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## 6.2 Properties of Parallelograms

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**6.2 Properties of Parallelograms**Geometry Mrs. Spitz Spring 2005**Objectives:**• Use some properties of parallelograms. • Use properties of parallelograms in real-lie situations such as the drafting table shown in example 6.**Assignment:**• pp. 333-335 #2-37 and 39**In this lesson . . .**And the rest of the chapter, you will study special quadrilaterals. A parallelogram is a quadrilateral with both pairs of opposite sides parallel. When you mark diagrams of quadrilaterals, use matching arrowheads to indicate which sides are parallel. For example, in the diagram to the right, PQ║RS and QR║SP. The symbol PQRS is read “parallelogram PQRS.”**6.2—If a quadrilateral is a parallelogram, then its**opposite sides are congruent. ►PQ≅RS and SP≅QR Theorems about parallelograms Q R P S**6.3—If a quadrilateral is a parallelogram, then its**opposite angles are congruent. P ≅ R and Q ≅ S Theorems about parallelograms Q R P S**6.4—If a quadrilateral is a parallelogram, then its**consecutive angles are supplementary (add up to 180°). mP +mQ = 180°, mQ +mR = 180°, mR + mS = 180°, mS + mP = 180° Theorems about parallelograms Q R P S**6.5—If a quadrilateral is a parallelogram, then its**diagonals bisect each other. QM ≅ SM and PM ≅ RM Theorems about parallelograms Q R P S**FGHJ is a parallelogram. Find the unknown length. Explain**your reasoning. JH JK Ex. 1: Using properties of Parallelograms 5 G F 3 K H J b.**FGHJ is a parallelogram. Find the unknown length. Explain**your reasoning. JH JK SOLUTION: a. JH = FG Opposite sides of a are ≅. JH = 5 Substitute 5 for FG. Ex. 1: Using properties of Parallelograms 5 G F 3 K H J b.**FGHJ is a parallelogram. Find the unknown length. Explain**your reasoning. JH JK SOLUTION: a. JH = FG Opposite sides of a are ≅. JH = 5 Substitute 5 for FG. Ex. 1: Using properties of Parallelograms 5 G F 3 K H J b. • JK = GK Diagonals of a bisect each other. • JK = 3 Substitute 3 for GK**PQRS is a parallelogram.**Find the angle measure. mR mQ Ex. 2: Using properties of parallelograms Q R 70° P S**PQRS is a parallelogram.**Find the angle measure. mR mQ a. mR = mP Opposite angles of a are ≅. mR = 70° Substitute 70° for mP. Ex. 2: Using properties of parallelograms Q R 70° P S**PQRS is a parallelogram.**Find the angle measure. mR mQ a. mR = mP Opposite angles of a are ≅. mR = 70° Substitute 70° for mP. mQ + mP = 180° Consecutive s of a are supplementary. mQ + 70° = 180° Substitute 70° for mP. mQ = 110° Subtract 70° from each side. Ex. 2: Using properties of parallelograms Q R 70° P S**PQRS is a parallelogram. Find the value of x.**mS + mR = 180° 3x + 120 = 180 3x = 60 x = 20 Consecutive s of a □ are supplementary. Substitute 3x for mS and 120 for mR. Subtract 120 from each side. Divide each side by 3. Ex. 3: Using Algebra with Parallelograms P Q 3x° 120° S R**Given: ABCD and AEFG are parallelograms.**Prove 1 ≅ 3. ABCD is a □. AEFG is a ▭. 1 ≅ 2, 2 ≅ 3 1 ≅ 3 Given Ex. 4: Proving Facts about Parallelograms**Given: ABCD and AEFG are parallelograms.**Prove 1 ≅ 3. ABCD is a □. AEFG is a □. 1 ≅ 2, 2 ≅ 3 1 ≅ 3 Given Opposite s of a▭ are ≅ Ex. 4: Proving Facts about Parallelograms**Given: ABCD and AEFG are parallelograms.**Prove 1 ≅ 3. ABCD is a □. AEFG is a □. 1 ≅ 2, 2 ≅ 3 1 ≅ 3 Given Opposite s of a▭ are ≅ Transitive prop. of congruence. Ex. 4: Proving Facts about Parallelograms**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Definition of a parallelogram Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Definition of a parallelogram Alternate Interior s Thm. Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Definition of a parallelogram Alternate Interior s Thm. Reflexive property of congruence Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Definition of a parallelogram Alternate Interior s Thm. Reflexive property of congruence ASA Congruence Postulate Ex. 5: Proving Theorem 6.2**Given: ABCD is a parallelogram.**Prove AB ≅ CD, AD ≅ CB. ABCD is a . Draw BD. AB ║CD, AD ║ CB. ABD ≅ CDB, ADB ≅ CBD DB ≅ DB ∆ADB ≅ ∆CBD AB ≅ CD, AD ≅ CB Given Through any two points, there exists exactly one line. Definition of a parallelogram Alternate Interior s Thm. Reflexive property of congruence ASA Congruence Postulate CPCTC Ex. 5: Proving Theorem 6.2**FURNITURE DESIGN. A drafting table is made so that the legs**can be joined in different ways to change the slope of the drawing surface. In the arrangement below, the legs AC and BD do not bisect each other. Is ABCD a parallelogram? Ex. 6: Using parallelograms in real life**FURNITURE DESIGN. A drafting table is made so that the legs**can be joined in different ways to change the slope of the drawing surface. In the arrangement below, the legs AC and BD do not bisect each other. Is ABCD a parallelogram? ANSWER: NO. If ABCD were a parallelogram, then by Theorem 6.5, AC would bisect BD and BD would bisect AC. They do not, so it cannot be a parallelogram. Ex. 6: Using parallelograms in real life