Image Science |
KONDO, Naoki |
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【Information and Electronic Engineering・2nd semester】
19-1-1225-2351 |
| 1. |
Outline |
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Students will learn the followings in this course,
(1) Physical and mathematical principles for image treatise (geometrical optics, theory of image formation )
(2) Basic computational implementations of above theories.
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| 2. |
Objectives |
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In this course we shall learn the basics of image science which will further lead us to deeper understanding and full utilization of modern advanced imaging technologies.
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| 3. |
Grading Policy |
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You will be graded by your quiz results and submitted reports (total 50%) and final examination marks (50%). Quiz results and reports are returned within 2 weeks after submission.
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| 4. |
Textbook and Reference |
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Text and supplementary materials are provided online on lecturer's web site.
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| 5. |
Requirements (Assignments) |
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Read the corresponding part of the text carefully (~1 hour).
It is recommended to verify the mathematical expressions and programs in the text and supplied materials in the review process (~2hours).
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| 6. |
Note |
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None.
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| 7. |
Schedule |
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| 1. Introduction: how 2D images are formed physically |
| 2. Physics of light 1 (Maxwell equations) |
| 3. Physics of light 2 (Wave equation and polarization) |
| 4. Physics of light 3 (Theoretical models in optics) |
| 5. Geometrical optics 1 (Concept of rays and their properties) |
| 6. Geometrical optics 2 (Refraction, reflection, absorption) |
| 7. Linear algebra 1 (Simultaneous equations and matrices) |
| 8. Linear algebra 2 (Product of a matrix and a vector, product of matrices) |
| 9. Matrix operation 1 (MATLAB basics) |
| 10. Matrix operation 2 (Matrix operations in MATLAB) |
| 11. Theory of image formation 1 (Ray transfer matrix, free space propagation) |
| 12. Theory of image formation 2 (Functions of lenses) |
| 13. Theory of image formation 3 (Mechanics of image formation) |
| 14. Theory of image formation 4 (binocular parallax and stereo vision) |
| 15. Summary |
|
| 1. |
Outline |
|
Students will learn the followings in this course,
(1) Physical and mathematical principles for image treatise (geometrical optics, theory of image formation )
(2) Basic computational implementations of above theories.
|
| 2. |
Objectives |
|
In this course we shall learn the basics of image science which will further lead us to deeper understanding and full utilization of modern advanced imaging technologies.
|
| 3. |
Grading Policy |
|
You will be graded by your quiz results and submitted reports (total 50%) and final examination marks (50%). Quiz results and reports are returned within 2 weeks after submission.
|
| 4. |
Textbook and Reference |
|
Text and supplementary materials are provided online on lecturer's web site.
|
| 5. |
Requirements (Assignments) |
|
Read the corresponding part of the text carefully (~1 hour).
It is recommended to verify the mathematical expressions and programs in the text and supplied materials in the review process (~2hours).
|
| 6. |
Note |
|
None.
|
| 7. |
Schedule |
|
| 1. Introduction: how 2D images are formed physically |
| 2. Physics of light 1 (Maxwell equations) |
| 3. Physics of light 2 (Wave equation and polarization) |
| 4. Physics of light 3 (Theoretical models in optics) |
| 5. Geometrical optics 1 (Concept of rays and their properties) |
| 6. Geometrical optics 2 (Refraction, reflection, absorption) |
| 7. Linear algebra 1 (Simultaneous equations and matrices) |
| 8. Linear algebra 2 (Product of a matrix and a vector, product of matrices) |
| 9. Matrix operation 1 (MATLAB basics) |
| 10. Matrix operation 2 (Matrix operations in MATLAB) |
| 11. Theory of image formation 1 (Ray transfer matrix, free space propagation) |
| 12. Theory of image formation 2 (Functions of lenses) |
| 13. Theory of image formation 3 (Mechanics of image formation) |
| 14. Theory of image formation 4 (binocular parallax and stereo vision) |
| 15. Summary |
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