Dan Julius
University of British Columbia
8 Papers
146 Citations
Dan Julius is an academic researcher from University of British Columbia. The author has contributed to research in topics: Shearing (physics) & Stiffness. The author has an hindex of 7, co-authored 8 publications.
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Papers
Virtual Garments: A Fully Geometric Approach for Clothing Design
Philippe Decaudin,Dan Julius,Jamie Wither,Laurence Boissieux,Alla Sheffer,Marie-Paule Cani +5 more
- 01 Sep 2006
TL;DR: Modeling dressed characters is known as a very tedious process, it usually requires specifying 2D fabric patterns, positioning and assembling the min 3D, and then performing a physically‐based simulation.
Model Composition from Interchangeable Components
V. Kreavoy,Dan Julius,Alla Sheffer +2 more
- 29 Oct 2007
TL;DR: This work develops a method for computing a compatible segmentation of input models into meaningful, interchangeable components and demonstrates that the shuffling paradigm allows for easy and fast creation of a rich geometric content.
125
Material-Aware Mesh Deformations.
Tiberiu Popa,Dan Julius,Alla Sheffer +2 more
- 01 Jan 2006
TL;DR: In this paper, the distribution of the bending and shearing across the model according to the local material stiffness is controlled by an intuitive paint-like interface or it can be learned from a sequence of sample deformations.
29
Material aware mesh deformations
Tiberiu Popa,Dan Julius,Alla Sheffer +2 more
- 31 Jul 2005
TL;DR: This paper proposes a new approach to model deformation that incorporates non-uniform materials into the geometric deformation framework and provides a simple and intuitive method to control the distribution of the bending and shearing throughout the model according to the local material stiffness.
Interactive and linear material aware deformations
TL;DR: This paper proposes a new approach to model deformation that incorporates nonuniform materials into the geometric deformation framework and provides a simple and intuitive method to control the distribution of the bending and shearing throughout the model according to the local material stiffness.