2015-09-14 1 GEOMETRICAL OPTICS I Lecture 1 Biophotonics Jae Gwan Kim [email protected] , X 2220 School of Information and Communication Engineering Gwangju Institute of Sciences and Technology Some Course Notes Lecture Notes will be provided on the web or sent by email Office Hours will be anytime as long as I’m at office Email for appointment: [email protected]
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2015-09-14
1
GEOMETRICALOPTICSI
Lecture1
Biophotonics
JaeGwan Kim
[email protected] ,X2220
SchoolofInformationandCommunicationEngineering
Gwangju InstituteofSciencesandTechnology
SomeCourseNotes
LectureNoteswillbeprovidedontheweborsentbyemail
OfficeHourswillbeanytimeaslongasI’matoffice
Emailforappointment:[email protected]
2015-09-14
2
ModuleGoal
• Learnenoughbasicopticstocommunicatehowtocouplelight frompointAtopointB
camera
lasercouplelaserintoafiber
PMT
opticalfiber
pictureafluorescingcell
collectlightfromatissue
?
?
?
ItemsYouWillLearn
1. Lensbasics–Conventions–typesoflenses–useoflensequations
2. Keycouplingconcepts–“f‐number”(f/#)–numericalaperture(NA)–aperturestops
3. FiberOptics–workingprinciples–typesoffibers– limitations
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OutlineforLenses
• Snell’sLawandrefraction
• ThinLenses
• LensConventions
• ATrueOpticsProblem
• CollectionEfficiency(f/# andNA)
• ExampleleadingtotheApertureStop
• FocusingConcerns
PRELIMINARY:REFRACTION&THETHINLENS
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ASimpleExample
• HowcanIcouplelightfroma1mmfilamentlampintoa0.1mmdiameteropticalfiber?
• Ofcourse,wemayusealens,buthowdowecalculate?
CONVENTIONS
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Conventions:LightIncidentonLeft
• Beforewecancalculatethegoodstuff,wewillneedtoadoptsomeconventionsconcerningournewfoundfriends.
• Conventionsneededfor:
1) objectdistance(so)2) imagedistance(si)3) radiusofcurvature(R)4) focalpoint(f)
(1)ObjectConventions
so
object is REALwhen rays diverge from object:
so > 0
object is VIRTUAL when rays converge to object:
so < 0
usually only with lens combinations
so
principal rays
+ ‐0
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(2)ImageConventions
si
image is REALwhen rays converge :
si > 0
image is VIRTUAL when rays diverge :
si < 0
rays project back to the imagesi
rays focus on the image‐ +0
(3)R Conventions
R1
R2
R1
R2
R > 0 when line lands on right R < 0 when line lands on left
R1 > 0
R2 < 0
R1 < 0
R2 >0
‐ +0
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(4)f Conventions
f
lens is CONVERGINGwhen rays converge:
f > 0
lens is DIVERGINGwhen rays diverge:
f < 0
f
f f check rays from
‐ +0
Geometrical Optics
https://youtu.be/uQE659ICjqQ
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LENSTYPE
CommonLensTypes
Planar convex
f > 0f > 0
Bi-convex
• symmetric lenses cancel some aberrations
• focus or magnify light
• produce real or virtual images
ForSimulations,http://phet.colorado.edu/sims/geometric‐optics/geometric‐optics_en.html
http://physics.bu.edu/~duffy/java/Opticsa1.html
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RayTracing
• Converginglens
http://upload.wikimedia.org/wikipedia/commons/8/82/Large_convex_lens.jpg
CommonLensTypes
Bi-concave
f < 0f < 0
Planar concave
• increase f of systems
• symmetric lenses cancel some aberrations
• light expanders
• produce real or virtual images
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RayTracing
• DivergingLens
http://en.wikipedia.org/wiki/File:Concave_lens.jpg
EyeAnatomy
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HumanLensFar distance Short distance
LensesMommyNeverMentioned
Meniscus (convex and concave)
f > 0 or f < 0
• used to change f or light collection in system
• aplanatic: won’t introduce spherical abbs
• BFL: back focal length• EFL: effective focal length,
for a thick lens or imaging system composed of multiple lenses/mirrors
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LensesMommyNeverMentioned
Cylindrical
• Used when magnification needed in only one dimension (slits, etc)
• Focus into a line instead of a point
f > 0 or f < 0
LensesMommyNeverMentioned
f > 0
Ball
f > 0
Gradient index (GRIN)
•collimate high-angle outputs (diode lasers, fibers)
• easy alignment, high coupling efficiencies
• easy to correct aberrations
• used in laser diode coupling
n=1.406
n=1.386
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LENSEQUATION
Refraction
n=1.33 n=1.51
n=1.0
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TheFundamentalLaw
2211 sinsin nn
1
2
n1 n2
taken wrt normal
for n2 > n1:ray bends towardsnormal
Snell’s Law
=
Snell’sLawSimulator
http://interactagram.com/physics/optics/refraction/
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ThePowerofSnell’sLaw
h = 0.7 mm
d = 1 mm
• Snell’s Law can calculate the focal spot of the glass sphere.
• Glass spheres are used to couple light into and from optical fibers. Use Snell’s law and that is all!
note: these rays are NOT paraxial
Paraxial: a ray makes a small angle to the optical axis of the system
LensMaker’sEquation
• Thefocallengthofathicklensin aircanbecalculatedfromthisequation.
Wheref isthefocaldistancefromlensnlens istherefractiveindexofthelensmaterial,R1 istheradiusofcurvatureofthelenssurfaceclosesttothelightsource,R2 istheradiusofcurvatureofthelenssurfacefarthestfromthelightsource,andd isthethicknessofthelens(thedistancealongthelensaxisbetweenthetwosurfacevertices).
11
1
1
1
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Thin LensEquation
• Ifd issmallcomparedtoR1 andR2,thenthethinlens approximationcanbemade.
• Ex)thinplanar‐convexlens,radius=50mm,=1.5,whatisf?
1.5 1
or 1.5 1 ,
=100mm
11
1
1
R1
R2
GaussianLensFormula
• Withtheparaxialapproximation,Gaussianlensformulaisasfollows
•
– iftheobjectdistanceSo becomesinfinity,thenSi becomesf.
– Whatare if isat600,200,150,100,and50mm?
–∗ 120 ,200,300,∞,and‐100mm
• Magnification Gaussian Lens Formula, For simulations, http://graphics.stanford.edu/courses/cs178-10/applets/gaussian.html
So is the distance to an object from lensSi is the distance from lens to image
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ThinLensEquationSign
So Si f
+ + +
+ ‐ +
+ ‐ ‐
1 1 1
Coupling:LamptoFiber
Goal: couple as much light as possible from this lamp into the fiber
Solution: f = 10 mm, D = 5 mm planar convex lens (cheap)
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HomeWork
• Derive usingthefollowingfigure
Center of lens
Optical axis
image
object
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