Presentation is loading. Please wait.

Presentation is loading. Please wait.

Lenses.

Published byTodd Ray Modified over 8 years ago

Similar presentations

Presentation on theme: "Lenses."— Presentation transcript:

1 Lenses

2 Lenses A converging lens, or positive lens is a convex lens.
A diverging lens, or negative lens is a concave lens. We will be using biconvex lenses for IB. Lenses use refraction, and the rays bend twice in the lens. We simplify this by bending light rays once along a vertical line at the lens midpoint. We refer to lenses as “thin” lenses so we can simplify by bending the rays once.

3 Biconvex Lens This lens is called a converging lens (or positive lens). Light rays converge on the real side (right side) at the focal point. As it is composed of two circular objects joined together, there are two foci. The real focus is on the right side and the virtual focus is on the left side. Uses: Magnifying glasses, cameras, photographic enlargers, slide projectors, movie projectors, reading glasses.

4 Biconvex Lens The centre of the lens, where it meets the principal axis (PA), is called the optical centre (OC) The vertical line bisecting the lens is called the axis of symmetry (A of S) There are two focal points: the real one (F) and the virtual one (F’). Light rays parallel to the principal axis, will converge at the focal length, f. F F’ OC A of S PA

5 Biconvex Lens A thin lens has a thickness much smaller than f.
Three rays are used, to locate images. Ray 1: a ray parallel to PA from the top of the object to the A of S, refracts through F Ray 2: a ray passing through F’ and the top of the object to the A of S, refracts parallel to the PA Ray 3: a ray passing through the OC to the A of S, will not refract and will pass straight through

6 Biconvex Lens Ray Diagram F F’ OC O

7 Biconvex Lens Ray Diagram F F’ OC O

8 Biconvex Lens Ray Diagram F F’ OC O

9 Biconvex Lens Ray Diagram F F’ OC O

10 Biconvex Lens Ray Diagram F F’ OC O

11 Biconvex Lens Ray Diagram F F’ OC O I

12 Biconvex Lens Ray Diagram F F’ OC O I Image Characteristics Type: Real
Attitude: Inverted Magnification: M = hi/ho = - _____cm/ ______cm = - ______ Location: di = + ________ cm

13 Human Eye

14 Calculations We can use the mirror formulae with lenses again.
The thin lens equation is very applicable here (obviously!) Remember that di is negative for virtual images and hi is negative if the image is inverted.

15 Calculations Ex 1) A convex lens of a magnifying glass is held 2.00 cm above a page to magnify the print. If the image produced by the lens is 3.60 cm away and virtual, what is the focal length of the lens?

16 Calculations Ex 2) A convex lens has a focal length of 60.0 cm. A candle is placed 50.0 cm from the lens. What type of image is formed and how far is the image from the lens? As di is negative, the image is virtual.

17 Text Practice Note: A biconcave lens is not required for SL. Page 739 #5, 6 – 9, 13. Page 740 #22 – 28 Lens worksheet

Download ppt "Lenses."

Similar presentations

Subject: PHYSICS Topic: Convex lens Light refraction in Prism Ray diagram of a convex lens Ray diagram illustrating graphical construction rules of a.

Subject: PHYSICS Topic: Convex lens Light refraction in Prism Ray diagram of a convex lens Ray diagram illustrating graphical construction rules of a.
Convex and Concave Lenses

Convex and Concave Lenses
Characteristics of Lenses Lens  Is a transparent object with at least one curved side that causes light to refract.  Have 2 sides  Either side could.

Characteristics of Lenses Lens  Is a transparent object with at least one curved side that causes light to refract.  Have 2 sides  Either side could.
Physics 1161 – Lecture 23 Lenses

Physics 1161 – Lecture 23 Lenses
Flat Lens (Window) n1n1 n2n2 Incident ray is displaced, but its direction is not changed. tt 11 11 If  1 is not large, and if t is small, the.

Flat Lens (Window) n1n1 n2n2 Incident ray is displaced, but its direction is not changed. tt 11 11 If  1 is not large, and if t is small, the.
Light and Optics Mirrors and Lenses. Types of Mirrors Concave mirrors – curve inward and may produce real or virtual images. Convex mirrors – curve outward.

Light and Optics Mirrors and Lenses. Types of Mirrors Concave mirrors – curve inward and may produce real or virtual images. Convex mirrors – curve outward.
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.
Grab Bag Wave Vocabulary Mirrors Light, Mirror, and Lens Lenses 10 20 30 40 50 40 30 20 10 50 40 30 20 10 50 40 30 20 10 50 40 30 20 10.

Grab Bag Wave Vocabulary Mirrors Light, Mirror, and Lens Lenses
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.
(10.3/10.4) Mirror and Magnification Equations (12.2) Thin Lens and Magnification Equations.

(10.3/10.4) Mirror and Magnification Equations (12.2) Thin Lens and Magnification Equations.
Chapter 34: Thin Lenses 1 Now consider refraction through this piece of glass: optic axis This is called a “Double Convex Lens” converging light focal.

Chapter 34: Thin Lenses 1 Now consider refraction through this piece of glass: optic axis This is called a “Double Convex Lens” converging light focal.
Types of Lenses If you have ever used a microscope, telescope, binoculars, or a camera, you have worked with one or more lenses. A lens is a curved transparent.

Types of Lenses If you have ever used a microscope, telescope, binoculars, or a camera, you have worked with one or more lenses. A lens is a curved transparent.
Magnification of lenses Images

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

Curved Mirrors. Two types of curved mirrors 1. Concave mirrors – inwardly curved inner surface that converges incoming light rays. 2. Convex Mirrors –
Homework Set 4: From “Seeing the Light” Chapter 3: (starting page 101) P9, P10, P11, PM3 From “Seeing the Light” Chapter 4: P2, P5, P7, P13 Due: Monday,

Homework Set 4: From “Seeing the Light” Chapter 3: (starting page 101) P9, P10, P11, PM3 From “Seeing the Light” Chapter 4: P2, P5, P7, P13 Due: Monday,
Section 12.2 Pages 494 - 498. Lens Terminology The principal axis is an imaginary line drawn through the optical centre perpendicular to both surfaces.

Section 12.2 Pages Lens Terminology The principal axis is an imaginary line drawn through the optical centre perpendicular to both surfaces.
Thin Lenses If the thickness of the lens is small compared to the object and image distances we can neglect the thickness (t) of the lens. All thin lenses.

Thin Lenses If the thickness of the lens is small compared to the object and image distances we can neglect the thickness (t) of the lens. All thin lenses.
Refraction (bending light) Refraction is when light bends as it passes from one medium into another. When light traveling through air passes into the glass.

Refraction (bending light) Refraction is when light bends as it passes from one medium into another. When light traveling through air passes into the glass.
Physics 1161 – Prelecture 23 Converging & Diverging Lenses.

Physics 1161 – Prelecture 23 Converging & Diverging Lenses.
Converging lenses Diverging Lenses The Lens Equation We can make use of the fact that changing the focal length and position of the object we can change.

Converging lenses Diverging Lenses The Lens Equation We can make use of the fact that changing the focal length and position of the object we can change.

Similar presentations

Ads by Google