Konghttp://www.cse.ust.hk/~psander/Geometry Processing. LOD. Silhouettes. Super-sampling. Mesh traversal. Realtime rendering. GPU. NPR of videos and animations.
Scott Schaefer
Texas A&M University College Station, College Station, Texas, United Stateshttp://faculty.cs.tamu.edu/schaefer/CAGD, subdivision surfaces, barycentric coordinates, surface reconstruction, implicit modeling, surface deformation.
Ariel Shamir
Interdisciplinary Center Herzliya, Herzliya, Israel http://www.faculty.idc.ac.il/arik/Geometric Modeling, Shape Analysis, Image Processing, Fabrications and 3D Printing, Visualization, Interactive Design, Sketch Based Design, Machine Learning
Vadim Shapiro
University of Wisconsin Madison, Madison, Wisconsin, United Stateshttp://homepages.cae.wisc.edu/~vshapiro/Constructive, generative, and parametric modeling. Topological and boundary representations. Tolerances and tolerant modeling. Physical modeling and simulations. Computational design and analysis.
Kenji Shimada
Carnegie Mellon University, Pittsburgh, Pennsylvania, United Stateshttp://www.andrew.cmu.edu/user/shimada/FE Mesh generation. Geometric modeling. Computational geometry. Computer graphics. Factory robotics. Computer assisted surgery. Human body modeling and simulation.
Georg Umlauf
University of Konstanz http://www-home.htwg-konstanz.de/~umlauf/	Subdivision algorithms. 3D reconstruction. Meshes. G-Spline surfaces.
Remco Veltkamp
Utrecht University, Utrecht, Netherlands http://people.cs.uu.nl/remcov/Shape analysis. Object recognition. Shape retrieval. Shape matching. 3D face modeling and recognition. Object and scene reconstruction.
Michael Wand
Max Planck Institute for Computer Science Department 4 Computer Graphics, Saarbrücken, Germany http://www.mpi-inf.mpg.de/~mwand/Statistical/machine learning/computer vision approaches to geometry processing: Correspondence problems, shape matching, symmetry for shape analysis, inverse procedural modeling, processing of dynamic (animated) geometry, large scene processing and rendering.
Yücel Yemez
Koc University, İstanbul, Turkey http://home.ku.edu.tr/~yyemez/Reconstruction from stereo, video, or silhouettes. 3D digitization. Optical triangulation. Mesh tracking, deformation, and analysis of evolution. 3D object retrieval, Shape description, matching, correspondence. Motion capture. Signal processing. Speech-driven face animation. Body motion analysis and synthesis. Music-driven dance analysis and choreography synthesis. Biometrics.
Sung-Eui Yoon
Korea Advanced Institute of Science and Technology, Daejeon, Korea, Republic ofhttp://sglab.kaist.ac.kr/~sungeui/Monte Carlo Rendering, Image Search, Motion Planning, Nearest Neighbor Search, Large-scale Computation, Collision Detection
Eugene Zhang
Oregon State University, Corvallis, Oregon, United Stateshttp://web.engr.oregonstate.edu/~zhange/ Tensor field visualization. Vector and tensor field design and processing. Non-photorealistic rendering. Computational geometry and topology. Surface parameterization. Remeshing. Shape analysis. Symmetry processing.
Denis Zorin
New York University, New York, New York, United Stateshttp://mrl.nyu.edu/~dzorin/Geometric modeling: subdivision surfaces, variational modeling, manifold constructions, interactive and appearance based modeling, discretization of geometric quantities. Scientific computing: Fast multipole methods, numerical solution of integral equations, fluid and deformable membrane simulation, parallel algorithms and software tools.
Editorial Advisory Board
Pierre Alliez
Inria Sophia Antipolis Mediterranean Research Centre, Sophia Antipolis, Francehttp://www-sop.inria.fr/members/Pierre.Alliez/Mesh generation and parameterization. Geometry compression. Shape reconstruction and approximation. Surface remeshing.
Chandrajit Bajaj
University of Texas at Austin, Austin, Texas, United Stateshttp://userweb.cs.utexas.edu/~bajaj/Computational biology. Geometric modeling. Image processing. Computational geometry. Graphics. Compression. Mesh generation. Sci. Computing. Visualization.
Pere Brunet
Polytechnic University of Catalonia, Barcelona, Spainhttp://www.lsi.upc.edu/~pere/Geometry processing. Volume and discrete representations. Computer-aided geometric design. Hierarchical data representations. Geometric algorithm. Interaction and virtual reality.
Elaine Cohen
The University of Utah, Salt Lake City, Utah, United Stateshttp://www.cs.utah.edu/~cohen/Algorithms, Representations, and Operators for Complex Models. Design of Mechanical Parts. Virtual Prototyping and Haptic. Rapid Prototyping. Layered Fabrication. Reverse Engineering and Data Fitting. Integrated Process Planning and Computer Aided Manufacturing.
Bianca Falcidieno, PhD
Institute of Applied Mathematics and Information Technologies Enrico Magenes National Research Council Genoa Branch, Genova, Italy Shape modeling, analysis, segmentation, semantics, classification, similarity, matching, comparison, and retrieval. Computational topology. Reeb graphs. Multirsolution modeling. Feature-based modeling. Applications to CAD, gaming, biometrics, medicine, biology, culture.
Jessica Hodgins
Carnegie Mellon University, Pittsburgh, Pennsylvania, United Stateshttp://www.cs.cmu.edu/~jkh/
Christoph Hoffmann
Purdue University, West Lafayette, Indiana, United Stateshttp://www.cs.purdue.edu/homes/cmh/Geometric computing and applications. Computer-Aided Design. Design system architectures. Geometric constraint. Robust geometric and symbolic computation.
Peter Lindstrom
Lawrence Livermore National Laboratory, Livermore, California, United Stateshttp://people.llnl.gov/plMesh simplification and compression, multi-resolution methods, geometric modeling, and large-data visualization.
Nadia Magnenat-Thalmann
Université de Genève, MIRALab, Carouge / Genève, Switzerlandhttp://www.miralab.ch/nthalmannDeformations. Haptic interaction. Physics-based simulation. Motion retargeting. Medical image segmentation. Animation of virtual humans, faces, hair, articulations. Clothes. Social robot behavior. Modeling memory processes and emotions.
Dinesh Manocha
North Carolina Agricultural and Technical State University Department of Computer Science, Chapel Hill, North Carolina, United States http://www.cs.unc.edu/~dm/Collision detection. Crowd simulation. GPU. Parallelization. Haptics. Motion and path planning. Sound. Rendering acceleration for massive models. Hair. Deformable models. Growth simulation. Simulation of articulated bodies. Multiresolution.
Nicholas Patrikalakis
Massachusetts Institute of Technology, Cambridge, Massachusetts, United Stateshttp://meche.mit.edu/people/faculty/index.html?id=67Robotics and Sensing, Dynamic Data-Driven Forecasting Systems, Computer-Aided Design, Computational Geometry, Visualization.
Jarek Rossignac
Georgia Institute of Technology, Atlanta, Georgia, United Stateshttp://www.gvu.gatech.edu/~jarek/Solid modeling using CSG and B-reps. Compact representations, compression, multi-resolution processing of triangle meshes. Offsetting. Blending. Morphing. Topology. Morphology. In-betweening animations. Interactive deformations. Sweeps. Skinning. Subdivision of shapes and motions. Fluid simulations. Reconstruction. Segmentation. Feature sharpening. Smoothing. GPU rendering. Visibility.
Hans-Peter Seidel
Max Planck Institute for Computer Science Department 4 Computer Graphics, Saarbrücken, Germany http://www.mpi-inf.mpg.de/~hpseidel/Tracking high-speed motion. Viscoelastic solids. Vector fields. Mesh metamorphosis. Reconstruction from voxels. Remeshing.
Carlo Séquin
University of California Berkeley, Berkeley, California, United Stateshttp://www.eecs.berkeley.edu/~sequin/Geometric modeling: subdivision surfaces, surface optimization, Euler spirals. Procedural modeling: inverse 3D modeling, parameterized generator programs. Art and Mathematics: geometrical sculpture, tilings (2D and 3D), polyhedra (3D and 4D). Visualization: virtual prototyping, mathematical visualization models, architecture. CAD-CAM: interactive modeling, user interfaces, rapid prototyping.
Harry Shum
Microsoft Research Asia, Beijing, China http://research.microsoft.com/en-us/people/hshum/Super resolution, computer vision, graphics, human computer interaction, statistical learning and robotics. Image completion. Graph cuts. Interactive manipulation of faces. Stereo reconstruction.
Editors Emeriti
Norman Badler
University of Pennsylvania Department of Computer and Information Science, Philadelphia, Pennsylvania, United States http://www.cis.upenn.edu/~badler/
Ingrid Carlbom
Uppsala University, Uppsala, Sweden http://www.cb.uu.se/~ingrid/