1. TRANSFORMATIONS!

2. To transform something is to change it.
In geometry, there are specific ways to describe how a figure is changed.
Translation
Rotation
Reflection
Dilation

3. Renaming Transformations
We use __________ _______ to help name the original shapes.
Capitol letters
To name transformed shapes we use the same letters with a _____ symbol:
Prime
Before: PRE IMAGE
After: IMAGE

4. Translations are SLIDES.
A translation "slides" an object a fixed distance in a given direction. 
Translations are ISOMETRIC – which means they have the same size and the same shape!
Translations are
SLIDES.

5. Let's examine some translations related to coordinate geometry.
The example shows how each vertex moves the same distance in the same direction.

6. A Rotation is also ISOMETRIC
A rotation is a transformation that turns a figure about a fixed point called the ___________________. 
A Rotation is also ISOMETRIC
Center of rotation

7. This rotation is 90 degrees counterclockwise.
                                            
Clockwise
         
Counterclockwise

8. A Reflection is ISOMETRIC
A reflection can be seen in water, in a mirror, in glass, or in a shiny surface. 
A Reflection is ISOMETRIC

9. The line (where a mirror may be placed) is called the line of reflection.  The distance from a point to the line of reflection is the same as the distance from the point's image to the line of reflection.
A reflection can be thought of as a "flipping" of an object over the line of reflection.
                             
   
                           
If you folded the two shapes together line of reflection the two shapes would overlap exactly!

10. A dilation is NOT ISOMETRIC!
Why? A dilation used to create an image larger than the original is called an enlargement.  A dilation used to create an image smaller than the original is called a reduction.

11. TRANSLATIONS!

12. A vector has _______ and _________ – it tells you where to go!
The vector <7,4> tells your x value to change by +7 and your y value to change by + 4
length
direction

13. Using points P,E,N,T,A, translate them along the vector –5, –1.
P(1, 0), E(2, 2), N(4, 1), T(4, –1), and A(2, –2)
The vector indicates a translation 5 units left and 1 unit down.
(x, y) → (x – 5, y – 1)
P(1, 0) → (–4, –1)
E(2, 2) → (–3, 1)
N(4, 1) → (–1, 0)
T(4, –1) → (–1, –2)
A(2, –2) → (–3, –3)

14. EX 2: Translate GHJK with the vertices
G(–4, –2), H(–4, 3), J(1, 3), K(1, –2) along the vector 2, –2.
Choose the correct coordinates for G'H'J'K'.
A. G'(–6, –4), H'(–6, 1), J'(1, 1), K'(1, –4)
B. G'(–2, –4), H'(–2, 1), J'(3, 1), K'(3, –4)
C. G'(–2, 0), H'(–2, 5), J'(3, 5), K'(3, 0)
D. G'(–8, 4), H'(–8, –6), J'(2, –6), K'(2, 4)

15. The graph shows repeated translations that result in the animation of the raindrop.
Describe the translation of the raindrop from position 3 to position 4 using a translation vector < a , b >.
(–1 + a, –1 + b) or (–1, –4)
–1 + a = –1 –1 + b = –4
a = 0 b = –3
Answer: translation vector:

16. REFLECTIONS

17. What happens to points in a Reflection?
Name the points of the
PRE-IMAGE:
A ( , )
B ( , )
C ( , )
IMAGE:
A’ ( , )
B’ ( , )
C’ ( , )
What is the line of reflection?
How did the points change from the original to the reflection?

18. A reflection is always ____________from the ___________________!
equidistant
Line of reflection

19. EX 1: Reflect ABCD with vertices A(1, 1), B(3, 2), C(4, –1), and D(2, –3) across the x-axis:
Multiply the y-coordinate of each vertex by –1.
(x, y) → (x, –y)
A(1, 1) → A'(1, –1) B(3, 2) → B'(3, –2) C(4, –1) → C'(4, 1) D(2, –3) → D'(2, 3)

20. EX 2: Graph quadrilateral ABCD with vertices A(1, 1), B(3, 2), C(4, –1), and D(2, –3) and its reflected image in the y-axis.
Multiply the x-coordinate of each vertex by –1.
(x, y) → (–x, y)
A(1, 1) → A'(–1, 1) B(3, 2) → B'(–3, 2) C(4, –1) → C'(–4, –1) D(2, –3) → D'(–2, –3)

22. Ex 3: Given the Pre Image Quadrilateral ABCD with vertices
A(1, 1), B(3, 2), C(4, –1), and D(2, –3).
Graph ABCD and its image
under reflection of the line y = x.
Interchange the x- and y-coordinates of each vertex.
(x, y) → (y, x)
A(1, 1) → A'(1, 1) B(3, 2) → B'(2, 3) C(4, –1) → C'(–1, 4) D(2, –3) → D'(–3, 2)

23. It was reflected over the line y=x, since all of the
EX 4: Quadrilateral EFGH has vertices
E(–3, 1), F(–1, 3), G(1, 2), and H(–3, –1).
The quadrilateral was reflected, giving the image the coordinates:
How was the quadrilateral reflected?
E'(1, –3), F'(3, –1), G'(2, 1), H'(–1, –3)
It was reflected over the line y=x, since all of the
x and y values have been switched

24. DILATIONS

25. Dilations always involve a change in size.
                                              
How did the coordiates of the image compare to the coordinates of the pre image?

26. Enlargement Reduction
If k>1 the dilation is an _________________ If k<1 the dilation is a __________________ Does it make sense for k to be less than 0?
Reduction

27. EX 1: Trapezoid EFGH has vertices
E(–8, 4), F(–4, 8), G(8, 4) and H(–4, –8).
Graph the image of EFGH after a dilation centered at the origin with a scale factor (k) of
Multiply the x- and y-coordinates of each vertex by the scale factor,

28. Ex 2: Triangle ABC has vertices A(–2, -4), B(3, 2), C(0, 4)
Ex 2: Triangle ABC has vertices A(–2, -4), B(3, 2), C(0, 4). Graph the image of ABC after a dilation centered at the origin with a scale factor of 1.5.

30. Rotations and Symmetry

31. Rotation – a transformation that turns every point of a pre-image through a specified angle and direction about a fixed point, called the Center of Rotation.
P is the Center of rotation!

32. Angle of rotation – the angle between a pre-image point and its corresponding image point..
The Angle of Rotation from A to A’ is 90° Counterclockwise!

33. EX 1: For the diagram to the right, which description best identifies the rotation of triangle ABC around point Q?
A. 20° clockwise
B. 20° counterclockwise
C. 90° clockwise
D. 90° counterclockwise

34. Thankfully, we really only care about rotating three ways…

35. EX 2: Hexagon DGJTSR is shown below
EX 2: 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)

36. EX 3:
What is the image of point Q after a 90° counterclockwise rotation about the origin?
What is the image of point Q after a 180° counterclockwise rotation about the origin?
What is the image of point Q after a 270° counterclockwise rotation about the origin?
(–5, 4)
(-4, -5)
(5, -4)

37. Rotational Symmetry:
A figure in a plane has rotational symmetry if the figure can be mapped onto itself by a rotation of 180⁰ or less.
The figure above has rotational symmetry because it maps onto itself by a rotation of 90⁰.

38. When a figure can be rotated less than 360° and the image and pre-image are indistinguishable (the same)
Symmetry
Rotational: 120° 90° ° °
Lines of :
Symmetry?
360/3 = /4 = /6 = /8 = 45

39. Does the following shape have symmetry?
Lines of Symmetry?
_______________
Rotational Symmetry?

41. Day 5 Composites!

42. More than one transformation is happening!
Composite transformations mean:
More than one transformation is happening!
Original
Move 1
Move 2

43. EX 1: 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.

44. Step 1 translation along 5, 0
(x, y) → (x + 5, y)
B(–3, 4) → B'(2, 4)
G(–1, 3) → G'(4, 3)
S(–4, 2) → S'(1, 2)
T(–1, 1) → T'(4, 1)

45. Step 2 reflection in the x-axis
(x, y) → (x, –y)
B'(2, 4) → B''(2, –4)
G'(4, 3) → G''(4, –3)
S'(1, 2) → S''(1, –2)
T'(4, 1) → T''(4, –1)

46. Ex 2:
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, 1 and a reflection in the x-axis. Which point is located at (–3, 0)?
A. R'
B. S'
C. T'
D. U'

47. EX 3:
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.

48. Step 1 translation along –1 , 5
(x, y) → (x + (–1), y + 5)
T(2, –1) → T'(1, 4)
U(5, –2) → U'(4, 3)
V(3, –4) → V'(2, 1)

49. Step 2 rotation 180 about the origin
(x, y) → (–x, –y)
T'(1, 4) → T''(–1, –4)
U'(4, 3) → U''(–4, –3)
V'(2, 1) → V''(–2, –1)

50. EX 4: ΔJKL has vertices J(2, 3), K(5, 2), and L(3, 0)
EX 4: ΔJKL has vertices J(2, 3), K(5, 2), and L(3, 0). Graph ΔTUV and its image after a translation along 3, 1 and 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)