Radial Basis Functions Applied to Integral Interpolation, Piecewise Surface Reconstruction and Animation Control

Langton, Michael Keith

January 2009

This thesis describes theory and algorithms for use with Radial Basis Functions (RBFs), emphasising techniques motivated by three particular application areas. In Part I, we apply RBFs to the problem of interpolating to integral data. While the potential of using RBFs for this purpose has been established in an abstract theoretical context, their use has been lacking an easy to check sufficient condition for finding appropriate parent basic functions, and explicit methods for deriving integral basic functions from them. We present both these components here, as well as explicit formulations for line segments in two dimensions and balls in three and five dimensions. We also apply these results to real-world track data. In Part II, we apply Hermite and pointwise RBFs to the problem of surface reconstruction. RBFs are used for this purpose by representing the surface implicitly as the zero level set of a function in 3D space. We develop a multilevel piecewise technique based on scattered spherical subdomains, which requires the creation of algorithms for constructing sphere coverings with desirable properties and for blending smoothly between levels. The surface reconstruction method we develop scales very well to large datasets and is very amenable to parallelisation, while retaining global-approximation-like features such as hole filling. Our serial implementation can build an implicit surface representation which interpolates at over 42 million points in around 45 minutes. In Part III, we apply RBFs to the problem of animation control in the area of motion synthesis---controlling an animated character whose motion is entirely the result of simulated physics. While the simulation is quite well understood, controlling the character by means of forces produced by virtual actuators or muscles remains a very difficult challenge. Here, we investigate the possibility of speeding up the optimisation process underlying most animation control methods by approximating the physics simulator with RBFs.

Radial Basis Functions

RBFs

Approximation

Integral Interpolation

Surface Reconstruction

Surface Fitting

Hermite RBFs

Piecewise RBFs

Piecewise Approximation

Hole Filling

Animation Control

Motion Synthesis

Control of physics-based fluid animation using a velocity-matching method

Kim, Yootai

27 September 2006

No description available.

Computer Science

computer graphics

computer animation

fluid animation

physics based animation

fluid simulation

smoke simulation

smoke animation

fluid animation control

path based flow control

linear feedback control

velocity matching

natural phenomena