Presentation is loading. Please wait.

Presentation is loading. Please wait.

Daily Challenge, 12/21 The distance from the front to the back of your eye is approximately 1.90 cm. If you see a clear image of your physics book when.

Published byCurtis Palmer Modified over 9 years ago

Similar presentations

Presentation on theme: "Daily Challenge, 12/21 The distance from the front to the back of your eye is approximately 1.90 cm. If you see a clear image of your physics book when."— Presentation transcript:

1 Daily Challenge, 12/21 The distance from the front to the back of your eye is approximately 1.90 cm. If you see a clear image of your physics book when it is 35.0 cm from your eyes, what must the focal length of your cornea be? Actually you can probably see a clear image of your book at a range of distances. Why? What does this tell you about the focal length of your cornea?

2 What happens to the image produced by a converging lens as you… move the object further from the lens? decrease the lens’ radius of curvature? decrease the refractive index? Dispersion Link http://www.shermanlab.com/science/physics/optics/ThinLens.php http://www.mtholyoke.edu/~mpeterso/classes/phys301/geomopti/lenses.html http://physics.bu.edu/~duffy/classroom.html

3 Polarization Plane-polarized light is light in which the oscillations are confined to a plane that includes the line of propagation. Can be achieved by… Selective absorption Reflection at the “polarization angle” Refraction (e.g. calcite -> Nicol prism)

4 http://www.glenbrook.k12.il.us/GBSSCI/PHYS/CLASS/light/u12l1e.html#trans Polarization

5 Daily Challenge, 12/22 A converging lens with a focal length of 15 cm is placed 53 cm from a light bulb. Where would you place a screen to focus an image of the object?

6 Daily Challenge, 12/23 Complete the “Light” crossword puzzle.

Download ppt "Daily Challenge, 12/21 The distance from the front to the back of your eye is approximately 1.90 cm. If you see a clear image of your physics book when."

Similar presentations

Learning Outcome Draw a ray diagram to find the position, nature and size of the image produced by a concave and convex mirrors.

Learning Outcome Draw a ray diagram to find the position, nature and size of the image produced by a concave and convex mirrors.
Chapter 23.

Chapter 23.
Class-X Light, Reflection and Refraction.

Class-X Light, Reflection and Refraction.
Early Work – Mar. 26 List five ways in which you use a mirror or a lens on a daily basis. Ch. 18 Vocab.

Early Work – Mar. 26 List five ways in which you use a mirror or a lens on a daily basis. Ch. 18 Vocab.
Chapter 15 Pretest Light and Refraction

Chapter 15 Pretest Light and Refraction
Law of Reflection (Smooth Surface):

Law of Reflection (Smooth Surface):
LENSES. LENSES A light ray bends as it enters glass and bends again as it leaves ◦This refraction is due to the difference in the average speed of light.

LENSES. LENSES A light ray bends as it enters glass and bends again as it leaves ◦This refraction is due to the difference in the average speed of light.
Refraction How to Find Images Using Ray Diagrams  Bending of light due to a change in speed (changes mediums)  Objects behind or in more optically dense.

Refraction How to Find Images Using Ray Diagrams  Bending of light due to a change in speed (changes mediums)  Objects behind or in more optically dense.
Optics Review #1 LCHS Dr.E.

Optics Review #1 LCHS Dr.E.
Physics 123 23. Light: Geometric Optics 23.1 The Ray Model of Light 23.2 Reflection - Plane Mirror 23.3 Spherical Mirrors 23.5 Refraction - Snell’s law.

Physics Light: Geometric Optics 23.1 The Ray Model of Light 23.2 Reflection - Plane Mirror 23.3 Spherical Mirrors 23.5 Refraction - Snell’s law.
Reflection from Curved Mirrors. 2 Curved mirrors The centre of the mirror is called the pole. A line at right angles to this is called the principal axis.

Reflection from Curved Mirrors. 2 Curved mirrors The centre of the mirror is called the pole. A line at right angles to this is called the principal axis.
1 From Last Time… Lenses and image formation Object Image Lens Object Image Thurs. Sep. 17, 2009Physics 208, Lecture 5.

1 From Last Time… Lenses and image formation Object Image Lens Object Image Thurs. Sep. 17, 2009Physics 208, Lecture 5.
The Refraction of Light The speed of light is different in different materials. We define the index of refraction, n, of a material to be the ratio of.

The Refraction of Light The speed of light is different in different materials. We define the index of refraction, n, of a material to be the ratio of.
Example A 2.0 cm high object is placed 5 cm in front of a +10 cm focal length lens. Where is the object located? Is it real or virtual? Find the height.

Example A 2.0 cm high object is placed 5 cm in front of a +10 cm focal length lens. Where is the object located? Is it real or virtual? Find the height.
LENS any transparent object having two nonparallel curved surfaces or one plane surface and one curved surface Converging Lenses - thicker in middle than.

LENS any transparent object having two nonparallel curved surfaces or one plane surface and one curved surface Converging Lenses - thicker in middle than.
James T. Shipman Jerry D. Wilson Charles A. Higgins, Jr. Optics and Wave Effects Chapter 7.

James T. Shipman Jerry D. Wilson Charles A. Higgins, Jr. Optics and Wave Effects Chapter 7.
Optics: Lenses & Mirrors. Thin Lenses Thin Lenses: Any device which concentrates or disperses light. Types of Lenses:  Converging Lens: Parallel rays.

Optics: Lenses & Mirrors. Thin Lenses Thin Lenses: Any device which concentrates or disperses light. Types of Lenses:  Converging Lens: Parallel rays.
Mirrors Physics 202 Professor Lee Carkner Lecture 22.

Mirrors Physics 202 Professor Lee Carkner Lecture 22.
8. Thin lenses Thin lenses are those whose thickness is small compared to their radius of curvature. They may be either converging or diverging. Example:

8. Thin lenses Thin lenses are those whose thickness is small compared to their radius of curvature. They may be either converging or diverging. Example:
Light & Optics: Making a Telescope Dr Lisa Jardine-Wright.

Light & Optics: Making a Telescope Dr Lisa Jardine-Wright.

Similar presentations

Ads by Google