Class 9MathematicsAreas of Parallelograms and TrianglesMix Examples - Areas of Parallelograms and Triangles
Difficult$ABCD$ is a trapezium in which $AB \parallel DC$,$DC = 30 \, cm$ and $AB = 50 \, cm$. If $X$ and $Y$ are,respectively,the mid-points of $AD$ and $BC$,prove that $\operatorname{ar}(DCYX) = \frac{7}{9} \operatorname{ar}(XYBA)$.
(N/A) In $\Delta MBY$ and $\Delta DCY$,we have:
$\angle 1 = \angle 2$ [Vertically opposite angles]
$\angle 3 = \angle 4$ [Since $AB \parallel DC$ and alternate interior angles are equal]
$BY = CY$ [Since $Y$ is the mid-point of $BC$]
Therefore,$\Delta MBY \cong \Delta DCY$ [By $ASA$ Congruence Rule]
So,$MB = DC = 30 \, cm$ [$CPCT$]
Now,$AM = AB + BM = 50 \, cm + 30 \, cm = 80 \, cm$
In $\Delta ADM$,by the Mid-point Theorem,$XY = \frac{1}{2} AM = \frac{1}{2} \times 80 \, cm = 40 \, cm$
As $AB \parallel XY \parallel DC$ and $X$ and $Y$ are the mid-points of $AD$ and $BC$,the heights of the trapeziums $DCXY$ and $XYBA$ are equal. Let the equal height be $h \, cm$.
$\frac{\operatorname{ar}(DCXY)}{\operatorname{ar}(XYBA)} = \frac{\frac{1}{2}(DC + XY) \times h}{\frac{1}{2}(XY + AB) \times h} = \frac{30 + 40}{40 + 50} = \frac{70}{90} = \frac{7}{9}$
Hence,$\operatorname{ar}(DCXY) = \frac{7}{9} \operatorname{ar}(XYBA)$.
$\angle 1 = \angle 2$ [Vertically opposite angles]
$\angle 3 = \angle 4$ [Since $AB \parallel DC$ and alternate interior angles are equal]
$BY = CY$ [Since $Y$ is the mid-point of $BC$]
Therefore,$\Delta MBY \cong \Delta DCY$ [By $ASA$ Congruence Rule]
So,$MB = DC = 30 \, cm$ [$CPCT$]
Now,$AM = AB + BM = 50 \, cm + 30 \, cm = 80 \, cm$
In $\Delta ADM$,by the Mid-point Theorem,$XY = \frac{1}{2} AM = \frac{1}{2} \times 80 \, cm = 40 \, cm$
As $AB \parallel XY \parallel DC$ and $X$ and $Y$ are the mid-points of $AD$ and $BC$,the heights of the trapeziums $DCXY$ and $XYBA$ are equal. Let the equal height be $h \, cm$.
$\frac{\operatorname{ar}(DCXY)}{\operatorname{ar}(XYBA)} = \frac{\frac{1}{2}(DC + XY) \times h}{\frac{1}{2}(XY + AB) \times h} = \frac{30 + 40}{40 + 50} = \frac{70}{90} = \frac{7}{9}$
Hence,$\operatorname{ar}(DCXY) = \frac{7}{9} \operatorname{ar}(XYBA)$.
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Similar Questions
State whether each of the following statements is true or false:
$(1)$ If $ar(ABC) = 96 \, cm^2$ for the parallelogram $ABCD$,then $ar(ABCD) = 192 \, cm^2$.
$(2)$ Area of a right triangle = Product of the sides forming the right angle.
$(1)$ If $ar(ABC) = 96 \, cm^2$ for the parallelogram $ABCD$,then $ar(ABCD) = 192 \, cm^2$.
$(2)$ Area of a right triangle = Product of the sides forming the right angle.
Medium
View SolutionIn $\Delta ABC$,$AD$ is a median and $AM$ is an altitude. The side $BA$ of $\Delta ABC$ is produced to any point $E$,so that $AB = AE$. If $BC = 16\, cm$ and $AM = 8\, cm$,then find the area of $\Delta EBD$ in $cm^2$.
Medium
View SolutionWrite True or False and justify your answer:
$PQRS$ is a rectangle inscribed in a quadrant of a circle of radius $13 \, cm$. $A$ is any point on $PQ$. If $PS = 5 \, cm$,then $\text{ar}(PAS) = 30 \, cm^2$.
$PQRS$ is a rectangle inscribed in a quadrant of a circle of radius $13 \, cm$. $A$ is any point on $PQ$. If $PS = 5 \, cm$,then $\text{ar}(PAS) = 30 \, cm^2$.
Difficult
View SolutionIn trapezium $PQRS, PQ || RS$ and diagonals $PR$ and $QS$ intersect at point $M$. Prove that,$ar(PQS) = ar(QPR)$.
Easy
View SolutionIn the figure,$ABCD$ is a parallelogram. Points $P$ and $Q$ on $BC$ trisect $BC$ into three equal parts. Prove that $\operatorname{ar}(APQ) = \operatorname{ar}(DPQ) = \frac{1}{6} \operatorname{ar}(ABCD)$.
Difficult
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