Presentation is loading. Please wait.

Presentation is loading. Please wait.

1cs426-winter-2008 Notes. 2 Velocity fields  Velocity field could be a combination of pre-designed velocity elements E.g. explosions, vortices, …  Or.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "1cs426-winter-2008 Notes. 2 Velocity fields  Velocity field could be a combination of pre-designed velocity elements E.g. explosions, vortices, …  Or."— Presentation transcript:

1 1cs426-winter-2008 Notes

2 2 Velocity fields  Velocity field could be a combination of pre-designed velocity elements E.g. explosions, vortices, …  Or from “noise” (or “Perlin noise”) Smooth random number field Essentially a Hermite spline from a pseudo- random hash  Or from a simulation Interpolate velocity from a computed grid E.g. smoke simulation

3 3cs426-winter-2008 Time integration woes  For rotational motion, immediately find serious flaw with Forward Euler: instability  Better off using a more accurate, more stable Runge-Kutta method For example: 3rd order

4 4cs426-winter-2008 Second order motion  Real particles move due to forces Newton’s law F=ma Need to specify force F (gravity, collisions, …) Divide by particle mass to get acceleration a Update velocity v by acceleration Update position x by velocity

5 5cs426-winter-2008 Basic rendering  Draw a dot for each particle  But what do you do with several particles per pixel? Add: models each point emitting (but not absorbing) light -- good for sparks, fire, … More generally, compute depth order, do alpha- compositing (and worry about shadows etc.) Can fit into Reyes very easily  Anti-aliasing Blur edges of particle, make sure blurred to cover at least a pixel  Particle with radius: kernel function

6 6cs426-winter-2008 Motion blur  One case where you can actually do exact solution instead of sampling  Really easy for simple particles Instead of a dot, draw a line (from old position to new position - the shutter time) May involve decrease in alpha More accurately, draw a spline curve May need to take into account radius as well…

7 7cs426-winter-2008 More detailed particle rendering  Stick a texture (or even a little movie) on each particle: “sprites” or “billboards” E.g. a noise function E.g. a video of real flames  Draw a little object for each particle Need to keep track of orientation as well, unless spherical We’ll get into full-fledged rigid bodies later  Draw between particles curve (hair), surface (cloth)  Implicit surface wrapped around virtual particles (e.g. water)

Download ppt "1cs426-winter-2008 Notes. 2 Velocity fields  Velocity field could be a combination of pre-designed velocity elements E.g. explosions, vortices, …  Or."

Similar presentations

Exploration of advanced lighting and shading techniques

Exploration of advanced lighting and shading techniques
Ray tracing. New Concepts The recursive ray tracing algorithm Generating eye rays Non Real-time rendering.

Ray tracing. New Concepts The recursive ray tracing algorithm Generating eye rays Non Real-time rendering.
1cs533d-winter-2005 Notes  Assignment 1 is not out yet :-)  courses/533d-winter-2005.

1cs533d-winter-2005 Notes  Assignment 1 is not out yet :-)  courses/533d-winter-2005.
Blender Particle Fluids. Blender Particle Fluids integrate into the existent powerful Blender particle system a fluid simulation tool that allows a wide.

Blender Particle Fluids. Blender Particle Fluids integrate into the existent powerful Blender particle system a fluid simulation tool that allows a wide.
1cs533d-term1-2005 Notes  For using Pixie (the renderer) make sure you type “use pixie” first  Assignment 1 questions?

1cs533d-term Notes  For using Pixie (the renderer) make sure you type “use pixie” first  Assignment 1 questions?
1Notes. 2 Building implicit surfaces  Simplest examples: a plane, a sphere  Can do unions and intersections with min and max  This works great for.

1Notes. 2 Building implicit surfaces  Simplest examples: a plane, a sphere  Can do unions and intersections with min and max  This works great for.
1cs533d-winter-2005 Computer Animation Robert Bridson (preview of CPSC 426)

1cs533d-winter-2005 Computer Animation Robert Bridson (preview of CPSC 426)
1Notes  Textbook: matchmove 6.7.2, B.9. 2 Match Move  For combining CG effects with real footage, need to match synthetic camera to real camera: “matchmove”

1Notes  Textbook: matchmove 6.7.2, B.9. 2 Match Move  For combining CG effects with real footage, need to match synthetic camera to real camera: “matchmove”
1Notes  Text:  Motion Blur A.3  Particle systems 4.5 (and 4.4.1, 6.6.2…)  Implicit Surfaces - 4.6  Classic particle system papers  W. Reeves, “Particle.

1Notes  Text:  Motion Blur A.3  Particle systems 4.5 (and 4.4.1, 6.6.2…)  Implicit Surfaces  Classic particle system papers  W. Reeves, “Particle.
MAT 594CM S10Fundamentals of Spatial ComputingAngus Forbes Week 2 : Dynamics & Numerical Methods Goal : To write a simple physics simulation Topics: Intro.

MAT 594CM S10Fundamentals of Spatial ComputingAngus Forbes Week 2 : Dynamics & Numerical Methods Goal : To write a simple physics simulation Topics: Intro.
Particle Systems 1 Adapted from: E. Angel and D. Shreiner: Interactive Computer Graphics 6E © Addison-Wesley 2012.

Particle Systems 1 Adapted from: E. Angel and D. Shreiner: Interactive Computer Graphics 6E © Addison-Wesley 2012.
Particle Systems and Fuzzy Shapes Presented by Dan Cogswell.

Particle Systems and Fuzzy Shapes Presented by Dan Cogswell.
Foundations of Computer Graphics (Spring 2010) CS 184, Lecture 24: Animation Many slides courtesy Adam Finkelstein,

Foundations of Computer Graphics (Spring 2010) CS 184, Lecture 24: Animation Many slides courtesy Adam Finkelstein,
CSCE 441 Computer Graphics: Keyframe Animation/Smooth Curves Jinxiang Chai.

CSCE 441 Computer Graphics: Keyframe Animation/Smooth Curves Jinxiang Chai.
1 7M836 Animation & Rendering Animation Jakob Beetz Joran Jessurun

1 7M836 Animation & Rendering Animation Jakob Beetz Joran Jessurun
1cs426-winter-2008 Notes  If you’re interested, read Bridson, Hourihan, Nordenstam, “Curl noise for procedural fluid flow”, SIGGRAPH ‘07.

1cs426-winter-2008 Notes  If you’re interested, read Bridson, Hourihan, Nordenstam, “Curl noise for procedural fluid flow”, SIGGRAPH ‘07.
Game Physics Chris Miles. The Goal To learn how to create game objects with realistic physics models To learn how to simulate aspects of reality in order.

Game Physics Chris Miles. The Goal To learn how to create game objects with realistic physics models To learn how to simulate aspects of reality in order.
1cs426-winter-2008 Notes  Course project: Will be due at the end of the term You can do it in pairs Create an animation that combines an algorithm for.

1cs426-winter-2008 Notes  Course project: Will be due at the end of the term You can do it in pairs Create an animation that combines an algorithm for.
Cloth Simulation CSE169: Computer Animation Instructor: Steve Rotenberg UCSD, Winter 2005.

Cloth Simulation CSE169: Computer Animation Instructor: Steve Rotenberg UCSD, Winter 2005.
Modeling Fluid Phenomena -Vinay Bondhugula (25 th & 27 th April 2006)

Modeling Fluid Phenomena -Vinay Bondhugula (25 th & 27 th April 2006)

Similar presentations

Ads by Google