(Redirected from Geometric optics)
'Optics' ('' ''appearance'' or ''look'' in
Ancient Greek) is a branch of
physics that describes the behavior and properties of
light and the interaction of
light with
matter. Optics explains
optical phenomena.
The field of optics usually describes the behavior of
visible,
infrared, and
ultraviolet light; however because light is an
electromagnetic wave, analogous phenomena occur in
X-rays,
microwaves,
radio waves, and other forms of
electromagnetic radiation. Optics can thus be regarded as a sub-field of
electromagnetism. Some optical phenomena depend on the
quantum nature of light relating some areas of optics to
quantum mechanics. In practice, the vast majority of optical phenomena can be accounted for using the electromagnetic description of light, as described by
Maxwell's Equations.
Optics, as a field, is often considered largely separate from the physics community. It has its own identity, societies, and conferences. The pure science aspects of the field are often called optical science or
optical physics. Applied optical sciences are often called
optical engineering. Applications of optical engineering related specifically to
illumination systems are called illumination engineering. Each of these disciplines tends to be quite different in its applications, technical skills, focus, and professional affiliations. More recent innovations in optical engineering are often categorized as
photonics or
optoelectronics. The boundaries between these fields and "optics" are often unclear, and the terms are used differently in different parts of the world and in different areas of industry.
Because of the wide application of the science of "light" to real-world applications, the areas of optical science and optical engineering tend to be very cross-disciplinary. Optical science is a part of many related disciplines including electrical engineering, physics, psychology, medicine (particularly
ophthalmology and
optometry), and others. Additionally, the most complete description of optical behavior, as known to physics, is unnecessarily complicated for most problems, so particular simplified models are used. These limited models adequately describe subsets of optical phenomena while ignoring behavior irrelevant and/or undetectable to the system of interest.
Classical optics
Before
quantum optics became important, optics consisted mainly of the application of classical electromagnetism and its
high frequency approximations to light. Classical optics divides into two main branches: geometric optics and
physical optics.
'Geometric optics', or 'ray optics', describes
light propagation in terms of "
rays".
Rays are bent at the between two dissimilar media, and may be curved in a
medium in which the
refractive index is a function of position.
The "ray" in geometric optics is an abstract object which is perpendicular to the
wavefronts of the actual optical waves. Geometric optics provides rules for propagating these rays through an optical system, which indicates how the actual wavefront will propagate. Note that this is a significant simplification of optics, and fails to account for many important optical effects such as
diffraction and
polarization.
Geometric optics is often simplified even further by making the
paraxial approximation, or "small angle approximation." The mathematical behavior then becomes linear, allowing optical components and systems to be described by simple matrices. This leads to the techniques of
Gaussian optics and ''paraxial raytracing'', which are used to find first-order properties of optical systems, such as approximate image and object positions and magnifications.
Gaussian beam propagation is an expansion of paraxial optics that provides a more accurate model of coherent radiation like
laser beams. While still using the paraxial approximation, this technique partially accounts for diffraction, allowing accurate calculations of the rate at which a laser beam expands with distance, and the minimum size to which the beam can be focused. Gaussian beam propagation thus bridges the gap between geometric and physical optics.
Physical optics or
wave optics builds on
Huygen's principle and models the propagation of complex wavefronts through optical systems, including both the
amplitude and the
phase of the wave. This technique, which is usually applied numerically on a computer, can account for diffraction,
interference, and polarization effects, as well as
aberrations and other complex effects. Approximations are still generally used, however, so this is not a full electromagnetic wave theory model of the propagation of light. Such a full model would (at present) be too computationally demanding to be useful for most problems, although some small-scale problems can be analyzed using complete wave models.
Topics related to classical optics
Conceptual animation of
dispersion of light in a prism.
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Aberrations
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Coherence
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Diffraction
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Dispersion
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Distortion
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Fabrication and testing (optical components)
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Fermat's principle
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Fourier optics
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Gradient index optics
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Optical lens design
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Optical resolution
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Polarization
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Ray (optics)
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Ray tracing
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Reflection
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Refraction
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Scattering
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Wave
★ Geometric optics of:
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Lenses
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Mirrors
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Optical instruments
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Prisms
Modern optics
''Modern optics'' encompasses the areas of optical science and engineering that became popular in the 20th century. These areas of optical science typically relate to the electromagnetic or quantum properties of light but do include other topics.
Topics related to modern optics
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Adaptive optics
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Circular dichroism
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Crystal optics
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Diffractive optics
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Guided wave optics
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Holography
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Integrated optics
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Jones calculus
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Lasers
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Micro-optics
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Non-imaging optics
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Nonlinear optics
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Optical modeling and simulation methods
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Optical pattern recognition
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Optical processors
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Optical Vortex
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Photometry
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Photonics
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Quantum optics
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Radiometry
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Statistical optics
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Stray light
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Thin-film optics
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X-ray optics
Other optical fields
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Color science
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Illumination engineering
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Image processing
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Information theory
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Linear optics
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Machine vision
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Materials science - optical properties
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Optical communication
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Optical computers
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Optical data storage
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Optical display system
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Optical feedback
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Pattern recognition
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Photography (science of)
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Thermal physics —
radiative heat transfer
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Visual system
Everyday optics
Optics is part of everyday life.
Rainbows and
mirages are examples of optical phenomena. Many people benefit from
eyeglasses or
contact lenses, and optics are used in many consumer goods including
cameras. Superimposition of periodic structures, for example transparent tissues with a grid structure, produces shapes known as
moiré patterns. Superimposition of periodic transparent patterns comprising parallel opaque lines or curves produces
line moiré patterns.
See also
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History of optics
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List of optical topics
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Important publications in optics
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Transparency (optics)
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Optical illusion
★ ''Optics'' is a book of
Ptolemy
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Optician
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Anti-fog treatment of optical surfaces
Societies
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Optical Society of America
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SPIE - The International Society for Optical Engineering
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European Optical Society
Wikibooks modules
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References
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Optics (4th ed.), Hecht, Eugene, , , Pearson Education, 2001, ISBN 0-8053-8566-5
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Physics for Scientists and Engineers (6th ed.), Serway, Raymond A.; Jewett, John W., , , Brooks/Cole, 2004, ISBN 0-534-40842-7
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Physics for Scientists and Engineers: Electricity, Magnetism, Light, and Elementary Modern Physics (5th ed.), Tipler, Paul, , , W. H. Freeman, 2004, ISBN 0-7167-0810-8
External links
Textbooks and tutorials
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Optics — an open-source Optics textbook
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Optics2001 — Optics library and community
Societies
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OSA — Optical Society of America
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SPIE
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EOS — European Optical Society
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Northwest Photonics Association — UK
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