1. Appearance Models for Graphics COMS 6998-3, Lecture 2 BRDFs and Radiometry Many slides courtesy Pat Hanrahan: http://graphics.stanford.edu/courses/cs348b-02/lectures/lecture4/illumination.pdf

3. Radiometry Physical measurement of electromagnetic energy We consider light field –Transport theory –Radiance, Irradiance –Reflection functions: BRDF –Examples, Properties –Simple BRDF models

4. Transport Theory Flow of stuff. In this case, stuff = photons of light Consider particle flow through small area [CW18] density

7. Radiance Power per unit projected area perpendicular to the ray per unit solid angle in the direction of the ray Symbol: L(x,ω) (W/m 2 sr) Flux given by dΦ = L(x,ω) cos θ dω dA

8. Radiance properties Radiance is constant as it propagates along ray –Derived from conservation of flux –Fundamental in Light Transport.

11. Radiance properties Sensor response proportional to surface radiance (constant of proportionality is throughput) –Far away surface: See more, but subtends smaller angle –Wall is equally bright across range of viewing distances Consequences –Radiance associated with rays in a ray tracer –All other radiometric quantities derived from radiance

14. Irradiance, Radiosity Irradiance E is the radiant power per unit area Integrate incoming radiance over hemisphere –Projected solid angle (cos θ d ω) –Uniform illumination: Irradiance = π [CW 24,25] –Units: W/m 2 Radiosity –Power per unit area leaving surface (like irradiance)

17. BRDF Reflected Radiance proportional to Irradiance Constant proportionality: BRDF [CW pp 28,29] –Bidirectional Reflection Distribution Function –(4 Vars) Reflectance Equation [CW pp 30]

20. Mirror

21. Lambertian

22. Reflectance/Energy Conservation

30. Retroreflection

31. Brdf Viewer plots Diffuse bv written by Szymon Rusinkiewicz Torrance-Sparrow Anisotropic

32. Representations

33. Reparameterizations