2. 5.1 Objectives Prove and apply theorems about perpendicular bisectors.
Prove and apply theorems about angle bisectors.

3. When a point is the same distance from two or more
objects, the point is said to be equidistant from
the objects. Triangle congruence theorems can be
used to prove theorems about equidistant points.
A locus is a set of points that satisfies a given condition. The perpendicular bisector of a segment can be defined as the locus of points in a plane that are equidistant from the endpoints of the segment.

5. Example 1A: Applying the Perpendicular Bisector Theorem and Its Converse
Find each measure. MN
MN = LN
 Bisector Thm.
MN = 2.6
Substitution

6. Example 1C: Applying the Perpendicular Bisector Theorem and Its Converse
Find each measure. TU
TU = UV
 Bisector Thm.
3x + 9 = 7x – 17
Substitution
9 = 4x – 17
Subtraction POE
26 = 4x
Addition POE.
6.5 = x
Division POE.
So TU = 3(6.5) + 9 = 28.5.

7. Check It Out! Example 1b
Find the measure.
Given that DE = 20.8, DG = 36.4, and EG =36.4, which Theorem would you use to find EF?
Since DG = EG and , is the perpendicular bisector of by the Converse of the Perpendicular Bisector Theorem.

8. Remember that the distance between a point and a line is the length of the perpendicular segment from the point to the line.

9. Example 2A: Applying the Angle Bisector Theorem
Find the measure. BC
BC = DC
 Bisector Thm.
BC = 7.2
Substitution
Find the measure.
mEFH, given that mEFG = 50°.
Since EH = GH,
and , bisects
EFG by the Converse
of the Angle Bisector Theorem.

10. Example 2C: Applying the Angle Bisector Theorem
Find mMKL.
, bisects JKL
Since, JM = LM, and
by the Converse of the Angle
Bisector Theorem.
mMKL = mJKM
Def. of  bisector
3a + 20 = 2a + 26
Substitution.
a + 20 = 26
Subtraction POE
a = 6
Subtraction POE
So mMKL = [2(6) + 26]° = 38°

11. Check It Out! Example 2a
Given that mWYZ = 63°, XW = 5.7, and ZW = 5.7, find mXYZ.
mWYZ + mWYX = mXYZ
mWYZ = mWYX
mWYZ + mWYZ = mXYZ
2mWYZ = mXYZ
2(63°) = mXYZ
126° = mXYZ

12. Example 4: Writing Equations of Bisectors in the Coordinate Plane
Write an equation in slope – intercept form for the perpendicular bisector of the segment with endpoints C(6, –5) and D(10, 1).

13. 5.2 Objectives
Prove and apply properties of perpendicular bisectors of a triangle.
Prove and apply properties of angle bisectors of a triangle.

14. The perpendicular bisector of a side of a triangle does not always pass through the opposite vertex.
Helpful Hint

15. When three or more lines intersect at one point, the lines are said to be concurrent. The point of concurrency is the point where they intersect. In the construction, you saw that the three perpendicular bisectors of a triangle are concurrent. This point of concurrency is the circumcenter of the triangle.

16. The circumcenter can be inside the triangle, outside the triangle, or on the triangle.

17. The circumcenter of ΔABC is the center of its circumscribed circle
The circumcenter of ΔABC is the center of its circumscribed circle. A circle that contains all the vertices of a polygon is circumscribed about the polygon.

18. Example 1: Using Properties of Perpendicular Bisectors
DG, EG, and FG are the perpendicular bisectors of ∆ABC. Find GC.
G is the circumcenter of ∆ABC. By the Circumcenter Theorem, G is equidistant from the vertices of
∆ABC.
GC = CB
Circumcenter Thm.
GC = 13.4
Substitute 13.4 for GB.

19. Example
Find GM.
MZ is a perpendicular bisector of ∆GHJ.
GM = MJ
GM = 14.5
Find GK.
KZ is a perpendicular bisector of ∆GHJ.
GK = 18.6
GK = KH
Find JZ.
Z is the circumcenter of ∆GHJ. By the Circumcenter Theorem, Z is equidistant from the vertices of ∆GHJ.
JZ = GZ
JZ = 19.9

20. Example 2: Finding the Circumcenter of a Triangle
Find the circumcenter of ∆HJK with vertices H(0, 0), J(10, 0), and K(0, 6).
Step 1 Graph.
Step 2 Find equations for two perpendicular bisectors.
The perpendicular bisector of HJ is x = 5, and the perpendicular bisector of HK is y = 3.
Step 3 Find the intersection of the two equations.
(5, 3) is the circumcenter of ∆HJK.

21. Check It Out! Example 2
Find the circumcenter of ∆GOH with vertices G(0, –9), O(0, 0), and H(8, 0) .
Step 2 Find equations for two perpendicular bisectors.
Step 1 Graph.
The perpendicular bisector of GO is y = –4.5, and the perpendicular bisector of OH is
x = 4.
Step 3 Find the intersection of the two equations.
The lines intersect at (4, –4.5), the circumcenter of ∆GOH.

22. A triangle has three angles, so it has three angle bisectors
A triangle has three angles, so it has three angle bisectors. The angle bisectors of a triangle are also concurrent. This point of concurrency is the incenter of the triangle .

23. Unlike the circumcenter, the incenter is always inside the triangle.

24. The incenter is the center of the triangle’s inscribed circle
The incenter is the center of the triangle’s inscribed circle. A circle inscribed in a polygon intersects each line that contains a side of the polygon at exactly one point.

25. Example 3A: Using Properties of Angle Bisectors
MP and LP are angle bisectors of ∆LMN. Find the distance from P to MN.
MP and LP are angle bisectors of ∆LMN. Find mPMN.

26. Example 4
A city plans to build a firefighters’ monument in the park between three streets. Draw a sketch to show where the city should place the monument so that it is the same distance from all three streets. Justify your sketch.
By the Incenter Thm., the incenter of a ∆ is equidistant from the sides of the ∆. Draw the ∆ formed by the streets and draw the  bisectors to find the incenter, point M. The city should place the monument at point M.

27. Homework
5.1 #12-17 all, 20, 22, 26-28all
5.2 #12-19all, 22, 23, 26, 40, 41