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Copyright © Cengage Learning. All rights reserved. Parallel Lines 2 2 Chapter.

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1 Copyright © Cengage Learning. All rights reserved. Parallel Lines 2 2 Chapter

2 Copyright © Cengage Learning. All rights reserved. Symmetry and Transformations 2.6

3 3 LINE SYMMETRY

4 4 Line Symmetry In the figure below, rectangle ABCD is said to have symmetry with respect to line ℓ because each point to the left of the line of symmetry or axis of symmetry has a corresponding point to the right; for instance, X and Y are corresponding points. Figure 2.38

5 5 Line Symmetry Definition A figure has symmetry with respect to a line ℓ if for every point X on the figure, there is a second point Y on the figure for which ℓ is the perpendicular bisector of XY. In particular, ABCD of Figure 2.38 has horizontal symmetry with respect to line ℓ ; that is, a vertical axis of symmetry leads to a pairing of corresponding points on a horizontal line. In Example 1, we see that a horizontal axis leads to vertical symmetry for points on ABCD.

6 6 Example 1 Rectangle ABCD in Figure 2.38 has a second line of symmetry. Draw this horizontal line (or axis) for which there is vertical symmetry. Figure 2.38

7 7 Example 1 – Solution Line m (determined by the midpoints of and ) is the desired line of symmetry. As shown in Figure 2.39(b), R and S are located symmetrically with respect to line m. Figure 2.39 (a)(b)

8 8 POINT SYMMETRY

9 9 Point Symmetry In Figure 2.41, rectangle ABCD is also said to have symmetry with respect to a point. As shown, point P is determined by the intersection of the diagonals of ABCD. Definition A figure has symmetry with respect to point P if for every point M on the figure, there is a second point N on the figure for which point P is the midpoint of Figure 2.41 (a) (b)

10 10 Point Symmetry On the basis of this definition, each point on ABCD in Figure 2.41(a) has a corresponding point that is the same distance from P but which lies in the opposite direction from P. In Figure 2.41(b), M and N are a pair of corresponding points. Even though a figure may have multiple lines of symmetry, a figure can have only one point of symmetry. Thus, the point of symmetry (when one exists) is unique.

11 11 Example 4 Which letter(s) shown below have point symmetry? M N P S X Solution: N, S, and X as shown all have point symmetry.

12 12 TRANSFORMATIONS

13 13 Transformations In the following material, we will generate new figures from old figures by association of points. In particular, the transformations included in this textbook will preserve the shape and size of the given figure; in other words, these transformations preserve lengths and angle measures and thus lead to a second figure that is congruent to the given figure. The types of transformations included are (1) the slide or translation, (2) the reflection, and (3) the rotation.

14 14 Transformations Slides (Translations) With this type of transformation, every point of the original figure is associated with a second point by locating it through a movement of a fixed length and direction. In Figure 2.43, ABC is translated to the second triangle (its image DEF) by sliding each point through the distance and in the direction that takes point A to point D. Figure 2.43

15 15 Transformations The background grid is not necessary to demonstrate the slide, but it lends credibility to our claim that the same length and direction have been used to locate each point.

16 16 Example 6 Slide XYZ horizontally in Figure 2.44 to form RST. In this example, the distance (length of the slide) is XR. Solution: Figure 2.44

17 17 Transformations In Example 6, XYZ  RTS. In every slide, the given figure and the produced figure (its image) are necessarily congruent. In Example 6, the correspondence of vertices is given by X R, Y T, and Z S. Reflections With the reflection, every point of the original figure is reflected across a line in such a way as to make the given line a line of symmetry. Each pair of corresponding points will lie on opposite sides of the line of reflection and at like distances.

18 18 Transformations In Figure 2.46, obtuse triangle MNP is reflected across the vertical line to produce the image GHK. The vertex N of the given obtuse angle corresponds to the vertex H of the obtuse angle in the image triangle. Figure 2.46

19 19 Transformations With the vertical line as the axis of reflection, a drawing such as Figure 2.46 is sometimes called a horizontal reflection, since the image lies to the right of the given figure. It is possible for the line of reflection to be horizontal or oblique (slanted).

20 20 Example 8 Draw the reflection of right ABC a) across line ℓ to form XYZ. b) across line m to form PQR.

21 21 Example 8 – Solution As shown in Figure 2.47 Figure 2.47 (a) (b)

22 22 Transformations Rotations In this transformation, every point of the given figure leads to a point (its image) by rotation about a given point through a prescribed angle measure. In Figure 2.50, ray AB rotates about point A clockwise through an angle of 30° to produce the image ray AC. This has the same appearance as the second hand of a clock over a five-second period of time. In this figure, A A and B C. Figure 2.50

23 23 Transformations As shown in Figure 2.50, the angle of rotation measures 30°; also the center of rotation is point A.

24 24 Example 11 In Figure 2.51, square WXYZ has been rotated counterclockwise about its center (intersection of diagonals) through an angle of 45° to form congruent square QMNP. What is the name of the eight-pointed geometric figure that is formed by the two intersecting squares?

25 25 Example 11 – Solution The eight-pointed figure formed is a regular octagram. Figure 2.51

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