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6.6 Special Quadrilaterals

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1 6.6 Special Quadrilaterals
Geometry

2 Objectives: Identify special quadrilaterals based on limited information. Prove that a quadrilateral is a special type of quadrilateral, such as a rhombus or trapezoid.

3 Summarizing Properties of Quadrilaterals
In this chapter, you have studied the seven special types of quadrilaterals shown at the right. Notice that each shape has all the properties of the shapes linked above it. For instance, squares have the properties of rhombuses, rectangles, parallelograms, and quadrilaterals. Trapezoid Kite Parallelogram Rhombus Rectangle Isosceles trapezoid Square

4 Ex. 1: Identifying Quadrilaterals
Quadrilateral ABCD has at least one pair of opposite sides congruent. What kinds of quadrilaterals meet this condition? Parallelogram Rhombus Opposites sides are ≅. All sides are congruent. Opposite sides are congruent. Legs are congruent. All sides are congruent.

5 Ex. 2: Connecting midpoints of sides
When you join the midpoints of the sides of any quadrilateral, what special quadrilateral is formed? Why?

6 Ex. 2: Connecting midpoints of sides
Solution: Let E, F, G, and H be the midpoints of the sides of any quadrilateral, ABCD as shown. If you draw AC, the Midsegment Theorem for triangles says that FG║AC and EG║AC, so FG║EH. Similar reasoning shows that EF║HG. So by definition, EFGH is a parallelogram.

7 Proof with Special Quadrilaterals
When you want to prove that a quadrilateral has a specific shape, you can use either the definition of the shape as in example 2 or you can use a theorem.

8 Proving Quadrilaterals are Rhombuses
You have learned 3 ways to prove that a quadrilateral is a rhombus. You can use the definition and show that the quadrilateral is a parallelogram that has four congruent sides. It is easier, however, to use the Rhombus Corollary and simply show that all four sides of the quadrilateral are congruent. Show that the quadrilateral is a parallelogram and that the diagonals are perpendicular (Thm. 6.11) Show that the quadrilateral is a parallelogram and that each diagonal bisects a pair of opposite angles. (Thm 6.12)

9 Ex. 3: Proving a quadrilateral is a rhombus
Show KLMN is a rhombus Solution: You can use any of the three ways described in the concept summary above. For instance, you could show that opposite sides have the same slope and that the diagonals are perpendicular. Another way shown in the next slide is to prove that all four sides have the same length. AHA – DISTANCE FORMULA If you want, look on pg. 365 for the whole explanation of the distance formula So, because LM=NK=MN=KL, KLMN is a rhombus.

10 Ex. 4: Identifying a quadrilateral
60° What type of quadrilateral is ABCD? Explain your reasoning. 120° 120° 60°

11 Ex. 4: Identifying a quadrilateral
60° What type of quadrilateral is ABCD? Explain your reasoning. Solution: A and D are supplementary, but A and B are not. So, AB║DC, but AD is not parallel to BC. By definition, ABCD is a trapezoid. Because base angles are congruent, ABCD is an isosceles trapezoid 120° 120° 60°

12 Ex. 5: Identifying a Quadrilateral
The diagonals of quadrilateral ABCD intersect at point N to produce four congruent segments: AN ≅ BN ≅ CN ≅ DN. What type of quadrilateral is ABCD? Prove that your answer is correct. First Step: Draw a diagram. Draw the diagonals as described. Then connect the endpoints to draw quadrilateral ABCD.

13 Ex. 5: Identifying a Quadrilateral
B First Step: Draw a diagram. Draw the diagonals as described. Then connect the endpoints to draw quadrilateral ABCD. 2nd Step: Make a conjecture: Quadrilateral ABCD looks like a rectangle. 3rd step: Prove your conjecture Given: AN ≅ BN ≅ CN ≅ DN Prove ABCD is a rectangle. C N A D

14 Given: AN ≅ BN ≅ CN ≅ DN Prove: ABCD is a rectangle.
Because you are given information about diagonals, show that ABCD is a parallelogram with congruent diagonals. First prove that ABCD is a parallelogram. Because BN ≅ DN and AN ≅ CN, BD and AC bisect each other. Because the diagonals of ABCD bisect each other, ABCD is a parallelogram. Then prove that the diagonals of ABCD are congruent. From the given you can write BN = AN and DN = CN so, by the addition property of Equality, BN + DN = AN + CN. By the Segment Addition Postulate, BD = BN + DN and AC = AN + CN so, by substitution, BD = AC. So, BD ≅ AC. ABCD is a parallelogram with congruent diagonals, so ABCD is a rectangle.

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