Now You See It Marion White and Alex Treser Period 8/9 AP Physics 1.

Slides:

Advertisements

Similar presentations

Mirror and Lens Properties. Image Properties/Characteristics Image Type: Real or Virtual Image Orientation: Erect or Inverted Image Size: Smaller, Larger,

Advertisements

Refraction of Light Chapter 17. Index of refraction When light travels from one material to another it usually changes direction The bending of light.

Foundations of Physics

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.

By Kristine. An optical device is any technology that uses light. An optical device can be as simple as a mirror, or as complex as the Hubble Space Telescope.

Chapter 5 The Law of reflection allows mirrors to form images.

Grab Bag Wave Vocabulary Mirrors Light, Mirror, and Lens Lenses

Mirrors and Lenses: Mirrors reflect the light Lenses refract the light.

3.6: Mirrors & Lenses 12/15/14. Part 1: Mirrors A.Light is necessary for eyes to see 1.Light waves spread in all directions from a light. 2.The brain.

Mirrors Ch. 20. Mirrors Mirror – any smooth object that reflects light to form an image.

Mirror and Lenses. A flat, smooth mirror is called a plane mirror. Greek Mythology tell the story of Narcissus. He noticed his image in a pool of water.

CH 14: MIRRORS & LENSES 14.1: Mirrors. I. Plane Mirrors  Flat, smooth mirror  Creates a virtual image: an image your brain perceives even though no.

Chapter 11 Review Mirrors & Lenses. What is an angle of incidence? 2 The angle between an incident ray and the normal of an optical device. Category:

Ray Diagrams Notes.

Curved Mirrors. Two types of curved mirrors 1. Concave mirrors – inwardly curved inner surface that converges incoming light rays. 2. Convex Mirrors –

Optics Can you believe what you see?. Optics Reflection: Light is retransmitted from or “bounces off” an object.

A. can be focused on a screen. B. can be projected on a wall.

Mirrors and Lenses Chapter 23

__(B.19): Describe how light is absorbed, refracted, and reflected by different surfaces.

(c) McGraw Hill Ryerson Extending Human Vision Microscopes A compound light microscope uses two convex lenses to magnify small, close objects.

Light and Optics.

Mirrors & Reflection.

Optics 2: REFRACTION & LENSES. REFRACTION Refraction: is the bending of waves because of the change of speed of a wave when it passes from one medium.

When light travels from an object to your eye, you see the object. How do you use light to see? 14.1 Mirrors When no light is available to reflect off.

Lenses. Applications of Light Refraction What are some common applications of the refraction of light? Cameras Microscopes Lenses Eyeglasses Human eye.

Light wave Recall: Light must reflect off of an object before it can be used to see the object. A flat mirror is called a plane mirror. A plane mirror.

Telescopes and Microscopes. Question: When you look through the converging eyepiece of a telescope, you see an enlarged image of a distant object. If.

Mirrors and Lenses Chapter 14.

13-3 and Notes Mirrors. Concave Mirror – An inwardly curved, mirrored surface that is a portion of a sphere and that converges incoming light. Concave.

ReflectionReflection and Mirrors The Law of Reflection always applies: “The angle of reflection is equal to the angle of incidence.”

Extending Human Vision. Microscopes (c) McGraw Hill Ryerson 2007  A compound light microscope uses two convex lenses to magnify small, close objects.

How do I see color? Photochemical receptors receive the light (____ and _____) Rods-brightness cones-the color They release a ________ signal to the brain.

Ray Diagrams Noadswood Science, 2013.

Dow Now What do you already know about light and how it moves?

November 6th, 2015 Katie Hellier IRIS Science Academy

LENSES Mrs. Franco. Refraction is the bending of light when it moves from one matter to another.

Lenses Convex lenses converge rays of light. Parallel rays converge a fixed distance away from the lens. This is known as the focal length.

Mirrors and Lenses. Mirrors and Images Key Question: How does a lens or mirror form an image?

Image Formation. Flat Mirrors  p is called the object distance  q is called the image distance  θ 1 = θ 2 Virtual Image: formed when light rays do.

Chapter 19. Reflection The smooth surface of the lake reflects light rays so that the observer sees an inverted image of the landscape.

Chapter 20 Mirrors and Lenses

Refraction & Lenses Sections 11.7 and 11.8.

Mirrors. Types of mirror There are two types of mirror Plane (flat) Curved Concave (curves in) Convex (curves out)

 Imagine a clear evening when a full moon is just starting to rise. Even though the Moon might seem large and close, it is still too far away for you.

Light and Optics Part Three: Optics and Reflection.

Spherical Mirrors A spherical mirror has the shape of a section of a sphere The mirror focuses incoming parallel rays to a point (focal point) A concave.

Lesson P4 Part 1 ~ Mirrors & Reflection

Mirrors and Reflection

Optics: Reflection, Refraction Mirrors and Lenses

While you are watching the video think about why this is happening.

Optics Optics is the study of how light behaves.

Refraction & Lenses Sections 11.7 and 11.8.

Thin Lenses-Intro Notes

Unit 8: Light and Optics Chapter 22: Optics

17.2 Mirrors, Lenses, and Images

Lesson P4 Part 2 ~ Lenses & Refraction

Lesson P4 Part 1 ~ Mirrors & Reflection

Part 3: Optics (Lenses and Mirrors)

Geometrical Optics Seminar add-on Ing. Jaroslav Jíra, CSc.

Mirrors and Lenses.

6.2 Extending Human Vision

5.3: Using Lenses to Form Images

Using Lenses to Form Images

Lesson P4 Part 2 ~ Lenses & Refraction

5.3: Using Lenses to Form Images

Presentation transcript:

Now You See It Marion White and Alex Treser Period 8/9 AP Physics 1

Types of Telescopes Refracting telescopes work by using two lenses to focus the light and make it look like the object is closer to you than it really is. Both lenses are in a shape that’s called 'convex'. Convex lenses work by bending light inwards (like in the diagram). This is what makes the image look smaller. Reflecting telescopes, on the other hand, don’t use lenses at all. Instead, they use mirrors to focus the light together. In this case, the type of mirror that they use is a concave mirror. Mirrors of this shape also accomplish the goal of bending light together, except that they do it by reflecting the light instead of bending it as it passes through (like lenses do)

“Object are Closer Than They Appear” Light bounces off the flat surface, the angle of the reflected light is equivalent to the angle at which it struck the surface. The focal point- where the incoming light strikes the surface. Passenger side mirror is usually convex which extends the focal point so that the light striking the curved surface from a wider swath of angles all converge at the same focal point and then bounce into your eye. Wider focal point compresses the reflected image which make the objects appear smaller.

Focal Length fair/article/upside/

Inverted L with lenses and flashlight Why? Magnifying glasses are made of convex lenses. A convex lens makes objects look larger because it disperses light. When objects are magnified, they are within the focal length of the magnifying glass. The focal length is the distance between the center of the lens and its focus, the point where an object can be viewed clearly through a lens.

Why can’t we see far away? As an object gets further away less of its light will reach your eye. The image takes up less space on your retina (the light-sensitive tissue at the back of your eye), making the image smaller. This makes details of the image harder to see.

To make a distant object appear brighter and larger, we effectively need a bigger eye to collect more light. With more light we can create a brighter image, we can then magnify the image so that it takes up more space on our retina. The big lens in the telescope (objective lens) collects much more light than your eye can from a distant object and focuses the light to a point (the focal point) inside the telescope. A smaller lens (eyepiece lens) takes the bright light from the focal point and magnifies it so that it uses more of your retina.

Mirror Equation f = focal length d0 = object distance di= image distance Magnification Equation di= image distance d0= object distance I= image size O= object size

Convering lense

Divergent Lens

Two Converging Lenses

Converging and Diverging Lense