P,Q,R,S are respectively the midpoints of the sides AB,BC,CD and DA of ||gm ABCD.Show that PQRS is a parallelogram and also show that $a r (| | g m P Q R S) = \frac{1}{2} a r (| | g m A B C D)$ .

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Solution

For this question we can use the theorem that a line joining the mid points of 2 sides of the triangle is parallel to the third side and equal to half of its length.

P and Q are mid-points of the sides AB and BC of triangle ABC.

=> PQ is parallel to side AC of triangle ABC and of length = (1/2)AC.

R and S are mid-points of the sides CD and DA of triangle ACD
=> RS is parallel to side AC of triangle ACD and of length = (1/2)AC

=> PQ and RS which are the opposite sides of the quadrilateral PQRS are of equal length and both being parallel to AC are parallel to each other.
=> quadrilateral PQRS is a parallelogram.

Also since, triangle(PQB)~triangle (ABC)

ar(PQB)/ar(ABC) = $P Q^{2} / B C^{2}$ = 1/4

area(PQB) = 1/4 x ar(ABC)

Similarly, ar(SDR) = 1/4 x ar(ADC)

ar(CRQ) = 1/4 x ar(CDB)

ar(ASP) = 1/4 x (ADB)

ar(PQRS) = ar(ABCD) - ar(PQB) - ar(SDR) - ar(CRQ) - ar(ASP)

ar(PQRS) = ar(ABCD) - 1/4 x (ar(ABC)+ar(ADC)+ar(CDB)+ar(ADB))

ar(PQRS) = ar(ABCD) - 1/4x (2 x ar(ABCD))

ar(PQRS) =1/2 ar(ABCD)

Hence, proved

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Similar questions

a r (| | g m P Q R S) = \frac{1}{2} a r (| | g m A B C D)

ar (| | gm P Q R S) = \frac{1}{2} \times ar (| | gm A B C D)

P, Q, R, S

A B, B C, C D

D A

1 g m

A B C D .

P Q R S

(1 g m

P Q R S) = \frac{1}{2} \times a r (1 g m

A B C D) .

A B C D

P, Q, R

S

A B, B C, C D

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P Q R S

P. Q, R and S are respectively the midpoints of the sides AB, BC, CD and DA of a quadrilateral ABCD. Show that

(i) PQ || AC and $P Q = \frac{1}{2} A C$

(ii) PQ || SR

(iii) PQRS is a parallelogram.

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