Chapter 2 geometrical_optics_a
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Transcript of Chapter 2 geometrical_optics_a
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Optics – geometrical optics
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Contents
Postulates of ray optics Optical components
-Mirrors
-Lenses
-Stops and pupils Matrix optics
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Ray Optics Ray optics is the simplest theory of light Light is described by rays that travel in different optical
media in accordance with a set of geometrical rules Ray optics is also known as Geometrical Optics Useful for studying image formation
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Ray Optics
QUANTUM OPTICS
ELECTROMAGNETIC OPTICS
WAVE OPTICS
GEOMETRICAL OPTICS
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Postulates of Ray Optics
Light travels in the form of rays An optical medium is characterized by a quantity
called refractive index, which is the ratio of speed of light in free space to that in the medium
The optical path length,
The optical path length corresponds to the distance in vacuum equivalent to the distance transverse in the medium of index n.
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The time taken by light to travel from point S to P is proportional to the optical path length
Fermat’s Principle- Light, in going from point S to P, traverses the route
having the smallest optical path length or shortest time. Derivative of OPL is zero.
- Governs the laws of refraction & reflection
Postulates of Ray Optics
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Plane of Incident
Plane of Incidence Contains Normal Contains Incident Ray Contains Refracted Ray Is the Plane Shown in
the Drawing Angles
– Defined from Normal
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Represent light waves as straight lines or rays
If incident (incoming) light wave hits surface of different material some light will
– be reflected back
– travel through and be refracted
Plane of Incident
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Define a line, the normal, which is - to surface at point where the incident beam hits the surface
Angles relative to normal– Angle of incidence -1– Angle of reflection q1’– Angle of refraction q2 Plane containing incident
ray and normal is plane of incidence
Plane of Incident
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Reflection & Refraction
Law of reflection: Reflected ray lies in plane of incidence and angle for reflection is equal to angle of incidence
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Law of refraction: Refracted ray lies in plane of incidence and angle of refraction is related to angle of incidence by Snell’s law
n is dimensionless constant called index of refraction. Index of refraction, n for given medium is defined as
Reflection & Refraction
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Exercise Use Fermat’s principle to derive the law of reflection and
law of refraction.
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Reflection & Refraction
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Reflection & RefractionExample of application of Snell’s law
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Exercise A beam of collimated light traveling in air makes an angle of
30o to the normal of a glass plate. If the index of the glass is ng = 3/2, determine the direction of the transmitted beam within the plate.
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Reflection & Refraction
The angle of incidence which causes the refracted ray to point directly along the surface is called the critical angle, qc
Angles larger than qc, no light is refracted, so we have total internal reflection (TIR)
For total internal reflection to occur n2 < n1– E.g. moving from water into air– Will not happen if moving from air into water
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Dispersion
n depends on wavelength of light, except in vacuum
Beam consists of different wavelengths, rays are refracted at different angles and spread out – chromatic dispersion
White light consists of components of all the colors in visible spectrum with uniform intensities
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Dispersion
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Imaging First, Assume a Point Object
Spherical Wavefronts and Radial Rays Define Object Location Find Image Location Real or Virtual?
Next Assume an Extended Object Compute Magnification
Transverse, Longitudinal, Angular
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Signs and definition Object Distance, s
– Positive to Left Image Distance, s’
– For Refraction
• Positive to Right
– For Reflection
• Positive to Left
B’
Imaging
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Imaging
Real Image Rays Converge Can Image on Paper Solid Lines in Notes
Virtual Image Extended Rays Converge Dotted-Lines in notes
Real and Virtual Images
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Planar Mirrors
Point Object Extended Object
q
q
A A’-s’s
q
A A’
B B’
h x x’‘
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Planar Mirrors
x’=x m=x’/x=1Transverse Magnification
ds’=-ds mz=ds’/ds=-1
Longitudinal Magnification
q’=q ma=q’/q =1Angular Magnification
Image is Virtual (Dotted lines converge)Erect (m>0),Perverted (cannot rotate to object)but not distorted (|m|=|mz|)
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Spherical Mirrors
CA A’
a bg
s
s’
R
h
Small-Angle Approximation
R
h
s
h
s
h 2
'
Rss
2
'
11
Conjugate Planes
Exterior Angles of Trianglesg=a+q b=g+q a+b=2gTangents of Anglestan a=h/s, tan b = h/s’,tan g = h/R
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Spherical Mirrors
AA’
ss’B
B’
Transverse Magnification
'
'tan
s
x
s
x
s
s
x
xm
''
ma= / b a =s/s’= |1/m|
x
x’q
q
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Spherical Mirrors
2''---
------
s
s
ds
dsmz
Image isReal (Converging Rays),Inverted (m<0),Distorted (mz=-m2),but Not Perverted (sign(m)=sign(mz))
ma=b/a =s/s’= |1/m|
Transverse Magnification
Longitudinal Magnification
Angular Magnification
s
s
x
xm
'' -==
Rss
2
'
11
0'
'22
s
ds
s
ds
Image Equation Differentiate2
''
s
s
ds
dsmz
Longitudinal Magnification
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Spherical Mirrors
FF’A’
Object at Infinity
Rss
2
'
11
Rs
2
'
1
fs
1
'
1Definition Application
fss
1
'
11
C
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Exercise Show that a spherical mirror equation is applicable to a
planar reflecting surface. A one-inch tall candle is set three inches in front of a
concave spherical mirror having a one-foot radius. Describe the resulting image.