Further Pure 1 - PowerPoint PPT Presentation

1 / 22
About This Presentation
Title:

Further Pure 1

Description:

Title: FP1 Last modified by: ksandhu Created Date: 11/1/2005 3:15:23 PM Document presentation format: On-screen Show Company: Hardenhuish School Other titles – PowerPoint PPT presentation

Number of Views:38
Avg rating:3.0/5.0
Slides: 23
Provided by: homepageN8
Category:

less

Transcript and Presenter's Notes

Title: Further Pure 1


1
Further Pure 1
  • Inverse Matrices

2
Reminder from lesson 1
  • Note that any matrix multiplied by the identity
    matrix is itself.
  • And any matrix multiplied by the zero matrix is
    the zero matrix.

3
Inverse Matrix
  • All operations have an opposite.
  • We discussed in lesson 2 about using matrices to
    perform transformations.
  • An inverse matrix will undo the transformation
    and return you to where you started.
  • If a matrix is called A, then its inverse is
    known as A-1.
  • In lesson 1 we briefly met the concept of an
    identity matrix (seen on first slide).
  • So if multiplying A by A-1 returns you to where
    you started and multiplying by the identity
    matrix leaves you where you are, we can conclude
    that AA-1 A-1A I

4
Challenge 1
  • You need to know the general formula for the
    inverse of a 2 2 matrix.
  • Can you find the inverse to the following matrix?
  • Use the property TT-1 I
  • From this we can form 2 pairs of simultaneous
    equations.
  • 2p 3q 1 2r 3s 0
  • p 4q 0 r 4s 1

5
Challenge 1
  • The solutions to these equations are
  • So the inverse of T is

6
Challenge 1
  • Lets now take any 2 2 matrix.
  • Can you use T and T-1 to find the inverse of M
    and hence the general formula for the inverse of
    any 2 2 matrix?

7
The Determinant of a 2 2 matrix
  • We have just found the general equation for the
    inverse of any 2 2 matrix.
  • The ? symbol is a capital delta and will always
    be a numerical value.
  • The value can be calculated from the matrix and
    is known as the determinant of the matrix.
  • Using T and T-1 can you spot how to calculate it?

8
The Determinant of a 2 2 matrix
  • To calculate the determinant of a matrix M you
    multiply a by d and subtract b by c.
  • Below is the official notation.
  • If the det is zero then the inverse does not
    exist and the matrix is known as singular.
  • If the det is not zero then the inverse does
    exist and the matrix is known as non-singular.
  • Note Only square matrices have inverses.

9
Challenge 2
  • This is above the scope of the course and not
    required for you to do.
  • However it is a challenging question that will
    test your algebraic manipulation skills.
  • Can you find the inverse of M using the identity
    below and the method we used a few slides ago.
  • This will also prove where the formula for the
    determinant comes from.

10
Questions
  • Find the inverse of the following matrices.

11
Inverse of a product
  • Find the inverse of AB.
  • Lets call the inverse of AB, X.
  • So as we already know X(AB) I
  • First multiply by B-1 X(AB)B-1 IB-1
  • XA B-1
  • Next multiply by A-1 XAA-1 B-1A-1
  • X B-1A-1
  • This is an important result that you need to know
  • (AB)-1 B-1A-1

12
Properties of the determinant
  • The orange square is an enlargement of the black
    square by a scale factor 2.
  • What is the area of the object?
  • Area 9 units2
  • What is the area of the image?
  • Area 36 units2
  • The transformation performed can be described by
    the following matrix
  • What do you notice about the determinant of the
    matrix and the enlargement shown.
  • The determinant of a matrix indicates the scale
    factor of the area of enlargement.
  • The det T is known as the signed scale factor as
    it can be negative.
  • The negative signifies that the rotation
    direction has been reversed.

13
Task
  • Can you explain how we know that the area of any
    shape rotated ? degrees anti-clockwise about the
    origin remains the same.

14
Matrices with det 0
  • The determinant of a matrix tells us the scale
    factor of the areas enlargement.
  • What would be the area of a shape transformed by
    a matrix with det 0?
  • The area would be 0.
  • All the points will have been transformed so what
    will the image look like?
  • The image will be a straight line.
  • We can see an example of this on the next slide.

15
Example 1
  • Lets start with a rectangle on a 2D pair of axes.
  • We can write the co-ordinates of the vertices in
    matrix form.
  • Next transform the object using a matrix with a
    det 0
  • The image becomes a series of points that are in
    a straight line.

16
Example 1
  • In fact although we used a rectangle for the
    example any point in the plane will transform to
    the line.
  • From the diagram its clear to see what the
    equation of the line will be.
  • y x

17
Example 1
  • We can reach the same result as the last slide
    using an algebraic method.
  • Lets look at the general co-ordinate (x,y).
  • Under the transformation we get the co-ordinates
    (x,y)
  • Using matrix multiplication we can see that.
  • x 2y x
  • x 2y y
  • From this we get y x 2y x
  • Or y x

18
Example 2
  • The plane is transformed by the
    matrix.
  • Show that the whole plane is mapped to a straight
    line and find the equation of this line.
  • Using matrix multiplication gives us the
    simultaneous equations.
  • x 2x y
  • y -4x 2y
  • From the equations we get y -2(2x y) -2x
  • All the points will map to the line y -2x

19
Example 2
  • All points in a plane transform to a straight
    line.
  • This is because there are infinitely many lines
    that transform to a single point.

20
Example 3
  • For the matrix T find the equation of the line of
    points that map to (5,-10).
  • We use matrix multiplication to find what
    equations will be equal to the co-ordinate
    (5,-10)
  • This gives us the equations
  • 2x y 5
  • -4x y -10
  • These two equations give the exact same
    information.
  • 2x y 5

21
Summary 1
  • The inverse of a matrix
  • Is
  • Where

22
Summary 2
  • MM-1 M-1M I
  • X B-1A-1
Write a Comment
User Comments (0)
About PowerShow.com