“Caustic (optics)”的意思、由来-开放百科全书

In optics, a caustic or caustic network^[1] is the envelope of light rays reflected or refracted by a curved surface or object, or the projection of that envelope of rays on another surface.^[2] The caustic is a curve or surface to which each of the light rays is tangent, defining a boundary of an envelope of rays as a curve of concentrated light.^[2] Therefore, in the adjacent image, the caustics can be the patches of light or their bright edges. These shapes often have cusp singularities.

Explanation

Concentration of light, especially sunlight, can burn. The word caustic, in fact, comes from the Greek καυστός, burnt, via the Latin causticus, burning. A common situation where caustics are visible is when light shines on a drinking glass. The glass casts a shadow, but also produces a curved region of bright light. In ideal circumstances (including perfectly parallel rays, as if from a point source at infinity), a nephroid-shaped patch of light can be produced.^[3]^[4] Rippling caustics are commonly formed when light shines through waves on a body of water.

Another familiar caustic is the rainbow.^[5]^[6] Scattering of light by raindrops causes different wavelengths of light to be refracted into arcs of differing radius, producing the bow.

Computer graphics

In computer graphics, most modern rendering systems support caustics. Some of them even support volumetric caustics. This is accomplished by raytracing the possible paths of a light beam, accounting for the refraction and reflection. Photon mapping is one implementation of this. Volumetric caustics can also be achieved by volumetric path tracing. Some computer graphic systems work by "forward ray tracing" wherein photons are modeled as coming from a light source and bouncing around the environment according to rules. Caustics are formed in the regions where sufficient photons strike a surface causing it to be brighter than the average area in the scene. “Backward ray tracing” works in the reverse manner beginning at the surface and determining if there is a direct path to the light source.^[7] Some examples of 3D ray-traced caustics can be found here.

The focus of most computer graphics systems is aesthetics rather than physical accuracy. This is especially true when it comes to real-time graphics in computer games^[8] where generic pre-calculated textures are mostly used instead of physically correct calculations.

Caustic engineering

Caustic engineering describes the process of solving the inverse problem to computer graphics. Given a specific shape or image one wants to find a surface such that the light refracted forms this image.

In the discrete version of this problem, the surface is divided into several micro-surfaces which are assumed smooth, i.e. the light reflected/refracted by each micro-surface forms a Gaussian caustic. The position and orientation of each of the micro-surfaces is then obtained using a combination of Poisson-integration and so-called simulated annealing.^[9]

For the continuous problem there have been many different approaches to solving it.

One approach uses an idea from transportation theory called ‘optimal transport’^[10] to find a mapping between incoming light rays and target surface. After obtaining such a mapping, the surface is optimized by adapting it iteratively using Snell’s law of refraction.^[11]^[12]

See also

References

1. ^Lynch DK and Livingston W (2001). Color and Light in Nature. Cambridge University Press. {{ISBN|978-0-521-77504-5}}. Chapter 3.16 The caustic network, [https://books.google.com/books?id=4Abp5FdhskAC&pg=PA93&lpg=PA93&dq=Caustic+Network&source=bl&ots=bN-ULVuyq3&sig=VHt0Y8UFxFOaoDBL8E_gmVxgoIg&hl=en&ei=7qRgSpufMtW-lAedlpnRCQ&sa=X&oi=book_result&ct=result&resnum=4 Google books preview]
2. ^¹{{cite book|last=Weinstein|first=Lev Albertovich|title=Open Resonators and Open Waveguides|year=1969|publisher=The Golem Press|location=Boulder, Colorado}}
3. ^Circle Catacaustic. Wolfram MathWorld. Retrieved 2009-07-17.
4. ^{{Cite web|url=https://sinews.siam.org/Details-Page/focusing-on-nephroids|title=Focusing on Nephroids|last=Levi|first=Mark|date=2018-04-02|website=SIAM News|archive-url=|archive-date=|dead-url=|access-date=2018-06-01}}
5. ^Rainbow caustics
6. ^Caustic fringes
7. ^{{cite book |title=GPU Gems: Programming Techniques, Tips and Tricks for Real-Time Graphics |date=2004 |editor-first=Randima |editor-last=Fernando |publisher=Addison-Wesley |isbn=978-0321228321 |chapter=Chapter 2. Rendering Water Caustics |first=Juan |last=Guardado |chapter-url=https://developer.nvidia.com/gpugems/GPUGems/gpugems_ch02.html}}
8. ^{{cite web |url=http://www.dualheights.se/caustics/caustics-water-texturing-using-unity3d.shtml |title=Caustics water texturing using Unity 3D |publisher= Dual Heights Software |accessdate=May 28, 2017}}
9. ^{{cite journal|author=Marios Papas|title=Goal Based Caustics|journal=Computer Graphics Forum (Proc. Eurographics)|volume=30|number=2|date=April 2011}}
10. ^{{cite book |last=Villani |first=Cedric |date=2009 |title=Optimal Transport - Old and New |publisher=Springer-Verlag Berlin Heidelberg |isbn=978-3-540-71049-3 }}
11. ^{{cite journal|author=Philip Ball|title=Light tamers|journal=New Scientist|volume=217|number=2902| date=February 2013 |pages=40–43|doi=10.1016/S0262-4079(13)60310-3}}
12. ^Choreographing light: New algorithm controls light patterns called 'caustics', organizes them into coherent images

Explanation

Computer graphics

Caustic engineering

See also

References

Further reading