Class 9 Maths Chapter 10 Exercise 10.5

\(\angle {AOC}=\angle {AOB}+\angle {BOC}\)
\(=60^{\circ}+30^{\circ}\)
\(=90^{\circ}\)
We know that angle subtended by an arc at the centre is double the angle subtended by it any point on the remaining part of the circle
\(\angle {ADC}=\frac{1}{2} \angle {AOC}\)
\(=\frac{1}{2} \times 90^{\circ}\)
\(=45^{\circ}\)

In \( \triangle {OAB} \),

\( {AB}={OA}={OB}= \) Radius
\( \triangle {OAB} \) is an equilateral triangle
Therefore, each interior angle of this triangle will be of \( 60^{\circ} \)
\(\angle {AOB}=60^{\circ}\)
\(\angle {ACB}=\frac{1}{2} \times {AOB}\)
\(=\frac{1}{2} \times 60^{\circ}\)
\(=30^{\circ}\)
In cyclic quadrilateral \( A C B D \)
\(\angle {ACB}+\angle {ADB}=180^{\circ}(\text {Opposite angle in cyclic quadrilateral})\)
\(\angle {ADB}=180^{\circ}-30^{\circ}\)
\(=150^{\circ}\)
Therefore, angle subtended by this chord at a point on the major arc and the minor arc are \( 30^{\circ} \) and \( 150^{\circ} \) respectively

Method 1:

We know angle subtended at centre by an arc is double the angle subtended by it at any other point.
Reflex angle \( \angle {POR}=2 \angle {PQR} \)
\(=2 \times 100^{\circ}\)
\(=200^{\circ}\)
Now, \( \angle {POR}=360^{\circ}-200=160^{\circ} \)
Also,
\( {PO}={OR} \quad\) [Radii of a circle]
\( \angle {OPR}=\angle {ORP}\quad \) [Opposite angles of isosceles triangle]
In \( \triangle {OPR}, \angle {POR}=160^{\circ} \)
\( \therefore \angle {OPR}=\angle {ORP}=10^{\circ} \)
Method 2:
Consider \(PR\) as a chord of the circle. Take any point \( S \) on the major arc of the circle
\(PQRS\) is a cyclic quadrilateral

\(\angle {PQR}+\angle {PSR}=180^{\circ}\) (Opposite angles of a cyclic quadrilateral)
\(\angle {PSR}=180^{\circ}-100^{\circ}=80^{\circ}\)
We know that the angle subtended by an arc at the centre is double the angle subtended by it at any point on the remaining part of the circle
\(\angle {POR} =2 \angle {PSR}\)
\(=2\left(80^{\circ}\right)\)
\(=160^{\circ}\)
In \( \triangle {POR} \),
\( {OP}={OR} \quad \) (Radii of the same circle)
\( \angle {OPR}=\angle {ORP} \) (Angles opposite to equal sides of a triangle)
\(\angle {OPR}+\angle {ORP}+\angle {POR}=180^{\circ}(\text {Angle sum property of a triangle})\)
\(\angle {OPR}+160^{\circ}=180^{\circ}\)
\(2 \angle {OPR}=180^{\circ}-160^{\circ}\)
\(2 \angle {OPR}=20^{\circ}\)
\(\angle {OPR}=10^{\circ}\)

\(\angle {BAC}=\angle {BDC}\) (Angles in the segment of the circle)
In triangle \(ABC \),
\(\angle {BAC}+\angle {ABC}+\angle {ACB}=180^{\circ}(\text {Sum of all angles in a triangle})\)
\(\angle {BAC}+69^{\circ}+31^{\circ}=180^{\circ}\)
\(\angle {BAC}=180^{\circ}-100^{\circ}\)
\(\angle {BAC}=80^{\circ}\)
Thus,
\(\angle {BDC}=80^{\circ}\)

In \( \triangle {CDE} \),
\(\angle {CDE}+\angle {DCE}={CEB} \text { (Exterior angle) }\)
\(\angle {CDE}+20^{\circ}=130^{\circ}\)
\(\angle {CDE}=110^{\circ}\)
However, \( \angle {BAC}=\angle {CDE} \) (Angles in the same segment of a circle)
\(\angle B A C=110^{\circ}\)
As angles in same segment are equal. So,
\(\angle B A C=\angle B D C=110^{\circ}\)

METHOD 1:
For chord \(CD\),
\( \angle {CBD}=\angle {CAD} \) (Angles on the same segment are equal)
\(\angle {CAD} =70^{\circ}\)
\(\angle {BAD} =\angle {BAC}+\angle {CAD}\)
\( =30^{\circ}+70^{\circ}\)
\(=100^{\circ}\)
\( \angle {BCD}+\angle {BAD}=180^{\circ} \) (Opposite angles of a cyclic quadrilateral)
\(\angle {BCD}+100^{\circ} =180^{\circ}\)
\(\angle {BCD} =80^{\circ}\)
Now, In \( \triangle {ABC} \),
\({AB} ={BC}\) (Given)
\(\angle {BCA} =\angle {CAB}\) (Angles opposite to equal sides of a triangle)
\(\angle {BCA} =30^{\circ}\)
We have,
\(\angle {BCD}=80^{\circ}\)
\(\angle {BCA}+\angle {ACD}=80^{\circ}\)
\(30^{\circ}+\angle {ACD}=80^{\circ}\)
\(\angle {ACD}=50^{\circ}\)
As \( \angle {ACD}=\angle {ECD} \)
\( \angle E C D=50^{\circ} \)
METHOD 2:
On chord \(AD\),
\( \angle {ABD}=\angle {ECD}\quad \ldots\ldots\text{(1)} \) [Since angles on the same segment are equal]
In \( \triangle {ABC} \),
Given: \( {AB}={BC} \) Therefore, \( \angle {BAC}=\angle {BCA}=30^{\circ} \)
Sum of angles of a triangle \( =180^{\circ} 30^{\circ}+30^{\circ}+\angle A B C=180^{\circ} \)
\( \angle {ABC}=120^{\circ}\quad \ldots\ldots\text{(2)} \)
And we can see that
\(\angle {ABC}=\angle {ABD}+\angle {DBC} 120^{\circ}=\angle {ABD}+70^{\circ} \angle {ABD}=50^{\circ}\)
And from equation \(1\), we can see that,
\(\angle {ECD}=50^{\circ}\)

Let ABCD be a cyclic quadrilateral having diagonals BD and AC, intersecting each other at point O.

\( {n} \triangle {AOD} \) and \( \triangle {COB} \)
\({AO}={CO}\quad {[\text {Radii of a circle}] }\)
\({OD}={OB}\quad {[\text {Radii of a circle}] }\)
\(\angle {AOD}=\angle {COB} \quad{[\text {Vertically opposite angles}] }\)
\(\therefore \triangle {AOD} \cong \triangle {COB} \quad{[\text {SAS congruency}] }\)
\(\therefore \angle {OAD}=\angle {OCB} \quad{[{CPCT}] }\)
But these are alternate interior angles made by the transversal AC, intersecting AD and BC.
\( \therefore {AD} \| {BC} \)
Similarly, \( {AB} \| {CD} \).
Hence, quadrilateral ABCD is a parallelogram.
Also, \( \angle {ABC}=\angle {ADC} \quad \ldots\ldots\text{(i)}\) [Opposite angles of a \( \| {gm} \) is equal]
And, \( \angle {ABC}+\angle {ADC}=180^{\circ} \quad \ldots\ldots\text{(ii)}\) [Sum of opposite angles of a cyclic quadrilateral is \( 180^{\circ} \)]
\( \Rightarrow \angle {ABC}=\angle {ADC}=90^{\circ} \quad\) [From (i) and (ii)]
\( \therefore {ABCD} \) is a rectangle.
[A \(\|\text{gm}\) one of whose angles are \( 90^{\circ} \) is a rectangle]
Hence Proved.

Consider a trapezium ABCD with
\( {AB} \| {CD} \) and
\({BC}={AD}\)
Draw AM perpendicular to \( C D \) and \( B N \) perpendicular to \( C D \)

In \( \triangle {AMD} \) and \( \triangle {BNC} \),
\({AD} ={BC}\) (Given)
\(\angle {AMD} =\angle {BNC}\) (By construction, each is \( 90^{\circ} \))
\({AM} ={BN}\) (Perpendicular distance between two parallel lines is same)
\(\triangle {AMD} \cong \triangle {BNC} \ (\text {RHS congruence rule})\)
\(\angle {ADM}=\angle {BCN} \ ({CPCT})\)
\(\Rightarrow \angle {ADC}=\angle {BCD}\quad \ldots\ldots\text{(i)}\)
\(BAD\) and \(ADC\) are on the same side of transversal \(AD\)
\( \angle {BAD}+\angle {ADC}=180^{\circ} \quad \ldots\ldots\text{(ii)}\)
\( \angle {BAD}+\angle {BCD}=180^{\circ} \) [Using equation (i)]
This equation shows that the opposite angles are supplementary
Therefore, ABCD is a cyclic quadrilateral.

Join chords AP and DQ

For chord AP,
\( \angle {PBA}=\angle {ACP} \) (Angles in the same segment) \(\quad \ldots\ldots\text{(i)}\)
For chord DQ,
\( \angle {DBQ}=\angle {QCD} \) (Angles in the same segment) \(\quad \ldots\ldots\text{(ii)}\)
\( A B D \) and \( P B Q \) are line segments intersecting at \( B \)
\( \angle {PBA}=\angle {DBQ} \quad \) (Vertically opposite angles) \(\quad \ldots\ldots\text{(iii)}\)
From (i), (ii), and (iii), we get
\( \angle {ACP}=\angle {QCD} \)
hence proved

Consider a \( \triangle {ABC} \)
Two circles are drawn while taking AB and AC as the diameter Join AD

\( \angle {ADB}=90^{\circ} \quad \) (Angle subtended by semi-circle)
\( \angle {ADC}=90^{\circ} \quad \) (Angle subtended by semi-circle)
\( \angle {BDC}=\angle {ADB}+\angle {ADC}=90^{\circ}+90^{\circ}=180^{\circ} \)
Therefore, BDC is a straight line
Thus, Point D lies on the third side BC of \( \triangle {ABC} \).

It is given in the question that,
AC is the common hypotenuse

So, \( \angle B=\angle D=90^{\circ} \)
We have to prove that,
\(\angle C A D=\angle C B D\)
Proof: We know that,
\( \angle {ABC} \) and \( \angle {ADC} \) are \( 90^{\circ} \) as these angles are in a circle
Thus, both the triangles are lying in the circle and both have same diameter i.e. AC
Points A, B, C and D are noncyclic
Therefore, CD is the chord
So,
\( \angle {CAD}=\angle {CBD} \) (As, angles made by a chord in the same segment are equal)

Given that: \(ABCD\) is a cyclic quadrilateral

We have to prove that: \( A B C D \) is a rectangle
Proof: \( \angle 1+\angle 2=180^{\circ} \) (Sum of opposite angles of a cyclic parallelogram)
We also know that, opposite angles of a cyclic parallelogram are equal
Therefore,
\(\angle 1=\angle 2\)
\(\angle 1+\angle 1=180^{\circ}\)
\(\angle 1=90^{\circ}\)
As,
One of the interior angle of the parallelogram is \( 90^{\circ} \)
Therefore, \(ABCD\) is a rectangle.