Vector Notation: AB represents the vector from point A to point B on a graph. The vector can be computed by B A.



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1 Linear Transformations Prepared by: Robin Michelle King A transformation of an object is a change in position or dimension (or both) of the object. The resulting object after the transformation is called the image. If the image of the object has the same dimensions as the object, the transformation is called a congruency. Two polygons are said to be similar when their corresponding interior angles are the same. Vector Notation: AB represents the vector from point A to point B on a graph. The vector can be computed by B A. Types of Transformations: Translation: A translation is a transformation of an object in which each point of the object moves the same distance and in the same direction. Translations may occur in any direction. Properties of Translations: A translation preserves the length and[ slope of a line. h A translation by a vector of the form shifts the k x-coordinate of each point by h units, and the y-coordinate of each point by k units. Reflection: A reflection is a transformation of an object that produces a mirror image of the object with respect to a line. The line about which the object is reflected is called the axis of symmetry. Properties of Reflections: A reflection preserves length but does not preserve slope or orientation of a line. A reflection in the line y = 0 (x-axis) changes the point (x, y) to (x, y) A reflection in the line x = 0 (y-axis) changes the point (x, y) to ( x, y) A reflection in the line y = x changes the point (x, y) to (y, x) A reflection in the line y = x changes the point (x, y) to ( y, x) Rotation: A rotation is a transformation where the object is turned. The point about which the object is rotated is called the center of rotation. Properties of Rotations: A rotation preserves length but does not necessarily preserve slope of a line. A 90 rotation ( 1 4 turn) anticlockwise about the origin changes the point (x, y) to ( y, x). A 180 rotation ( 1 2 turn) clockwise or anticlockwise about the origin changes the point (x, y) to ( x, y). A 270 rotation ( 4 turn) anticlockwise changes about the origin the point (x, y) to (y, x).

2 Enlargements and Reductions: Enlargements and reductions are transformations in which the object is made larger or made smaller by a factor of k. The factor k is called the scale factor. Properties of Enlargement: These transformations preserve slope but do not preserve length or area (except when k =1) If k > 1 the transformation is an enlargement and the image is larger than the original. If 0 < k < 1, the transformation is a reduction and the image is smaller than the original. if k < 0, the object is also reflected across the x axis. Composition of Linear Transformations: When a question requires multiple linear transformations to be performed, perform each linear transformation one at a time to find the image points, or line, after each transformation. Then the image can be used to perform the next linear transformation. Finding a Matrix of a Linear Transformation: To find the matrix of a linear transformation given two points, (x 1, y 1 ) and (x 2, y 2 ), and (x 1, y 1 ) and (x 2, y 2 ): [ a b 1. Let the transformation matrix be represented by: T = c d 2. Multiply each point by the transformation matrix T and set it equal to its image. This will create four equations of the form: ax 1 + by 1 = x 1 ax 2 + by 2 = x 2 cx 1 + dy 1 = y 1 cx 2 + dy 2 = y 2. Then, using each pair of equations, use substitution or elimination to solve for a, b, c, and d. Once the transformation matrix is found, we can determine the image of any point by multiplying the point by the transformation matrix. (ie. [T x) Note: Matrix multiplication is not commutative. This means that XT T X To multiply a 2 2 matrix (a matrix with 2 rows and 2 columns) by a 2 1 matrix (a matrix with 2 rows and 1 column): [ a b c d [ x y = [ ax + by cx + dy Linear Transformation of a Line: To find the equation of the image of a line under a translation, reflection, rotation, or enlargement: 1. Find the coordinates of any two points on the line. 2. Find the coordinates of the images of the two points from step 1.. Use the two image points from step 2 to find the slope of the image line. 4. Use one of the image points, the slope from step, and the equation of a line to find the equation of the image line.

Examples: 1. a) Suppose that A(1, 2), B( 2, 1) and C( 6, 2m) are three points in the xy plane and that m is a constant, find: i) [ 4 BA ii) The value of m if BC = 5 b) A(, 6), B(6, 2), and C(x, y) are three points in the xy plane. If 1 OA + OB + OC = AB, find the coordinates of C. Solution: a) i) BA = A B = (1, 2) ( 2, 1) = (1 ( 2), 2 ( 1)) = (, ) ii) BC = C B ( 4, 5) = ( 6, 2m) ( 2, 1) ( 4, 5) = ( 6 ( 2), 2m ( 1)) ( 4, 5) = ( 4, 2m + 1) 5 = 2m + 1 Equate the y components to solve for m 4 = 2m m = 2 b) 1 OA + OB + OC = AB 1 (A O) + (B O) + (C O) = B A 1 [(, 6) (0, 0) + [(6, 2) (0, 0) + [(x, y) (0, 0) = (6, 2) (, 6) 1 (, 6) + (6, 2) + (x, y) = (6, 2 ( 6)) (1, 2) + (6, 2) + (x, y) = (, 4) (7, 4) + (x, y) = (, 4) (x, y) = (, 4) (7, 4) (x, y) = ( 4, 8) 2. a) Plot the triangle ABC with vertices A(1, 1), B(4, 1), and C(2, ) [ b) Draw the image A 1 B 1 C 1 of ABC when it has been translated by the vector 2 c) Draw the image A 2 B 2 C 2 of ABC when it has been rotated anticlockwise 90 about the origin. d) Draw the image A B C of ABC when it is reflected across the line y = 0. e) Draw the image A 4 B 4 C 4 of ABC when it has been enlarged by a scale factor of 2. Solution: a)

4 b) We can find A 1, B 1, and C 1 by translating the x coordinates units and the y coordinates 2 units. A(1, 1) A 1 (1 +, 1 + 2) = (4, ) B(4, 1) B 1 (4 +, 1 + 2) = (7, ) C(2, ) C 1 (2 +, + 2) = (5, 5) c) We can find A 1, B 1, and C 1 by changing each (x, y) to ( y, x). A(1, 1) A 1 ( 1, 1) B(4, 1) B 1 ( 1, 4) C(2, ) C 1 (, 2) d) We can find A 1, B 1, and C 1 by negating the y coordinate of each pair. A(1, 1) A 1 (1, 1) B(4, 1) B 1 (4, 1) C(2, ) C 1 (2, ) e) We can find A 1, B 1, and C 1 by multiplying both the x and y coordinates by the scale factor (2). A(1, 1) A 1 (2 1, 2 1) = (2, 2) B(4, 1) B 1 (2 4, 2 1) = (8, 2) C(2, ) C 1 (2 2, 2 ) = (4, 6)

5. a) Graph the line 2x + y 6 = 0 b) Find the equation of the image of the line in part (a) under a 90 anticlockwise rotation about the origin. c) Graph the image line on the same axis as part (a). Solution: a) b) To find the equation of the image line, we first start by finding two points that lie on the original line. Let s choose (0, 6) and ( 2, 10). Then we find the image of these two points under the transformation (a 90 anticlockwise rotation). The image point of (0, 6) under the rotation is ( 6, 0) and the image point of ( 2, 10) under the rotation is ( 10, 2). We can now use the two image points to find the slope of our image line. Slope = y x 0 ( 2) = 6 ( 10) = 2 4 = 1 2 Then, we can use the slope and one point to find the equation of the image line. Let s use ( 6, 0). The equation of a line is y = mx+b where m is slope and b is the y-intercept y = mx + b y = 1 x + b plug in ( 6, 0) and solve for b 2 0 = 1 2 ( 6) + b 0 = + b b = So the equation of the image line is: y = 1 2 x + or y 1 2 x = 0 c)

6 4. A linear transformation T maps A(1, 2) to A 1 ( 4, 6) and B(6, ) to B 1 (, 0). Find each of the following: a) The matrix of T. b) The image of the point K( 5, 2) under T. Solution: [ a b a) Let T=. Then, c d [ [ [ a b 1 4 = gives us the following equations: c d 2 6 a + 2b = 4... (1) c + 2d [ = 6 [... [ (2) a b 6 and = gives us: c d 0 6a + d =... () 6c + d = 0... (4) Substitute (1) into (): 6( 4 2b) + b = 24 12b + b = Substitute b = into (1) 9b = 27 b = a + 2( ) = 4 a 6 = 4 [ a = 2 2 Therefore, T = 2 4 [ [ [ 2 5 4 b) = 2 4 2 2 Substitute (2) into (4): 6(6 2d) + d = 0 6 12d + d = 0 9d = 6 d = 4 Substitute d = 4 into (2) c + 2(4) = 6 c + 8 = 6 c = 2

7 Exercises: 1. Given that P (, 1), Q(6, 1), and R(, m) are three points in the xy plane and that m is a constant, find: a) P Q b) The value of m if P R = c) OP + OQ + 1 OR [ 6 5 2. Given that A( 2, 4), B(5, [ 1), and C(x, y) are three points in the xy plane. 2 If AB + AC + BC =, find the coordinates of C. 2. In DEF, [ DE = 2 and F E = [ 6 4. Find DF. 4. a) Plot the triangle RST with vertices R( 1, 0), S(, 2), and T ( 4, ) [ 1 b) Draw the image R 1 S 1 T 1 of RST when it has been translated by the vector c) Draw the image R 2 S 2 T 2 of RST when it has been rotated clockwise 90 about the origin. d) Draw the image R S T of RST when it is reflected across the line x = 2. e) Draw the image R 4 S 4 T 4 of RST when it has been enlarged by a scale factor of 1 2 about the origin. 5. a) Graph the line 2x + y 6 = 0. b) Determine the equation of the image of the line from part (a) under a 90 anticlockwise rotation. c) Graph the image line on the same axis as part (a). 6. Draw each of the following on the same graph, clearly indicating the coordinates of each vertex. a) A quadrilateral ABCD has vertices A(2, 2), B(6, 2), C(8, 8), and D(4, 8). b) The image A 1 B 1 C 1 D 1 of quadrilateral ABCD under a reflection in the line y = x. c) Find the equation of the line D 1 7. From Examiners Report [ 2006. 4 a) Given that A = and X = (, 4), evaluate XA. 2 5 b) A linear transformation T maps A(, 4) to A 1 ( 6, 8) and B(5, 2) to B 1 ( 10, 4). Find each of the following: i) The matrix of T. ii) The image of the point K(1, 1) under T. 8. P QR has coordinates P (, 1), Q( 2, 4), and R(0, 4). If M is a reflection in the line x = 1, R is a clockwise rotation of 90 about the point (2, 0) and E is an enlargement by a scale factor of 1 2 about the origin. Find the image of P QR after: a) M b) R c) M followed by R d) R followed by M e) E

8 9. Determine the equation of the [ line x 5y 15 = 0 under the following linear transformations: 2 a) A translation by the vector. b) Reflection in the line y = x. c) A 270 anticlockwise rotation. 10. A 1 (5, 5), B 1 ( 5, 10), C 1 (0, 20) are the images of A(2, 2), B( 2, 4), and C(0, 8) after a transformation F. a) Draw the triangles ABC and A 1 B 1 C 1 on the same graph. b) Describe fully the transformation F. c) Find the coordinates of the image of ABC after a rotation of 270 clockwise about the point (, 2) 11. From Examiners Report 2006. a) Using a scale of 2 cm to 2 units on both axes draw, on graph paper, two perpendicular axes 0x and 0y for 8 x 8 and 8 y 8. b) Draw the P QR with vertices P (2, 5), Q(2, 1), and R(8, 4). c) Describe fully two different transformations that map P to Q. d) Draw the image P 1 Q 1 R 1 of P QR under a 90 anticlockwise rotation about the origin. e) Find the vector P P 1 12. W XY Z is a quadrilateral with vertices W (1, 1), X(2, 1), Y (4, 0), and Z(, 1). a) Draw W XY Z and clearly label each of its vertices. b) Draw the image W 1 X 1 Y 1 Z 1 of W XY Z under a reflection in the line y = 2. Clearly label the coordinates of each vertex. c) S is a transformation which maps W XY Z onto quadrilateral W 2 X 2 Y 2 Z 2 with vertices W 2 (-5,-), X 2 (-7,-), Y 2 (-8,-2), and Z 2 (-6,-1). Draw W 2 X 2 Y 2 Z 2 and describe the transformation S fully. 1. a) On the same axes, graph the two lines L 1 and L 2 where L 1 : 2x 5y+10 = 0 and L 2 : 2x 5y 10 = 0 b) Describe a possible transformation in which L 1 is the image of L 2 assuming that the transformation is a: i) translation ii) reflection iii) rotation 14. a) Draw the P QR with vertices P (1, 2), Q(, 4), R(6, 1). b) Draw the image: i) P 1 Q 1 R 1 of P QR under a reflection in the x-axis ii) P 2 Q 2 R 2 of P 1 Q 1 R 1 under a reflection in the y-axis iii) P Q R of P QR under a 90 anticlockwise rotation about the origin c) Describe fully, the single transformation that takes: i) P QR to P 2 Q 2 R 2 ii) P 2 Q 2 R 2 to P Q R 15. a) Graph the line y = 2 x b) On the same axes, graph the line in part (a) after it has been reflected in the line y = x. c) Determine the equation of the line in part (b). d) Determine the matrix of the linear transformation.

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