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Isosceles and Equilateral Triangles Lesson Presentation

Prove theorems and apply properties of isosceles and equilateral triangles using examples and practice problems.

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Isosceles and Equilateral Triangles Lesson Presentation

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  1. 4-8 Isosceles and Equilateral Triangles Lesson Presentation Holt Geometry

  2. 1. Find each angle measure. • True or False. If false explain. • 2. Every equilateral triangle is isosceles. • 3. Every isosceles triangle is equilateral. 60°; 60°; 60° True False; an isosceles triangle can have only two congruent sides.

  3. Objectives Prove theorems about isosceles and equilateral triangles. Apply properties of isosceles and equilateral triangles.

  4. Vocabulary legs of an isosceles triangle vertex angle base base angles

  5. Recall that an isosceles triangle has at least two congruent sides. The congruent sides are called the legs. The vertex angle is the angle formed by the legs. The side opposite the vertex angle is called the base, and the base angles are the two angles that have the base as a side. 3 is the vertex angle. 1 and 2 are the base angles.

  6. Reading Math The Isosceles Triangle Theorem is sometimes stated as “Base angles of an isosceles triangle are congruent.”

  7. The length of YX is 20 feet. Explain why the length of YZ is the same. Example 1: Astronomy Application The mYZX = 180 – 140, so mYZX = 40°. Since YZXX,∆XYZ is isosceles by the Converse of the IsoscelesTriangle Theorem. Thus YZ = YX = 20 ft.

  8. Example 2A: Finding the Measure of an Angle Find mF. mF= mD = x° Isosc. ∆ Thm. mF+ mD + mE = 180 ∆ Sum Thm. Substitute the given values. x+ x + 22 = 180 Simplify and subtract 22 from both sides. 2x= 158 Divide both sides by 2. x= 79 Thus mF = 79°

  9. Example 2B: Finding the Measure of an Angle Find mG. mJ= mG Isosc. ∆ Thm. Substitute the given values. (x+ 44) = 3x Simplify x from both sides. 44= 2x Divide both sides by 2. x= 22 Thus mG = 22° + 44° = 66°.

  10. Check It Out! Example 2A Find mH. mH= mG = x° Isosc. ∆ Thm. mH+ mG + mF = 180 ∆ Sum Thm. Substitute the given values. x+ x + 48 = 180 Simplify and subtract 48 from both sides. 2x= 132 Divide both sides by 2. x= 66 Thus mH = 66°

  11. Check It Out! Example 2B Find mN. mP= mN Isosc. ∆ Thm. Substitute the given values. (8y – 16) = 6y Subtract 6y and add 16 to both sides. 2y= 16 Divide both sides by 2. y= 8 Thus mN = 6(8) =48°.

  12. The following corollary and its converse show the connection between equilateral triangles and equiangular triangles.

  13. Example 3A: Using Properties of Equilateral Triangles Find the value of x. ∆LKM is equilateral. Equilateral ∆  equiangular ∆ The measure of each  of an equiangular ∆ is 60°. (2x + 32) = 60 Subtract 32 both sides. 2x= 28 Divide both sides by 2. x= 14

  14. Example 3B: Using Properties of Equilateral Triangles Find the value of y. ∆NPO is equiangular. Equiangular ∆  equilateral ∆ Definition of equilateral ∆. 5y – 6 = 4y + 12 Subtract 4y and add 6 to both sides. y= 18

  15. Check It Out! Example 3 Find the value of JL. ∆JKL is equiangular. Equiangular ∆  equilateral ∆ Definition of equilateral ∆. 4t – 8 = 2t + 1 Subtract 4y and add 6 to both sides. 2t= 9 t= 4.5 Divide both sides by 2. Thus JL= 2(4.5) + 1 =10.

  16. Practice Problems • pp. 276-279 #12-24 even • Chapter 4 Review • pp. 284-285 #1-21, 28-30 • For #12-21, give the theorem/postulate that proves the triangles are congruent

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