Presentation is loading. Please wait.

Presentation is loading. Please wait.

Unit 39 Matrices Presentation 1Matrix Additional and Subtraction Presentation 2Scalar Multiplication Presentation 3Matrix Multiplication 1 Presentation.

Published byOliver Barrett Modified over 9 years ago

Similar presentations

Presentation on theme: "Unit 39 Matrices Presentation 1Matrix Additional and Subtraction Presentation 2Scalar Multiplication Presentation 3Matrix Multiplication 1 Presentation."— Presentation transcript:

1 Unit 39 Matrices Presentation 1Matrix Additional and Subtraction Presentation 2Scalar Multiplication Presentation 3Matrix Multiplication 1 Presentation 4Matrix Multiplication 2 Presentation 5Determinants Presentation 6Inverse Matrices Presentation 7Solving Equations Presentation 8Geometrical Transformations Presentation 9Geometric Transformations: Example

2 Unit 39 39.1 Matrix Additional and Subtraction

3 If a matrix has m rows and n columns, we say that its dimensions are m x n. For example is a 2 x 2 matrix is a 2 x 3 matrix You can only add and subtract matrices with the same dimensions; you do this by adding and subtracting their corresponding elements. ? ?

4 Example 1 (a) (b) ? ? ? ? ? ? ? ? ? ?

5 Example 2 Ifwhat are the values of a, b, c and d? Solution Subtracting gives Hence ? ? ? ? ? ? ? ?

6 Unit 39 39.2 Scalar Multiplication

7 For scalar multiplication, you multiply each element of the matrix by the scalar (number) so Example If then ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ?

8 Unit 39 39.3 Matrix Multiplication 1

9 ? ? ? You can multiply two matrices, A and B, together and write only if the number of columns of A = number of rows of B; that is, if A has dimension m x n and B has dimension n x k, then the resulting matrix, C, has dimensions m x k. To find, C, we multiply corresponding elements of each row of A by elements of each column of B and add. The following examples show you how the calculation is done. Example If and, then A is a 2 x 2 matrix and B is a 2 x 1 matrix, so C = AB is defined and is a 2 x 1 matrix, given by: ? ? ?

10 Unit 39 39.4 Matrix Multiplication 2

11 Here we show a matrix multiplication that is not commutative Considerand First we calculate AB. ? ? ? ? ? ? ? ? ? ? ? ?

12 Is AB = BA? No Hence matrix multiplication is NOT commutative Here we consider a matrix multiplication that is not commutative Considerand And now for BA. ? ? ? ? ? ? ? ? ? ? ? ? ?

13 Unit 39 39.5 Determinants

14 ? For a 2 x 2 square matrix its determinant is the number defined by Example 1 What is detA if ? Solution ? ? ? ?

15 ? ? ? ? For a 2 x 2 square matrix its determinant is the number defined by Example 2 Ifwhat is the value of x that would make detM = 0 ? Solution ? ? A matrix, M, for which detM = 0 is called a singular matrix.

16 Unit 39 39.6 Inverse Matrices

17 For a 2 x 2 matrix, M, its inverse, is defined by You can always find the inverse of M if it is non-singular, that is. For Example If find and verify that Solution Hence ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? where

18 Unit 39 39.7 Solving Equations

19 You can write the simultaneous equation In the formwhen You can solve for X by multiplying by This givesor So we first need to find. Now and Hence ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ?

20 Unit 39 39.8 Geometrical Transformations

21 You can use matrices to describe transformations. We write where is transformed into Lets look at the common transformations

22 ? ? ? ?

23 ? ? ?

24 ?

25 Unit 39 39.9 Geometric Transformations: Example

26 Example A triangle, XYZ, with coordinates X (4, 5), Y(-3, 2) and Z(-1, 4) is mapped onto triangle X ʹ Y ʹ Z ʹ by a transformation (a)Calculate the coordinates of the vertices of triangle X ʹ Y ʹ Z ʹ Solution ? ? ? ? ? ? i.e.

27 Example A triangle, XYZ, with coordinates X (4, 5), Y(-3, 2) and Z(-4, 4) is mapped onto triangle X ʹ Y ʹ Z ʹ by a transformation ? ? ? ? (b)A matrixmaps triangle X ʹ Y ʹ Z ʹ onto triangle X ʹʹ Y ʹʹ Z ʹʹ. Determine the 2 x 2 matrix, Q, which maps triangle XYZ onto X ʹʹ Y ʹʹ Z ʹʹ. Solution X ʹʹ = NX ʹ = NMX so X ʹʹ = QX where

28 Example A triangle, XYZ, with coordinates X (4, 5), Y(-3, 2) and Z(-4, 4) is mapped onto triangle X ʹ Y ʹ Z ʹ by a transformation (c)Show that the matrix which maps triangle X ʹʹ Y ʹʹ Z ʹʹ back onto XYZ is equal to Q. Solution so QX ʹʹ = X and similarly QY ʹʹ = Y and QZ ʹʹ = Z Thus Q maps X ʹʹ Y ʹʹ Z ʹʹ back to XYZ ? ? ? ? ? ? ? ? ? ? ? ? ?

Download ppt "Unit 39 Matrices Presentation 1Matrix Additional and Subtraction Presentation 2Scalar Multiplication Presentation 3Matrix Multiplication 1 Presentation."

Similar presentations

Fundamentals of matrices

Fundamentals of matrices
8.4 Matrix Operations Day 1 Thurs May 7 Do Now Solve X – 2y = -6 3x + 4y = 7.

8.4 Matrix Operations Day 1 Thurs May 7 Do Now Solve X – 2y = -6 3x + 4y = 7.
4.2 Adding and Subtracting Matrices 4.3 Matrix Multiplication

4.2 Adding and Subtracting Matrices 4.3 Matrix Multiplication
Chapter 7 Matrix Mathematics Matrix Operations Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Chapter 7 Matrix Mathematics Matrix Operations Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Row 1 Row 2 Row 3 Row m Column 1Column 2Column 3 Column 4.

Row 1 Row 2 Row 3 Row m Column 1Column 2Column 3 Column 4.
4.2 Operations with Matrices Scalar multiplication.

4.2 Operations with Matrices Scalar multiplication.
MATRICES Adapted from presentation found on the internet. Thank you to the creator of the original presentation!

MATRICES Adapted from presentation found on the internet. Thank you to the creator of the original presentation!
Matrix Entry or element Rows, columns Dimensions Matrix Addition/Subtraction Scalar Multiplication.

Matrix Entry or element Rows, columns Dimensions Matrix Addition/Subtraction Scalar Multiplication.
Chapter 4 Matrices By: Matt Raimondi.

Chapter 4 Matrices By: Matt Raimondi.
Row 1 Row 2 Row 3 Row m Column 1Column 2Column 3 Column 4.

Row 1 Row 2 Row 3 Row m Column 1Column 2Column 3 Column 4.
Chapter 8 Matrices and Determinants Copyright © 2014, 2010, 2007 Pearson Education, Inc. 1 8.3 Matrix Operations and Their Applications.

Chapter 8 Matrices and Determinants Copyright © 2014, 2010, 2007 Pearson Education, Inc Matrix Operations and Their Applications.
Overview Definitions Basic matrix operations (+, -, x) Determinants and inverses.

Overview Definitions Basic matrix operations (+, -, x) Determinants and inverses.
Matrices. A matrix, A, is a rectangular collection of numbers. A matrix with “m” rows and “n” columns is said to have order m x n. Each entry, or element,

Matrices. A matrix, A, is a rectangular collection of numbers. A matrix with “m” rows and “n” columns is said to have order m x n. Each entry, or element,
Copyright © 2013, 2009, 2005 Pearson Education, Inc. 1 5 Systems and Matrices Copyright © 2013, 2009, 2005 Pearson Education, Inc.

Copyright © 2013, 2009, 2005 Pearson Education, Inc. 1 5 Systems and Matrices Copyright © 2013, 2009, 2005 Pearson Education, Inc.
1 C ollege A lgebra Systems and Matrices (Chapter5) 1.

1 C ollege A lgebra Systems and Matrices (Chapter5) 1.
Unit 6 : Matrices.

Unit 6 : Matrices.
10.4 Matrix Algebra 1.Matrix Notation 2.Sum/Difference of 2 matrices 3.Scalar multiple 4.Product of 2 matrices 5.Identity Matrix 6.Inverse of a matrix.

10.4 Matrix Algebra 1.Matrix Notation 2.Sum/Difference of 2 matrices 3.Scalar multiple 4.Product of 2 matrices 5.Identity Matrix 6.Inverse of a matrix.
Matrices A matrix is a table or array of numbers arranged in rows and columns The order of a matrix is given by stating its dimensions. This is known as.

Matrices A matrix is a table or array of numbers arranged in rows and columns The order of a matrix is given by stating its dimensions. This is known as.
AIM: How do we perform basic matrix operations? DO NOW:  Describe the steps for solving a system of Inequalities  How do you know which region is shaded?

AIM: How do we perform basic matrix operations? DO NOW:  Describe the steps for solving a system of Inequalities  How do you know which region is shaded?
If A and B are both m × n matrices then the sum of A and B, denoted A + B, is a matrix obtained by adding corresponding elements of A and B. add these.

If A and B are both m × n matrices then the sum of A and B, denoted A + B, is a matrix obtained by adding corresponding elements of A and B. add these.

Similar presentations

Ads by Google