200 likes | 224 Views
This chapter explains rotations, compositions of transformations, and provides examples and exercises to practice graphing images after rotations and compositions.
E N D
Chapter 9.3 and 9.4 Rotations and Compositions of Transformations
Rotations • A rotation is a turn that moves every point of an image through a specified angle and direction about a fixed point.
Rotate 90° • Graph the point A (-2, 4) • Graph the image of A’ under a rotation of 90° counterclockwise about the origin
Rotate 180° • Graph the point B (2, -5) • Graph the image of B’ under a rotation of 180° counterclockwise about the origin
Rotate 270° • Graph the point C (-4, -6) • Graph the image of C’ under a rotation of 270° counterclockwise about the origin
Example 3 Rotations in the Coordinate Plane Hexagon DGJTSR is shown below. What is the image of point T after a 90 counterclockwise rotation about the origin? A (5, –3) B (–5, –3) C (–3, 5) D (3, –5)
Example 3 Triangle PQR is shown below. What is the image of point Q after a 90° counterclockwise rotation about the origin? A. (–5, –4) B. (–5, 4) C. (5, 4) D. (4, –5)
Rotations in the Coordinate Plane Triangle DEF has vertices D(–2, –1), E(–1, 1), and F(1, –1). Graph ΔDEF and its image after a rotation of 90° counterclockwise about the origin.
Rotations in the Coordinate Plane Line segment XY has vertices X(0, 4) and Y(5, 1). Graph XY and its image after a rotation of 270° counterclockwise about the origin.
Composition of transformations • When a transformation is applied to a figure and then another transformation is applied to its image, the result is called a composition of transformations.
Graph a Glide Reflection Quadrilateral BGTS has vertices B(–3, 4), G(–1, 3), T(–1 , 1), and S(–4, 2). Graph BGTS and its image after a translation along 5, 0 and a reflection in the x-axis.
Quadrilateral RSTU has vertices R(1, –1), S(4, –2), T(3, –4), and U(1, –3). Graph RSTU and its image after a translation along –4, 1and a reflection in the x-axis. Which point is located at (–3, 0)? A.R' B.S' C.T' D.U'
Graph Other Compositions of Isometries ΔTUV has vertices T(2, –1), U(5, –2), and V(3, –4). Graph ΔTUV and its image after a translation along –1 , 5 and a rotation 180° about the origin.
ΔJKL has vertices J(2, 3), K(5, 2), and L(3, 0). Graph ΔTUV and its image after a translation along 3, 1and a rotation 180° about the origin. What are the new coordinates of L''? A. (–3, –1) B. (–6, –1) C. (1, 6) D. (–1, –6)
Example 4 Describe Transformations A. LANDSCAPING Describe the transformations that are combined to create the brick pattern shown.
Example 4 Describe Transformations B. LANDSCAPING Describe the transformations that are combined to create the brick pattern shown.
Example 4 A. What transformation must occur to the brick at point M to further complete the pattern shown here? A. The brick must be rotated 180° counterclockwise about point M. B. The brick must be translated one brick width right of point M. C. The brick must be rotated 90° counterclockwise about point M. D. The brick must be rotated 360° counterclockwise about point M.
Example 4 B. What transformation must occur to the brick at point M to further complete the pattern shown here? A. The two bricks must be translated one brick length to the right of point M. B. The two bricks must be translated one brick length down from point M. C. The two bricks must be rotated 180° counterclockwise about point M. D. The two bricks must be rotated 90° counterclockwise about point M.