Space-time sculpting of liquid animation

International audienceWe propose an interactive sculpting system for seamlessly editing pre-computed animations of liquid, without the need for any re-simulation. The input is a sequence of meshes without correspondences representing the liquid surface over time. Our method enables the efficient selection of consistent space-time parts of this animation, such as moving waves or droplets, which we call space-time features. Once selected, a feature can be copied, edited, or duplicated and then pasted back anywhere in space and time in the same or in another liquid animation sequence. Our method circumvents tedious user interactions by automatically computing the spatial and temporal ranges of the selected feature. We also provide space-time shape editing tools for non-uniform scaling, rotation, trajectory changes, and temporal editing to locally speed up or slow down motion. Using our tools, the user can edit and progressively refine any input simulation result, possibly using a library of pre-computed space-time features extracted from other animations. In contrast to the trial-and-error loop usually required to edit animation results through the tuning of indirect simulation parameters, our method gives the user full control over the edited space-time behaviors

MaxControl: ein objektorientiertes Werkzeug zur automatischen Erstellung von 3D-Computeranimationsfilmen und dessen Integration in eine professionelle 3D-Animationssoftware

Durch die wachsende Computerleistung können 3D-Computeranimationen sehr komplexe Szenen mit ebenso komplexen zeitlichen Abläufen animiert darstellen. Jedoch ist neben der Erstellung einer komplexen Szene auch deren Animation entsprechend aufwendig, wenn keine Automatisierungen genutzt werden können. Das in dieser Arbeit entwickelte Werkzeug MaxControl ist ein System zur automatischen Animation von nicht-interaktiven 3D-Animationsfilmen. Dies wird durch die Simulation von Verhaltensweisen erreicht, die den 3D-Objekten zugewiesen werden

Modeling and Animating Gases with Simulation Features Abstract

In modeling natural phenomena, artists often compromise the benefits of direct control for the visual realism of physics-based simulation. For gases, Eulerian simulations traditionally provide realistic results, but a poor representation for artistically shaping the media. In our system, users work with a more intuitive set of continuously extracted features whose manipulation feeds back into the original simulation. This novel approach overcomes common control issues by providing modeling tools to manipulate high-level behavior in Eulerian simulations. We employ techniques in feature extraction, real-time gas simulation, and volume rendering to build an interactive system to sculpt three-dimensional flows