a practical analytic model for daylight a. j. preetham, peter shirley, brian smits siggraph ’99...

22
A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Upload: noreen-martin

Post on 16-Dec-2015

229 views

Category:

Documents


0 download

TRANSCRIPT

Page 1: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

A Practical Analytic Modelfor Daylight

A. J. Preetham, Peter Shirley, Brian SmitsSIGGRAPH ’99

Presentation by Jesse Hall

Page 2: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Introduction

• Outdoor scenes are becoming more feasible and common

• Most light comes from sun and sky

• Distances make atmosphere visible

Page 3: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Example

Important in photographs, paintings

Page 4: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Goals

• Accurate formulas for sun and sky color, aerial perspective effects

• Simple, intuitive parameters

– Location, direction, date, time of day, conditions…

• Computationally efficient

Page 5: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Background

• Sky color and aerial perspective are caused by atmospheric scattering of light (Minneart 1954)

• Primary and secondary scattering most important

Page 6: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Scattering: Air Molecules

• Most important scattering due to air molecules

• Molecules smaller than wavelength: Rayleigh scattering

• Wavelength-dependent scattering gives sky overall blue color

• Also causes yellow/orange sun, sunsets

Page 7: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Scattering: Haze

• Light also scattered by ‘haze’ particles (smoke, dust, smog)

• Haze particles larger than wavelength: Mie scattering, wavelength independent

• Usually approximated with turbidity parameter: T = (tm+th)/tm

Page 8: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Previous Work: Sky Color

• Explicit modeling

• Measured data– CIE IDMP, Ineichen 1994

• Simulation– Klassen 1987, Kaneda 1992, Nishita 1996

• Analytic– CIE formula 1994, Perez 1993

Page 9: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Previous Work:Aerial Perspective

• Explicit modeling

• Simulation– Ebert et al. 1998

• Analytic model for fog– Kaneda 1991

• Simple non-directional models– Ward-Larson 1998 (Radiance)

Page 10: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Sunlight & Skylight

• Input: sun position, turbidity

• Output: spectral radiance

• Sun position calculated from latitude, longitude, time, date

• Haze density based on turbidity and measured data

Page 11: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Sunlight

1. Look up spectral radiance outside atmosphere in table

2. Calculate attenuation from different particles using constants given in Iqbal 1983

3. Multiply extra-terrestrial spectral radiance by all attenuation coefficients to get direct spectral radiance

Page 12: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Skylight: Geometry

Page 13: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Skylight: Model

• Use Perez et al. model (1993)

A) darkening/brightening of horizonB) luminance gradient near horizonC) relative intensity of circumsolar regionD) width of circumsolar regionE) relative backscattered light

γ)ECe)(Ae(F DγθB/ 2cos11),( cos

),0(

),(

sz F

FYY

Page 14: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Skylight: Simulation

1. Compute spectral radiance for various viewing directions, sun positions, and turbidities using Nishita (1996) model

• Multiple scattering, spherical or planar atmosphere

• 12 sun positions, 5 turbidities, 343 viewing directions

• 600 CPU hours• Requires careful implementation

Page 15: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Skylight: Fitting

• Fit Perez coefficients to simulation using non-linear least-squares

• Luminance, chromaticity values require separate coefficients

• Result is three functions which combine to give spectral radiance

Page 16: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

CIE Chromaticity

Page 17: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Aerial Perspective

• Can’t be precomputed since it depends on distance and elevations

• Simpler model required for feasibility

• Assume particle density decreases exponentially with elevation

• Assume earth is flat

inLLsL 0)(

Page 18: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Aerial Perspective: Geometry

Page 19: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Aerial Perspective: Extinction

• Molecules and haze vary separately

= exponential decay constant 0 = scattering coefficient at surface• u(x) = ratio of density at x to density at surface

0

cos00

222111

cos

1

)()(

h

ee

suHKsuHK

eH

eK

ees

h

Page 20: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Aerial Perspective: Inscattering

• S(,,x): Light scattered into viewing direction at point x

• If |s cos |«1, Ii reduces to simple closed-form equation

dxxxuI

ISISLs

ii

in

),0()(

),(),(

0

2021

01

Page 21: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Aerial Perspective: Solution

• Otherwise, computing Ii directly is too expensive to be practical

• Approximate some terms in expansion with Hermite cubic polynomial, which is easily integrable

• Result is an analytic equation

Page 22: A Practical Analytic Model for Daylight A. J. Preetham, Peter Shirley, Brian Smits SIGGRAPH ’99 Presentation by Jesse Hall

Conclusions

• Reasonably accurate model

• Efficient enough for practical use

• Great pictures!

• Doesn’t model cloudy sky, fog, or localized pollution sources