Advanced Computer Graphics (Spring 2013) CS 283, Lecture 8: Illumination and Reflection Many slides courtesy.

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Presentation transcript:

Advanced Computer Graphics (Spring 2013) CS 283, Lecture 8: Illumination and Reflection Many slides courtesy Pat Hanrahan

Overview  Moving from geometry to rendering and appearance  Major part of course: 10 lectures  Includes discussion of current research topics  Assignments 2 and 3  First couple of lectures recap of 184 for those in it  Formal illumination, reflection, global illumination  But quickly move to new and advanced material  Remember Mesh Assignment due Feb 22

Radiometry  Physical measurement of electromagnetic energy  Measure spatial (and angular) properties of light  Radiance, Irradiance  Reflection functions: Bi-Directional Reflectance Distribution Function or BRDF  Reflection Equation  Simple BRDF models  Environment Maps

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

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

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

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

Irradiance Environment Maps Incident Radiance (Illumination Environment Map) Irradiance Environment Map R N

Radiometry  Physical measurement of electromagnetic energy  Measure spatial (and angular) properties of light  Radiance, Irradiance  Reflection functions: Bi-Directional Reflectance Distribution Function or BRDF  Reflection Equation  Simple BRDF models  Environment Maps

Building up the BRDF Bi-Directional Reflectance Distribution Function [Nicodemus 77] Function based on incident, view direction Relates incoming light energy to outgoing Unifying framework for many materials

BRDF Reflected Radiance proportional Irradiance Constant proportionality: BRDF Ratio of outgoing light (radiance) to incoming light (irradiance) –Bidirectional Reflection Distribution Function –(4 Vars) units 1/sr

Isotropic vs Anisotropic  Isotropic: Most materials (you can rotate about normal without changing reflections)  Anisotropic: brushed metal etc. preferred tangential direction Isotropic Anisotropic

Reflection Equation Reflected Radiance (Output Image) Incident radiance (from light source) BRDF Cosine of Incident angle

Reflection Equation Sum over all light sources Reflected Radiance (Output Image) Incident radiance (from light source) BRDF Cosine of Incident angle

Reflection Equation Replace sum with integral Reflected Radiance (Output Image) Incident radiance (from light source) BRDF Cosine of Incident angle

Radiometry  Physical measurement of electromagnetic energy  Measure spatial (and angular) properties of light  Radiance, Irradiance  Reflection functions: Bi-Directional Reflectance Distribution Function or BRDF  Reflection Equation  Simple BRDF models  Environment Maps

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

Analytical BRDF: TS example  One famous analytically derived BRDF is the Torrance-Sparrow model.  T-S is used to model specular surface, like the Phong model.  more accurate than Phong  has more parameters that can be set to match different materials  derived based on assumptions of underlying geometry. (instead of ‘because it works well’)

Torrance-Sparrow  Assume the surface is made up grooves at the microscopic level.  Assume the faces of these grooves (called microfacets) are perfect reflectors.  Take into account 3 phenomena Shadowing MaskingInterreflection

Torrance-Sparrow Result Fresnel term: allows for wavelength dependency Geometric Attenuation: reduces the output based on the amount of shadowing or masking that occurs. Distribution: distribution function determines what percentage of microfacets are oriented to reflect in the viewer direction. How much of the macroscopic surface is visible to the light source How much of the macroscopic surface is visible to the viewer

Other BRDF models  Empirical: Measure and build a 4D table  Anisotropic models for hair, brushed steel  Cartoon shaders, funky BRDFs  Capturing spatial variation  Very active area of research

Radiometry  Physical measurement of electromagnetic energy  Measure spatial (and angular) properties of light  Radiance, Irradiance  Reflection functions: Bi-Directional Reflectance Distribution Function or BRDF  Reflection Equation  Simple BRDF models  Environment Maps

Environment Maps  Light as a function of direction, from entire environment  Captured by photographing a chrome steel or mirror sphere  Accurate only for one point, but distant lighting same at other scene locations (typically use only one env. map) Blinn and Newell 1976, Miller and Hoffman, 1984 Later, Greene 86, Cabral et al. 87

Reflection Equation Replace sum with integral Reflected Radiance (Output Image) Environment Map (continuous) BRDF Cosine of Incident angle

Environment Maps  Environment maps widely used as lighting representation  Many modern methods deal with offline and real-time rendering with environment maps  Image-based complex lighting + complex BRDFs