1. 4.1 Vocabulary Transformation Preimage Image Isometry
(1)Translation, (2)Reflection, (3)Rotation
Vector

2. A transformation is a change in the position, size, or shape of a figure. The original figure is called the preimage. The resulting figure is called the image. A transformation maps the preimage to the image. Arrow notation () is used to describe a transformation, and primes (’) are used to label the image.

3. An isometry is a transformation that does not change the shape or size of a figure. Reflections, Translations, and Rotations are all isometries. Isometries are also called
congruence transformations or rigid motions.
A translation is a rigid transformation where all the points of a figure are moved the same distance in the same direction. A translation is an isometry, so the image of a translated figure is congruent to the preimage.

4. Recall that a vector in the coordinate plane can be written as <a, b>, where a is the horizontal change and b is the vertical change from the initial point to the terminal point.
Vector r <3, –1> “translates” all the x values to
x + 3, and all the y values to y - 1 .
The vector from point A to point B can also be written as AB (it looks like a Ray but it stops at B)

6. Example 1: Drawing Translations in the Coordinate Plane
Translate the triangle with vertices D(–3, –1), E(5, –3), and F(–2, –2) along the vector s = <3, –1>.
The image of (x, y) is (x + 3, y – 1).
D(–3, –1) D’(–3 + 3, –1 – 1) = D’(0, –2)
E(5, –3) E’(5 + 3, –3 – 1) = E’(8, –4)
F(–2, –2) F’(–2 + 3, –2 – 1) = F’(1, –3)
Graph the preimage and the image.

7. The image of (x, y) is (x – 3, y – 3).
Example 2
Translate quadrilateral with vertices R(2, 5), S(0, 2), T(1,–1), and U(3, 1) along the vector m =<–3, –3>.
The image of (x, y) is (x – 3, y – 3).
R(2, 5) R’(2 – 3, 5 – 3)
= R’(–1, 2) R S T U R’ S’ T’ U’
S(0, 2) S’(0 – 3, 2 – 3)
= S’(–3, –1)
T(1, –1) T’(1 – 3, –1 – 3)
= T’(–2, –4)
U(3, 1) U’(3 – 3, 1 – 3)
= U’(0, –2)
Graph the preimage and the image.

8. Example 3: Recreation Application
A sailboat has coordinates 100° west and 5° south. The boat sails 50° due west. Then the boat sails 10° due south. What is the boat’s final position? What single translation vector moves it from its first position to its final position?

9. Compositions of Transformations
Two or more RIGID transformations may be combined into a single rigid transformation. To perform multiple translations they may be done sequentially or as a vector sum of the individual translations.
To combine multiple vectors into a single resultant vector simply add the x-components and add the
y-components.
Given u =<-2, 4> and s = <3, 5>, u + s = <1, 9>

10. Example 4: Translation Composition
Translate the triangle with vertices D(–3, –1), E(5, –3), and F(–2, –2) along the vector s = <3, –1>. Then perform a second translation by u =<-2, 4>.
First translation: D D’ (0, -2), E E’ (8, -4) and F F’ (1, -3)
Second: D’ D” (-2, 2), E’ E” (6, 0), and F’ F” (-1, 1)
OR: r = s + u, r = <1, 3>. Translating by <1, 3> Gives:
D D” (-2, 2), E E” (6, 0) and F F” (-1, 1)

11. Lesson Quiz:
Translate the figure with the given vertices along the given vector.
1. G(8, 2), H(–4, 5), I(3,–1); v = <–2, 0>
2. S(0, –7), T(–4, 4), U(–5, 2), V(8, 1); t =<–4, 5>
3. A rook on a chessboard has coordinates (3, 4). The rook is moved up two spaces. Then it is moved three spaces to the left. What is the rook’s final position? What single vector moves the rook from its starting position to its final position?