Computer graphics lighting: Difference between revisions

'''Computer graphics lighting''' isencompasses the collectionrange of techniques used to simulate light inwithin [[computer graphics]] scenes. WhileThese lightingmethods techniques offer flexibilityvary in the[[computational level of detail and functionality availablecomplexity]], theyoffering alsoartists operateflexibility atin differentboth levelsvisual of computational demanddetail and [[Computational complexity|complexity]]performance. Graphics artistsprofessionals can chooseselect from a varietywide array of [[light sourcessource]]s, models[[lighting model]]s, [[shading]] techniques, and effects to suitmeet the needsspecific requirements of each applicationproject.

Light sources allow for different ways to introduce light into graphics scenes.<ref>{{Cite news|url=https://garagefarm.net/blog/light-the-art-of-exposure|title=Light: The art of exposure|date=2020-11-11|work=GarageFarm|access-date=2020-11-11|language=en-US}}</ref><ref name=":7">{{Cite web|url=https://www.cs.uic.edu/~jbell/CourseNotes/ComputerGraphics/LightingAndShading.html|title=Intro to Computer Graphics: Lighting and Shading|website=www.cs.uic.edu|access-date=2019-11-05}}</ref>

[[File:Real-time Raymarched Terrain.png|thumb|309x309px|A directional light source illuminating a terrain.]]

A directional source (or distant source) uniformly lights a scene from one direction.<ref name=":8" /> Unlike a point source, the intensity of light produced by a directional source does not change with distance over the scale of the scene, as the directional source is treated as though it is extremely far away from the scene.<ref name=":8" /> An example of a directional source is sunlight on Earth.<ref name=":9">{{Cite web|url=https://www.pluralsight.com/blog/film-games/understanding-different-light-types|title=Understanding Different Light Types|website=www.pluralsight.com|language=en|access-date=2019-11-05}}</ref>

A spotlight produces a directed [[cone]] of light.<ref name=":73">{{Cite web|url=https://www.cs.uic.edu/~jbell/CourseNotes/ComputerGraphics/LightingAndShading.html|title=Intro to Computer Graphics: Lighting and Shading|website=www.cs.uic.edu|access-date=2019-11-05}}</ref> The light becomes more intense as the viewer gets closer to the spotlight source and to the center of the light cone.<ref name=":73" /> An example of a spotlight is a flashlight.<ref name=":9" />

A lightwarp is a technique of which an object in the geometrical world [[refracts]] light based offon the [[Unit vector|direction]] and [[Intensity (physics)|intensity]] of the light. The light is then [[Wave function|warped]] using an ambient diffuse term with a range of the [[color spectrum]]. The light then may be [[reflectively]] scattered to produce a higher [[depth of field]], and [[refracted]]. The technique is used to produce a [[Style_(visual_arts)#Stylization|unique rendering style]] and can be used to limit [[overexposure]] of objects. Games such as [[Team Fortress 2]] use the rendering technique to create a [[cartoon]] [[cel shaded]] stylized look.<ref>{{Cite webbook|chapter-url=https://hal.inria.fr/inria-00449828|titlechapter=Radiance Scaling for Versatile Surface Enhancement|first1=Romain|last1=Vergne|first2=Romain|last2=Pacanowski|first3=Pascal|last3=Barla|first4=Xavier|last4=Granier|first5=Christophe|last5=Schlick|title=Proceedings of the 2010 ACM SIGGRAPH symposium on Interactive 3D Graphics and Games |date=February 19, 2010|pages=143–150 |publisher=ACM|via=hal.inria.fr|doi=10.1145/1730804.1730827|isbn=9781605589398 |s2cid=18291692 }}</ref>

In computer graphics, light usually consists of multiple components.<ref name=":8">{{Cite web|url=http://www.bcchang.com/immersive/ygbasics/lighting.html|title=Lighting in 3D Graphics|website=www.bcchang.com|access-date=2019-11-05}}</ref> Thethe overall effect of a light source on an object is determined by the combination of the object's interactions with theseit usually described by at least three main components.<ref name=":82">{{Cite web|url=http://www.bcchang.com/immersive/ygbasics/lighting.html|title=Lighting in 3D Graphics|website=www.bcchang.com|access-date=2019-11-05}}</ref> The three primary lighting components (and subsequent interaction types) are diffuse, ambient, and specular.<ref name=":82" />

[[File:Phong components revised.png|thumb|544x544px|Decomposition of lighting interactions.]]

Diffuse lighting (or [[diffuse reflection]]) is the direct illumination of an object by an even amount of light interacting with a [[Scattering|light-scattering]] surface.<ref name=":8"/><ref name=":10">{{Cite web|url=http://graphics.cs.cmu.edu/nsp/course/15-462/Spring04/slides/07-lighting.pdf|title=Lighting and Shading|last=Pollard|first=Nancy|author-link=Nancy Pollard|date=Spring 2004}}</ref> After light strikes an object, it is [[Reflection (computer graphics)|reflected]] as a function of the surface properties of the object as well as the angle of incoming light.<ref name=":10" /> This interaction is the primary contributor to the object's brightness and forms the basis for its color.<ref name=":83">{{Cite web|url=http://www.bcchang.com/immersive/ygbasics/lighting.html|title=Lighting in 3D Graphics|website=www.bcchang.com|access-date=2019-11-05}}</ref>

One of the most common shadingreflection models is the Phong model.<ref name=":1" /> The Phong model assumes that the intensity of each [[pixel]] is the sum of the intensity due to diffuse, specular, and ambient lighting.<ref name=":3" /> This model takes into account the ___location of a viewer to determine specular light using the angle of light reflecting off an object.<ref name=":4" /> The [[Trigonometric functions|cosine]] of the angle is taken and raised to a power decided by the designer.<ref name=":3" /> With this, the designer can decide how wide a highlight they want on an object; because of this, the power is called the shininess value.<ref name=":4" /> The shininess value is determined by the roughness of the surface where a mirror would have a value of infinity and the roughest surface might have a value of one.<ref name=":3" /> This model creates a more realistic looking white highlight based on the perspective of the viewer.<ref name=":1" />

Light sources emit rays that interact with various surfaces through absorption, reflection, or refraction.<ref name=":72" /> An observer of the scene would see any light source that reaches their eyes; a ray that does not reach the observer goes unnoticed.<ref>{{Cite web|url=https://developer.nvidia.com/rtx/raytracing|title=Introducing the NVIDIA RTX Ray Tracing Platform|date=2018-03-06|website=NVIDIA Developer|language=en|access-date=2019-11-08}}</ref> It is possible to simulate this by having all of the light sources emit rays and then compute how of each of them interact with all of the objects in the scene.<ref name=":17">Reif, J. H. (1994). "[https://users.cs.duke.edu/~reif/paper/tygar/raytracing.pdf Computability and Complexity of Ray Tracing]"(PDF). ''Discrete and Computational Geometry''.</ref> However, this process is inefficient as most of the light rays would not reach the observer and would waste processing time.<ref name=":21">Wallace, John R.; Cohen, Michael F.; Greenberg, Donald P. (1987). "A Two-pass Solution to the Rendering Equation: A Synthesis of Ray Tracing and Radiosity Methods". ''Proceedings of the 14th Annual Conference on Computer Graphics and Interactive Techniques''. SIGGRAPH '87. New York, NY, USA: ACM: 311–320. {{doi|10.1145/37401.37438}}. {{ISBN|9780897912273}}.</ref> Ray tracing solves this problem by reversing the process, instead sending view rays from the observer and calculating how they interact until they reach a light source.<ref name=":17" /> Although this way more effectively uses processing time and produces a light simulation closely imitating natural lighting, ray tracing still has high computation costs due to the high amounts of light that reach viewer's eyes.<ref name=":0">{{Cite journal|last=Greenberg|first=Donald P.|date=1989-04-14|title=Light Reflection Models for Computer Graphics|journal=Science|language=en|volume=244|issue=4901|pages=166–173|doi=10.1126/science.244.4901.166|issn=0036-8075|pmid=17835348|bibcode=1989Sci...244..166G |s2cid=46575183 }}</ref>

[[Photon]] mapping was created as a two-pass global illumination algorithm that is more efficient than raytracingray tracing.<ref name=":19">Wann Jensen, Henrik (1996). "[http://graphics.ucsd.edu/~henrik/papers/photon_map/global_illumination_using_photon_maps_egwr96.pdf Global Illumination using Photon Maps] {{Webarchive|url=https://web.archive.org/web/20080808140048/http://graphics.ucsd.edu/~henrik/papers/photon_map/global_illumination_using_photon_maps_egwr96.pdf |date=2008-08-08 }}" (PDF). ''Rendering Techniques ’96'': 21–30.</ref> It is the basic principle of tracking photons released from a light source through a series of stages.<ref name=":19" /> The first pass includes the photons being released from a light source and bouncing off their first object; this map of where are the photons are located is then recorded.<ref name=":18" /> The photon map contains both the position and direction of each photon which either bounce or are absorbed.<ref name=":19" /> The second pass happens with [[Rendering (computer graphics)|rendering]] where the reflections are calculated for different surfaces.<ref name=":20">{{Cite web|url=https://web.cs.wpi.edu/~emmanuel/courses/cs563/write_ups/zackw/photon_mapping/PhotonMapping.html|title=Photon Mapping - Zack Waters|website=web.cs.wpi.edu|access-date=2019-11-08}}</ref> In this process, the photon map is decoupled from the geometry of the scene, meaning rendering can be calculated separately.<ref name=":18" /> It is a useful technique because it can simulate caustics, and pre-processing steps do not need to be repeated if the view or objects change.<ref name=":20" />

[[File:Flatshading00.png|alt=|thumb|165x165px|An example of flat shading.]]

[[File:Gouraudshading01.png|alt=|thumb|165x165px|An example of Gouraud shading.]]

[[File:Phongshading00.png|alt=|thumb|165x165px|An example of Phong shading.]]

[[File:Miroir-cercle.jpg|thumb|A reflective material demonstrating caustics.]]

[[Caustic (optics)|Caustics]] are a lightingan effect of light reflected and refracted lightin movinga medium with curved interfaces or reflected throughoff a mediumcurved surface.<ref name=":14">{{Cite web|url=https://developer.nvidia.com/gpugems/GPUGems/gpugems_ch02.html|title=GPU Gems|website=NVIDIA Developer|language=en|access-date=2019-10-30}}</ref> They appear as ribbons of concentrated light and are often seen when looking at bodies of water or glass.<ref name=":15">{{Cite web|url=https://www.dualheights.se/caustics/caustics-water-texturing-using-unity3d.shtml|title=Caustics water texturing using Unity 3D|website=www.dualheights.se|access-date=2019-11-06}}</ref> Caustics can be implemented in 3D graphics by blending a caustic [[Texture mapping|texture map]] with the texture map of the affected objects.<ref name=":15" /> The caustics texture can either be a static image that is animated to mimic the effects of caustics, or a [[Real-time computing|Real-time]] calculation of caustics onto a blank image.<ref name=":15" /> The latter is more complicated and requires backwards [[Ray tracing (graphics)|ray tracing]] to simulate photons moving through the environment of the 3D render.<ref name=":14" /> In a photon mapping illumination model, [[Monte Carlo sampling|Monte Carlo]] sampling is used in conjunction with the ray tracing to compute the intensity of light caused by the caustics.<ref name=":14" />