Presentation is loading. Please wait.

Presentation is loading. Please wait.

Activity 2-5: Conics www.carom-maths.co.uk. Take a point A, and a line not through A. Another point B moves so that it is always the same distance from.

Published byNoel Cook Modified over 8 years ago

Similar presentations

Presentation on theme: "Activity 2-5: Conics www.carom-maths.co.uk. Take a point A, and a line not through A. Another point B moves so that it is always the same distance from."— Presentation transcript:

1 Activity 2-5: Conics www.carom-maths.co.uk

2 Take a point A, and a line not through A. Another point B moves so that it is always the same distance from A as it is from the line.

3 Task: what will the locus of B be? Try to sketch this out. This looks very much like a parabola...

4 We can confirm this with coordinate geometry: This is of the form y = ax 2 + bx + c, and so is a parabola.

5 Suppose now we change our starting situation, and say that AB is e times the distance BC, where e is a number greater than 0. What is the locus of B now? We can use a Geogebra file to help us. Geogebra file

6 We can see the point A, and the starting values for e and q (B is the point (p, q) here). What happens as you vary q? The point B traces out a parabola, as we expect. (Point C traces out the left-hand part of the curve.)

7 Now we can reduce the value of e to 0.9. What do we expect now? This time the point B traces an ellipse. What would happen if we increased e to 1.1? The point B traces a graph in two parts, called a hyperbola.

8 Can we get another other curves by changing e? The ellipse gets closer and closer to being a circle. What happens as e gets closer and closer to 0? What happens as e gets larger and larger? The curve gets closer and closer to being a pair of straight lines.

9 So to summarise: This number e is called the eccentricity of the curve. e = 0 – a circle. 0 < e < 1 – an ellipse. e = 1 – a parabola 1 < e <  – a hyperbola. e =  – a pair of straight lines.

10 Now imagine a double cone, like this: If we allow ourselves one plane cut here, what curves can we make? Clearly this will give us a circle.

11 This gives you a perfect ellipse… A parabola… A hyperbola… and a pair of straight lines. Exactly the same collection of curves that we had with the point-line scenario.

12 This collection of curves is called ‘the conics’ (for obvious reasons). They were well-known to the Greeks – Appollonius (brilliantly) wrote an entire book devoted to the conics. It was he who gave the curves the names we use today.

13 Task: put the following curve into Autograph and vary the constants. How many different curves can you make? ax 2 + bxy + cy 2 + ux + vy + w = 0 Exactly the conics and none others!

14 Notice that we have arrived at three different ways to characterise these curves: 1. Through the point-line scenario, and the idea of eccentricity 2. Through looking at the curves we can generate with a plane cut through a double cone 3. Through considering the Cartesian curves given by all equations of second degree in x and y. Are there any other ways to define the conics?

15 With thanks to: Wikipedia, for helpful words and images. Carom is written by Jonny Griffiths, mail@jonny-griffiths.net

Download ppt "Activity 2-5: Conics www.carom-maths.co.uk. Take a point A, and a line not through A. Another point B moves so that it is always the same distance from."

Similar presentations

Conic Sections: Eccentricity

Conic Sections: Eccentricity
Graphing and Writing Equations

Graphing and Writing Equations
Appendix C- Part 2 Graphs of Second Degree Equations.

Appendix C- Part 2 Graphs of Second Degree Equations.
10.1 Parabolas.

10.1 Parabolas.
Warm Up Complete the square 1) 2) 3).

Warm Up Complete the square 1) 2) 3).
Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.
Conic Section By H.K.MEENA PGT (Maths) KV BEAWAR (Raj)

Conic Section By H.K.MEENA PGT (Maths) KV BEAWAR (Raj)
Section 11.6 – Conic Sections

Section 11.6 – Conic Sections
10.3 Ellipses JMerrill, 2010. General Second Degree Equation Ax 2 + Bxy + Cy 2 + Dx + Ey + F = 0.

10.3 Ellipses JMerrill, General Second Degree Equation Ax 2 + Bxy + Cy 2 + Dx + Ey + F = 0.
MATH CORE TERM 2 PROJECT Done by: Mohamed Saeed AlSayyah & Abdullah Aljasmi and Ahmed Salem 12-4.

MATH CORE TERM 2 PROJECT Done by: Mohamed Saeed AlSayyah & Abdullah Aljasmi and Ahmed Salem 12-4.
An Introduction to Conics

An Introduction to Conics
By: Leonardo Ramirez Pre Calculus Per.6 Mr. Caballero.

By: Leonardo Ramirez Pre Calculus Per.6 Mr. Caballero.
ACT Opener: Find 2

ACT Opener: Find 2
Conic Sections. (1) Circle A circle is formed when i.e. when the plane  is perpendicular to the axis of the cones.

Conic Sections. (1) Circle A circle is formed when i.e. when the plane  is perpendicular to the axis of the cones.
ESSENTIAL CALCULUS CH09 Parametric equations and polar coordinates.

ESSENTIAL CALCULUS CH09 Parametric equations and polar coordinates.
Introduction to Parabolas SPI 3103.3.11 Graph conic sections (circles, parabolas, ellipses and hyperbolas) and understand the relationship between the.

Introduction to Parabolas SPI Graph conic sections (circles, parabolas, ellipses and hyperbolas) and understand the relationship between the.
Rotation of Axes; General Form of a Conic

Rotation of Axes; General Form of a Conic
Unit #4 Conics. An ellipse is the set of all points in a plane whose distances from two fixed points in the plane, the foci, is constant. Major Axis Minor.

Unit #4 Conics. An ellipse is the set of all points in a plane whose distances from two fixed points in the plane, the foci, is constant. Major Axis Minor.
8.6 Conic Sections Write equations of conic sections in standard form Identify conic sections from their equations.

8.6 Conic Sections Write equations of conic sections in standard form Identify conic sections from their equations.
Activity 1-7: The Overlapping Circles www.carom-maths.co.uk.

Activity 1-7: The Overlapping Circles

Similar presentations

Ads by Google