cSculpt: a system for collaborative sculpting

Collaborative systems are well established solutions for sharing work among people. In computer graphics these workflows are still not well established, compared to what is done for text writing or software development. Usually artists work alone and share their final models by sending files. In this paper we present a system for collaborative 3D digital sculpting. In our prototype, multiple artists concurrently sculpt a polygonal mesh on their local machines by changing its vertex properties, such as positions and material BRDFs. Our system shares the artists' edits automatically and seamlessly merges these edits even when they happen on the same region of the surface. We propose a merge algorithm that is fast-enough for seamless collaboration, respects users' edits as much as possible, can support any sculpting operation, and works for both geometry and appearance modifications. Since in sculpting artists alternatively perform fine adjustments and large scale modifications, our algorithm is based on a multiresolution edit representation that handles concurrent overlapping edits at different scales. We tested our algorithm by modeling meshes collaboratively in different sculpting sessions and found that our algorithm outperforms prior works on collaborative mesh editing in all cases.

[1]  Kei Iwasaki,et al.  Real‐time Rendering of Dynamic Scenes under All‐frequency Lighting using Integral Spherical Gaussian , 2012, Comput. Graph. Forum.

[2]  Davide Eynard,et al.  Shape‐from‐Operator: Recovering Shapes from Intrinsic Operators , 2015, Comput. Graph. Forum.

[3]  Daniel Cohen-Or,et al.  Linear rotation-invariant coordinates for meshes , 2005, ACM Trans. Graph..

[4]  Christian Santoni,et al.  MeshHisto: collaborative modeling by sharing and retargeting editing histories , 2015, ACM Trans. Graph..

[5]  Fabio Pellacini,et al.  AppIm , 2014, ACM Trans. Graph..

[6]  Anthony Steed,et al.  3D diff: an interactive approach to mesh differencing and conflict resolution , 2012, SIGGRAPH Talks.

[7]  David P. Dobkin,et al.  Multiresolution mesh morphing , 1999, SIGGRAPH.

[8]  Xin Huang,et al.  A GPU based interactive modeling approach to designing fine level features , 2007, GI '07.

[9]  Marc Alexa,et al.  Differential coordinates for local mesh morphing and deformation , 2003, The Visual Computer.

[10]  Geoff Wyvill,et al.  Sweepers: Swept deformation defined by gesture , 2006, Graph. Model..

[11]  Rynson W. H. Lau,et al.  Collaborative distributed virtual sculpting , 2001, Proceedings IEEE Virtual Reality 2001.

[12]  Jirí Zára,et al.  Geometric skinning with approximate dual quaternion blending , 2008, TOGS.

[13]  Fabio Pellacini,et al.  MeshGit: diffing and merging meshes for polygonal modeling , 2013, ACM Trans. Graph..

[14]  Fabio Pellacini,et al.  3DFlow , 2015, ACM Trans. Graph..

[15]  Tony DeRose,et al.  Mesh optimization , 1993, SIGGRAPH.

[16]  Jaroslav Krivánek,et al.  Real-time shading with filtered importance sampling , 2007, SIGGRAPH '07.

[17]  Christian Rössl,et al.  Laplacian surface editing , 2004, SGP '04.

[18]  Andrei Khodakovsky,et al.  Progressive geometry compression , 2000, SIGGRAPH.

[19]  Xiaohu Guo,et al.  Spectral mesh deformation , 2008, The Visual Computer.

[20]  Hans-Peter Seidel,et al.  Vector field based shape deformations , 2006, ACM Trans. Graph..