Inleiding Optica
Introduction to Optics
2010-2011
vaknummer 146012
Instructors
name:
leerstoel:
office:
phone:
IO section:
Jennifer Herek
OS
Carre 4441
3172
Fred van Goor
LPNO
Hogekamp B0236
3967
Hans Kanger
NBP
Zuidhorst 156
3726
hoorcolleges
werkcolleges
practica
computer work
werkcolleges
practica
Q: How was this photo made (no photoshop!)?
What is the optical element in my hands? Draw the rays that produce 3rd eye.
Why you will love optics
1. Because it will change the way you see
the world
2. Because you are Dutch
3. Because you belong to Arago
Why you will love optics
1. Because it will change the way you see
the world
2. Because you are Dutch
3. Because you belong to Arago
Dutch pioneers of optics
Pioneers in the Optical Sciences http://www.molecularexpressions.com/optics/index.html
Why you will love optics
1. Because it will change the way you see
the world
2. Because you are Dutch
3. Because you belong to Arago
Who was Arago?
Course structure
conceptual, analytical, practical
Monday: HC (OH 210; 10:45 – 12:30)
Monday: Practicum group 1
(Carre 4; 13:45 – 17:30)
Tuesday: Practicum group 2
(Carre 4; 13:45 – 17:30)
Wednesday: WC (OH 210; 13:45 – 15:30)
Thursday: Practicum group 3
(Carre 4; 13:45 – 17:30)
Friday: Practicum group 4
(Carre 4; 13:45 – 17:30)
Practicum = learning by doing
- deelname verplicht
- inschrijven on practicum website (http://www.utwente.nl/tnw/onderwijs/practica_tnw/)
- read manual
- download software to your laptop
- bring laptop
6 bonus opdrachten (computer experiments)
- deelname verplicht
- each worth 2 pts (hence, max 12 pts added to your final exam result)
- details on course website (http://edu.tnw.utwente.nl/inlopt )
Final exam
- maximum 100 pts
- 5 November 2010, 08:45 – 12:30
- open book (Pedrotti3) + max 2 A4tjes of formulas (zelfgemaakt)
Course grade
- requires “voldoende” for all 4 practicum exercises
- based on final exam + bonus points
Yes, it’s a lot of work…
Studiepunten: 5 EC
1 EC = 28 hours
Total time requirement 5 x 28 140
hoorcolleges
8x2
werkcolleges
8x2
practica 6 x 4 24
computer exercises
STUDY TIME
hours
16
16
6 x 2? 12
~70
hours
…but worth it. And fun!
Study material
Website: http://edu.tnw.utwente.nl/inlopt
• Studiehandleiding
(rooster, tentamenstof, begripsvragen, ...)
• Simulaties optische verschijnselen
• Lecture slides
• 2009 lecture slides (with NL audio)
• Mini videos of important concepts
• Bonusopdrachten (computer experimenten)
• Practicum info
• Links naar interessante optica web-sites
Blackboard:
INLEIDING OPTICA (2010)
(2010_191460121) (inschrijven!)
Textbook:
Introduction to Optics, 3rd edition
Pedrotti, Pedrotti & Pedrotti
NEW
for 2010
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
Chapter 8
Chapter 9
Chapter 10
Chapter 11
Chapter 12
Chapter 13
Chapter 14
Chapter 15
Chapter 16
Chapter 17
Chapter 18
Chapter 19
Chapter 20
Chapter 21
Chapter 22
Chapter 23
Chapter 24
Chapter 25
Chapter 26
Chapter 27
Chapter 28
Nature of Light
Geometrical Optics
Optical Instrumentation
Wave Equations
Superposition of Waves
Properties of Lasers
Interference of Light
Optical Interferometry
Coherence
Fiber Optics
Fraunhofer Diffraction
The Diffraction Grating
Fresnel Diffraction
Matrix Treatment of Polarization
Production of Polarized Light
Holography
Optical Detectors and Displays
Matrix Methods in Paraxial Optics
Optics of the Eye
Aberration Theory
Fourier Optics
Theory of Multilayer Films
Fresnel Equations
Nonlinear Optics and the Modulation of Light
Optical Properties of Materials
Laser Operation
Characteristics of Laser Beams
Selected Modern Applications
Chapter 1
Chapter 2
Chapter 3
Chapter 4
Chapter 5
Chapter 6
Chapter 7
Chapter 8
Chapter 9
Chapter 10
Chapter 11
Chapter 12
Chapter 13
Chapter 14
Chapter 15
Chapter 16
Chapter 17
Chapter 18
Chapter 19
Chapter 20
Chapter 21
Chapter 22
Chapter 23
Chapter 24
Chapter 25
Chapter 26
Chapter 27
Chapter 28
Nature of Light
Geometrical Optics
Optical Instrumentation
Wave Equations
Superposition of Waves
Properties of Lasers
Interference of Light
Optical Interferometry
Coherence
Fiber Optics
Fraunhofer Diffraction
The Diffraction Grating
Fresnel Diffraction
Matrix Treatment of Polarization
Production of Polarized Light
Holography
Optical Detectors and Displays
Matrix Methods in Paraxial Optics
Optics of the Eye
Aberration Theory
Fourier Optics
Theory of Multilayer Films
Fresnel Equations
Nonlinear Optics and the Modulation of Light
Optical Properties of Materials
Laser Operation
Characteristics of Laser Beams
Selected Modern Applications
Week 1 = TODAY
Chapter 1 Nature of Light
wave-particle duality
radiometry
Chapter 2
Week 2
Chapter 4
Geometrical Optics
basic principles
reflection
refraction
imaging
Wave Equations
Week 8
Chapter 23 Fresnel Equations
Week 3
Chapter 5
Superposition of Waves
Week 4
Chapter 7
Interference of Light
Week 5
Chapter 11 Fraunhofer Diffraction
Week 6
Chapter 13 Fresnel Diffraction
Week 7
Chapter 14 Matrix Treatment of Polarization
Chapter 18 Matrix Methods in Paraxial Optics
5 tips for success during lectures
1. Be on time
2. Pay attention
3. Take notes
4. Ask questions
5. Give feedback
no texting
no talking
no earphones
Any questions?