Presentation Transcript

1. Howtomake a PIXAR movie

   Global Illumination Effects
2. Motivation Realisticilluminationofthescene
3. Motivation Soft shadows
4. Motivation Subsurfacescattering
5. Motivation Manyalgorithmsexist Photon mapping AmbientOcclusion … Common goal: Solvingpartsofthe Rendering Equation
6. Problems Scene changes -> New computation Still not possible in real-time UsesRaytracingorRadiosity Alreadyexplained Goingtobeexplainednow
7. Photons Haveenergy h: Planck constant v: Frequencyoflight
8. RadiometricQuantities
9. Radiance θ: angle betweensurface‘s normal andω cosθ: Lambertianlaw Constant along a ray
10. Irradiance
11. BRDF Bidirectionalreflectancedistributionfunction Howmuchlightisreflected
12. ReflectionEquation Integrateoverthehemisphere
13. Rendering Equation Radiance BRDF Geometryfactor Visibility Emittedlight Surfaces
14. Radiosity Ideal diffuse reflectioncanbesimulatedwithRadiosity Uses finite elements IntroducedbyGoral et al.
15. Radiosity Origin: Thermal heattransfer Developed in 1984, still in use Modellingof diffuse lighting Doesn‘taccountforspecularlighting Independent ofviewer Therefore: Staysconstant in constantscene
16. RadiosityEquation constant Emissivity Radiosity Reflectivity Form factor
17. Form Factors
18. Form Factors
19. Nusselt Analog Simple geometric analog forcalculating form factors B A
20. HemicubeAlgorithm Hemicubeinsteadofhemisphere
21. HemicubeAlgorithm Idea: Precomputedelta form factorsanalytically Count coveredpixels Sumupcovereddelta form factorstothetrue form factor
22. HemicubeExample
23. HemicubeAlgorithm on GPU Useprojectioncenterasviewport Usecurrentfaceasviewing plane Do therendering Grab thecolourbuffer (IDs ofpatches) Count colouredpixels Visibilitytestperformedbydepthtest
24. RadiosityAlgorithm Compute form factors Solve linear equationsystem for i = 1, … , n
25. Von Neumann Series 0 Bounces 1 Bounce 2 Bounces 3 Bounces
26. Jacobi Iteration
27. Shooting / Gathering
28. RadiosityResult
29. Radiosity vs. Ray Tracing
30. RadiosityConclusion Old, but still in use Usedforsimulating diffuse lighting Resultcanbeused in combinationwithother GI algorithms
31. AmbientOcclusion Motivation Ambienttermconstant in Phong model Not veryrealistic Idea: Computeocclusionofeachface
32. AmbientOcclusion Result: Occludedareasappeardarkerthanbrigtherones MultiplywithusualPhong model 2 possibilities: Screen space Objectspace
33. Screen Space AmbientOcclusion Can becompletelydone on GPU Nopreprocessing Independent ofscenecomplexity Idea: Insteadofperformingfullraytracinguseocclusioninformationfrom z-buffer
34. Screen Space AmbientOcclusion Take 3D samplesaroundeachpoint Determineocclusionofeachpointbytestingagainstthedepthbuffer Farsampleswithlessinfluence Useblurringfor smooth results
35. Screen Space AmbientOcclusion
36. Object Space AmbientOcclusion Definesurfaceelementas an orienteddisk UseHeron‘sformula , Store position, normal andarea in textureforpixelshader
37. Object Space AmbientOcclusion Computeaccessibilityvalueat eachelement (% ofhemisphere) Approximation based on the solid angle of an orienteddisk Stronglydependent on scene complexity
38. Object Space AmbientOcclusion
39. AmbientOcclusionResults
40. AmbientOcclusionResults
41. AmbientOcclusionConclusion Can bepreprocessedforeachobject Used in thecurrentversionofPIXAR‘sRenderMan
42. Outlook Fastercomputation Cheaper Artistscanseeresultsfaster More realisticlighting
43. Conclusion Veryimportantforanyanimatedmovie Computation time not tooimportant
44. Thanksforyourattention!