**Chapter 3 Circle Set 3**

## Chapter 3 Circle Set 3

**Question 1.Four alternative answers for each of the following questions are given. Choose the correct alternative.**

**i. Two circles of radii 5.5 cm and 3.3 cm respectively touch each other. What is the distance between their centres?(A) 4.4 cm(B) 8.8 cm(C) 2.2 cm(D) 8.8 or 2.2 cmAnswer:** (D)

Two circles can touch each other internally or externally.

âˆ´ Distance between centres = 5.5 + 3.3 or 5.5 â€“ 3.3 = 8.8 or 2.2

**ii. Two circles intersect each other such that each circle passes through the centre of the other. If the distance between their centres is 12, what is the radius of each circle?(A) 6 cm(B) 12 cm(C) 24 cm(D) canâ€™t sayAnswer:** (B)

PQ is the radius = 12 cm

**iii. A circle touches all sides of a parallelogram. So the parallelogram must be a __________.(A) rectangle(B) rhombus(C) square(D) trapeziumAnswer: **(B)

ê ¸ABCD is a rhombus.

Note: It cannot be square as the angles are not mentioned as 90Â°.

**iv. Length of a tangent segment drawn from a point which is at a distance 12.5 cm from the centre of a circle is 12 cm, find the diameter of the circle.(A) 25 cm(B) 24 cm(C) 7 cm(D) 14 cmAnswer: **(C)

In âˆ†OAB, âˆ B = 90Â° [Tangent theorem]

âˆ´ OA

^{2}= OB

^{2}+ AB

^{2}[Pythagoras theorem]

âˆ´ 12.5

^{2}= OB

^{2}+ 12

^{2}

âˆ´ OB

^{2}= 156.25- 144

âˆ´ Diameter = 2 Ã— OB = 2 Ã— 3.5 = 7 cm

**v. If two circles are touching externally, how many common tangents of them can be drawn?(A) One(B) Two(C) Three(D) FourAnswer:** (C)

line l, line m and line n are the tangents.

**vi. âˆ ACB is inscribed in arc ACB of a circle with centre O. If âˆ ACB = 65Â°, find m(arc ACB).(A) 65Â°(B) 130Â°(C) 295Â°(D) 230Â°Answer:** (D)

mâˆ ACB =1/2m(arc AB) [Inscribed angle theorem]

âˆ´ m(arc AB) = 2 mâˆ ACB =

= 2 Ã— 65

= 130Â°

m(arc ACB) = 360Â° â€“ m(arc AB) [Measure of a circle is 360Â°]

= 360Â° â€“ 130Â°

= 230Â°

**vii. Chords AB and CD of a circle intersect inside the circle at point E. If AE = 5.6, EB = 10, CE = 8, find ED.(A) 7(B) 8(C) 11.2(D) 9Answer: **(A)

Chords AB and CD intersect

internally at E.

AE Ã— EB = CE Ã— ED [Theorem of internal division of chords]

âˆ´ 5.6 Ã— 10 = 8 Ã— ED

âˆ´ ED = 7 units

**viii. In a cyclic ê ¸ABCD, twice the measure of âˆ A is thrice the measure of âˆ C. Find the measure of âˆ C?(A) 36Â°(B) 72Â°(C) 90Â°(D) 108Â°Answer:** (B)

âˆ A + âˆ C = 180Â° [Theorem of cyclic quadrilateral]

âˆ´ 2âˆ A + 2âˆ C = 2 Ã— 180Â° [Multiplying both sides by 2]

âˆ´ 3âˆ C + 2âˆ C = 360Â° [âˆµ 2âˆ A = 3âˆ C]

âˆ´ 5âˆ C = 360Â°

âˆ´ âˆ C = 72Â°

**ix. Points A, B, C are on a circle, such that m(arc AB) = m(arc BC) = 120Â°. No point, except point B, is common to the arcs. Which is the type of âˆ†ABC?(A) Equilateral triangle(B) Scalene triangle(C) Right angled triangle(D) Isosceles triangleAnswer:** (A)

m(arc AB) + m(arc BC) + m(arc AC) = 360Â° [Measure of a circle is 360Â°]

âˆ´ 120Â° + 120Â° + m (arc AC) = 360Â°

âˆ´ m(arc AC) = 120Â°

âˆ´ arc AB = arc BC = arc AC

âˆ´ seg AB â‰… seg BC â‰… seg AC [Corresponding chords of congruents arcs of a circle are congruent]

âˆ´ âˆ†ABC is an equilateral triangle.

**x. Seg XZ is a diameter of a circle. Point Y lies in its interior. How many of the following statements are true?(i) It is not possible that âˆ XYZ is an acute angle.(ii) âˆ XYZ canâ€™t be a right angle.(iii) âˆ XYZ is an obtuse angle.(iv) Canâ€™t make a definite statement for measure of âˆ XYZ.(A) Only one(B) Only two(C) Only three(D) AllAnswer:** (C)

x. seg XZ is the diameter.

âˆ´ âˆ XWZ is a right angle. [Angle inscribed in a semicircle]

Since, Y lies in the interior of âˆ†XWZ,

âˆ´ âˆ XYZ > 90Â°

i.e., âˆ XYZ is an obtuse angle.

**Question 2.Line l touches a circle with centre O at point P. If radius of the circle is 9 cm, answer the following.i. What is d(O, P) = ? Why?ii. If d(O, Q) = 8 cm, where does the point Q lie?iii. If d(O, R) = 15 cm, how many locations of point R are on line l ?At what distance will each of them be from point P?Solution:**

i. seg OP is the radius of the circle.

âˆ´ d(0, P) = 9 cm

ii. Here, 8 cm < 9 cm

âˆ´ d(0, Q) < d(0, P)

âˆ´ d(0, Q) < radius

Point Q lies in the interior of the circle.

iii. There can be two locations of point R on line l.

d(0, R) = 15 cm

Now, in âˆ†OPR, âˆ OPR = 90Â° [Tangent theorem]

âˆ´ OR

^{2}= OP

^{2}+ PR

^{2}[Pythagoras theorem]

âˆ´ 15

^{2}= 9

^{2}+ PR

^{2}

âˆ´ 225 = 81 + PR

^{2}

âˆ´ PR

^{2}= 225 â€“ 81 = 144 [Taking square root of both sides]

= 12 cm

**Question 3.In the adjoining figure, M is the centre of the circle and seg KL is a tangent segment. If MK = 12, KL = 6âˆš3 ,then findi. Radius of the circle.ii. Measures of âˆ K and âˆ M.Solution:**
i. Line KL is the tangent to the circle at point L and seg ML is the radius. [Given]

âˆ´ âˆ MLK = 90Â°â€¦â€¦â€¦â€¦. (i) [Tangent theorem]

In âˆ†MLK, âˆ MLK = 90Â°

âˆ´ MK

^{2}= ML

^{2}+ KL

^{2}[Pythagoras theorem]

âˆ´ 12

^{2}= ML

^{2}+ (6âˆš3)

^{2}

âˆ´ 144 = ML

^{2}+ 108

âˆ´ ML

^{2}= 144 â€“ 108

âˆ´ ML

^{2}= 36

âˆ´ ML = = 6 units. [Taking square root of both sides]

âˆ´ Radius of the circle is 6 units.

ii. We know that,

ML = 1/2 MK

âˆ´ âˆ K = 30Â° â€¦â€¦â€¦â€¦â€¦ (ii) [Converse of 30Â° â€“ 60Â° â€“ 90Â° theorem]

In âˆ†MLK ,

âˆ L = 90Â° [From (i)]

âˆ K = 30Â° [From (ii)]

âˆ´ âˆ M = 60Â° [Remaining angle of âˆ†MLK]

**Question 4.In the adjoining figure, O is the centre of the circle. Seg AB, seg AC are tangent segments. Radius of the circle is r and l(AB) = r. Prove that, â–¡ABOC is a square.Given: O is the centre of circle.seg AB and seg AC are the tangents, radius = r, /(AB) = r.To prove: â–¡ABOC is a square.Construction: Draw seg OB and seg OC.Proof:**

seg AB and seg AC are the tangents to the circle. [Given]

âˆ´ AB = AC [Tangent segment theorem]

But, AB = r [Given]

âˆ´ AB = AC = r â€¦â€¦â€¦.. (i)

Also, OB = OC = r â€¦â€¦â€¦.. (ii) [Radii of the same circle]

âˆ´ AB = AC = OB = OC [From (i) and (ii)]

âˆ´ â–¡ABOC is a rhombus.

âˆ OBA = 90Â° [Tangent theorem]

âˆ´ â–¡ABOC is a square [A rhombus is a square, if one of its angles is a right angle]

**Question 5.In the adjoining figure, ê ¸ABCD is a parallelogram. It circumscribes the circle with centre T. Points E, F, G, H are touching points. If AE = 4.5, EB = 5.5, find AD.Solution:**

Let the values of DH and CF be x and y respectively.

[ AE = AH = 4.5

BE = BF = 5.5

DH = DG = x

CF = CG = y ] [Tangent segment theorem]

â–¡ABCD is a parallelogram. [Given]

âˆ´ AB = CD [Opposite sides of a parallelogram]

âˆ´ AE + BE = DG + CG [A â€“ E â€“ B, D â€“ G â€“ C]

âˆ´ 4.5 + 5.5 = x + y

âˆ´ x + y = 10 â€¦â€¦â€¦.. (i)

Also, AD = BC [Opposite sides of a parallelogram]

âˆ´ AH + DH = BF + CF [A â€“ H â€“ D, B â€“ F â€“ C]

âˆ´ 4.5 + x = 5.5 + y

âˆ´ x â€“ y = 1 â€¦â€¦â€¦â€¦ (ii)

Adding equations (i) and (ii), we get

2x = 11

âˆ´ x = 112 = 5.5

âˆ´ AD = AH + DH [A â€“ H â€“ D]

= 4.5 + 5.5

âˆ´ AD = 10 units

**Question 6.In the adjoining figure, circle with centre M touches the circle with centre N at point T. Radius RM touches the smaller circle at S. Radii of circles are 9 cm and 2.5 cm. Find the answers to the following questions, hence find the ratio MS : SR.i. Find the length of segment MT.ii. Find the length of seg MN.iii. Find the measure of âˆ NSM.Solution:**

i. MT = 9 cm [Radius of the bigger circle]

ii. MT = MN + NT [M â€“ N â€“ T]

âˆ´ 9 = MN + 2.5

âˆ´ MN = 9 â€“ 2.5

âˆ´ MN = 6.5 cm

iii. seg MR is a tangent to the smaller circle and NS is its radius.

âˆ´ âˆ NSM = 90Â° [Tangent theorem]

iv. In âˆ†NSM, âˆ NSM = 90Â°

âˆ´ MN

^{2}= NS

^{2}+ MS

^{2}[Pythagoras theorem]

âˆ´ 6.5

^{2}= 2.5

^{2}+ MS

^{2}

âˆ´ MS

^{2}= 6.5

^{2}â€“ 2.5

^{2}

= (6.5 + 2.5) (6.5 â€“ 2.5) [âˆµ a

^{2}â€“ b

^{2}= (a + b)(a â€“ b)]

= 9 Ã— 4=36

âˆ´ MS = [Taking square root of both sides]

= 6 cm

But, MR = MS + SR [M â€“ S â€“ R]

âˆ´ 9 = 6 + SR

âˆ´ SR = 9 â€“ 6

âˆ´ SR = 3cm

** Question 7.In the adjoining figure, circles with centres X and Y touch each other at point Z. A secant passing through Z intersects the circles at points A and B respectively. Prove that, radius XA || radius YB. Fill in the blanks and complete the proof.Given: X and Y are the centres of circle.To prove: radius XA || radius YBConstruction: Draw segments XZ and YZ.Proof:**
By theorem of touching circles, points X, Z,

Y are collinear.

âˆ´ âˆ XZA â‰… âˆ BZY [Vertically opposite angles]

Let âˆ XZA = âˆ BZY = a â€¦â€¦â€¦â€¦â€¦.. (i)

Now, seg XA seg XZ [Radii of the same circIe]

âˆ´ âˆ XAZ â‰…âˆ XZA = a â€¦â€¦â€¦â€¦â€¦.. (ii) [Isosceles triangle theorem]

Similarly, seg YB â‰… seg YZ [Radii of the same circie]

âˆ´ âˆ BZY = âˆ ZBY = a â€¦â€¦â€¦â€¦â€¦.. (iii) [Isosceles triangle theorem]

âˆ´ âˆ XAZ = âˆ ZBY [From (i), (ii) and (iii)]

âˆ´ radius XA || radius YB [Alternate angles test]

**Question 8.In the adjoining figure, circles with centres X and Y touch internally at point Z. Seg BZ is a chord of bigger circle and it intersects smaller circle at point A. Prove that, seg AX || seg BY.Given: X and Y are the centres of the circle.To prove: seg AX || seg BYProof:**
In âˆ†XAZ,

seg XA â‰… seg XZ [Radii of the same circle]

âˆ´ âˆ XZA â‰… âˆ XAZ â€¦â€¦â€¦â€¦ (i) [Isosceles triangle theorem]

Also, in âˆ†YBZ,

seg YB â‰… seg YZ [Radii of the sanie circle]

âˆ´ âˆ YZB â‰…âˆ YBZ [Isosceles triangle theorem]

âˆ´ âˆ XZA â‰… âˆ YBZ â€¦â€¦â€¦â€¦.. (ii) [Y â€“ X â€“ Z,B â€“ A â€“ Z]

âˆ´ âˆ XAZ â‰… âˆ YBZ [From (i) and (ii)]

âˆ´ seg AX || seg BY [Corresponding angles test]

**Question 9.In the adjoining figure, line l touches the circle with centre O at point P, Q is the midpoint of radius OP. RS is a chord through Q such that chords RS || line l. If RS = 12, find the radius of the circle.Solution:**

Let the radius of the circle be r.

line l is the tangent to the circle and [Given]

seg OP is the radius.

âˆ´ seg OP âŠ¥ line l [Tangent theorem]

chord RS || line l [Given]

**Question 10.In the adjoining figure, seg AB is a diameter of a circle with centre C. Line PQ is a tangent, which touches the circle at point T. Seg AP âŠ¥ line PQ and seg BQ âŠ¥ line PQ. Prove that seg CP â‰… seg CQ.Given: C is the centre of circle.seg AB is the diameter of circle.line PQ is a tangent, seg AP âŠ¥ line PQ and seg BQ âŠ¥ line PQ.To prove: seg CP â‰… seg CQConstruction: Draw seg CT, seg CP and seg CQ.Proof:**

Line PQ is the tangent to the circle at point T. [Given]

âˆ´ seg CT âŠ¥ line PQ (i) [Tangent theorem]

Also, seg AP âŠ¥ line PQ,

seg BQ âŠ¥ line PQ [Given]

âˆ´ seg AP || seg CT || seg BQ [Lines perpendicular to the same line are parallel to each other]

âˆ´ PT = TQ â€¦â€¦â€¦â€¦ (ii)

âˆ´ In âˆ†CTP and âˆ†CTQ,

seg PT â‰… seg QT [From (ii)]

âˆ CTP â‰… âˆ CTQ [From (i), each angle is of measure 90Â° ]

seg CT â‰… seg CT [Common side]

âˆ´ âˆ†CTP â‰… âˆ†CTQ [SAS test of congruence]

âˆ´ seg CP â‰… seg CQ [c.s.c.t]

**Question 11.Draw circles with centres A, B and C each of radius 3 cm, such that each circle touches the other two circles.Analysis:**

Let the circles with centres A, B, C touch each other at points P, Q, R.

[âˆ´ A â€“ P â€“ B

A â€“ Q â€“ C

B â€“ R â€“ C ] [Theorem of touching circles]

âˆ´ AB = AP + BP [A â€“ P â€“ B]

âˆ´ AB = 3 + 3 = 6 cm

Similarly, BC = 6 cm, AC = 6 cm

So, if we construct triangle âˆ†ABC of side 6 cm each, then with A, B, C as the centres and radius 3 cm, the touching circles can be drawn.

**Question 12.Prove that any three points on a circle cannot be collinearGiven: A circle with centre O.Points A, B and C lie on the circle.To prove: Points A, B and C are not collinear.Proof:**

OA = OB [Radii of the same circle]

âˆ´ Point O is equidistant from the endpoints A and B of seg AB.

âˆ´ Point O lies on the perpendicular bisector of AB. [Perpendicular bisector theorem]

Similarly, we can prove that,

Point O lies on the perpendicular bisector of BC.

âˆ´ Point O is the point of intersection of perpendicular bisectors of AB and BC (i.e., circumcentre of âˆ†ABC) â€¦â€¦â€¦ (i)

Now, suppose that the points A, B, C are collinear.

Then, the perpendicular bisector of AB and BC will be parallel. [Perpendiculars to the same line are parallel]

âˆ´ The perpendicular bisector do not intersect at O.

This contradicts statement (i) that the perpendicular bisectors intersect each other at O.

âˆ´ Our supposition that A, B, C are collinear is false.

âˆ´ Points A, B and C are non collinear points.

**Question 13.In the adjoining figure, line PR touches the circle at point Q. Answer the following questions with the help of the figure.i. What is the sum of âˆ TAQ and âˆ TSQ?ii. Find the angles which are congruent to âˆ AQP.iii. Which angles are congruent to âˆ QTS?iv. âˆ TAS = 65Â°, find the measures of âˆ TQS and arc TS.v. If âˆ AQP = 42Â° and âˆ SQR = 58Â° find measure of âˆ ATS.Solution:**

i. ê ¸AQST is a cyclic quadrilateral. [Given]

âˆ´ âˆ TAQ + âˆ TSQ = 180Â° [Opposite angles of a cyclic quadrilateral are supplementary]

ii. line PR is the tangent and seg AQ is the secant. [Given]

âˆ´âˆ AQP = 1/2 m(arc AQ) [Theorem of angle between tangent and secant]

But,âˆ ASQ = 1/2 m(arc AQ) [Inscribed angle theorem]

âˆ´âˆ AQP â‰… âˆ ZASQ

Similarly, we can prove that,

âˆ AQP â‰… âˆ ATQ

iii. âˆ QTS = 1/2 m(arc QS) [Inscribed angle theorem]

But, âˆ SQR = 1/2 m(arc QS) [Theorem of angle between tangent and secant]

âˆ´ âˆ QTS â‰… âˆ SQR

Also, âˆ QTS = âˆ QAS [Angles inscribed in the same arc]

iv. âˆ TQS = âˆ TAS [Angles inscribed in the same arc]

âˆ´ âˆ TQS = 65Â°

Now, âˆ TQS = 1/2 m(arc TS) [Inscribed angle theorem]

âˆ´ 65Â°= 1/2 m(arcTS)

âˆ´ m(arc TS) = 65Â° Ã— 2

âˆ´ m(arc TS) = 130Â°

v. âˆ AQP + âˆ AQS + âˆ SQR = 180Â° [Angles in a linear pair]

âˆ´ 42Â° + âˆ AQS + 58Â° = 180Â°

âˆ´âˆ AQS + 100Â° = 180Â° â€¦â€¦â€¦â€¦ (i)

But, ê ¸AQST is a cyclic quadrilateral.

âˆ´ âˆ AQS + âˆ ATS = 180Â° â€¦â€¦â€¦â€¦ (ii) [Theorem of cyclic quadrilateral]

âˆ´ âˆ ATS = 100Â° [From (i) and (ii)]

**Question 14.In the adjoining figure, O is the centre of a circle, chord PQ â‰… chord RS.If âˆ POR = 70Â° and (arc RS) = 80Â°, findi. m (arc PR)ii. m (arc QS)iii. m (arc QSR).Solution:**

i. m(arc PR) = mâˆ POR [Definition of measure of arc]

âˆ´ m(arc PR) = 70Â°

ii. chord PQ chord RS [Given]

âˆ´ m(arc PQ) = m(arc RS) = 80Â° [Corresponding arcs of congruents chords of a circle are congruent]

Now, m(arc QS) + m(arc PQ) + m(arc PR) + m(arcRS) = 360Â°

âˆ´ m(arc QS) + 80Â° + 70Â° + 80Â° = 360Â° [Measure of a circle is 360Â°]

âˆ´ m(arc QS) + 230Â° = 360Â°

âˆ´ m(arc QS) = 130Â°

iii. m(arc QSR) = m(arc QS) + m(arc SR) [Arc addition property]

= 130Â° + 80Â°

âˆ´ m(arc QSR) = 210Â°

**Question 15.In the adjoining figure, m(arc WY) = 44Â°, m(arc ZX) = 68Â°, theni. Find the measure of âˆ ZTX.ii. If WT = 4.8, TX = 8.0, YT = 6.4, find TZ.iii. If WX = 25, YT = 8, YZ = 26, find WT.Solution:**

i. Chords WX and YZ intersect internally at point T.

âˆ´ âˆ ZTX = 1/2 m(arc WY) + m(arc ZX)]

= 1/2 (44Â° + 68Â°)

= 1/2 Ã— 112Â°

âˆ´ m âˆ ZTX = 56Â°

ii. WT Ã— TX = YT Ã— TZ [Theorem of internal division of chords]

âˆ´ 4.8 Ã— 8.0 = 6.4 Ã— TZ

âˆ´ TZ =

âˆ´ l(TZ) = 6.0 units

iii. Let the value of WT be x. [W â€“ T â€“ X]

WT + TX = WX

âˆ´ x + TX = 25

âˆ´ TX = 25 â€“ x

Also, YT + TZ = YZ [Y â€“ T â€“ Z]

âˆ´ 8 + TZ = 26

âˆ´ TZ = 26 â€“ 8

= 18 units

But, WT Ã— TX = YT Ã— TZ [Theorem of internal division of chords]

âˆ´ x Ã— (25 â€“ x) = 8 Ã— 18

âˆ´ 25x â€“ x

^{2}= 144

âˆ´ x

^{2}â€“ 25x + 144 = 0

âˆ´ (x â€“ 16)(x â€“ 9) = 0

âˆ´ x = 16 or x = 9

âˆ´ WT = 16 units or WT = 9units

**Question 16.In the adjoining figure,i. Mn (arc CE) = 54Â°, m (arc BD) = 23Â°, find measure of âˆ CAE.ii. If AB = 4.2,BC = 5.4, AE = 12.0, find AD.iii. If AB = 3.6, AC = 9.0, AD = 5.4, find AE.Solution:**

i. Chords BC and ED intersect each other externally at point A.

âˆ´ âˆ CAE = 1/2 [m(arc CE) â€“ m(arc BD)]

= 1/2 (54Â° â€“ 23Â°)

= 1/2 Ã— 31Â°

âˆ´ mâˆ CAE = 15.5Â°

ii. AC = AB + BC [A â€“ B â€“ C]

= 4.2 + 5.4

= 9.6 units

Now, AB Ã— AC = AD Ã— AE [Theorem of external division of chords]

âˆ´ 4.2 Ã— 9.6 = AD Ã— 12.0

âˆ´ AD =

âˆ´ AD = 3.36 units

iii. AB Ã— AC = AD Ã— AE [Theorem of external division of chords]

âˆ´ 3.6 Ã— 9.0 = 5.4 Ã— AE

âˆ´ AE =

âˆ´ AE = 6 units

**Question 17.In the adjoining figure, chord EF || chord GH. Prove that, chord EG â‰… chord FH.Fill in the blanks and write the proof.Given: chord EF || chord GHTo prove: chord EG = chord FHConstruction: Draw seg GF.Proof:**

âˆ EFG = âˆ FGH (i) Alternate angles

âˆ EFG = 1/2 m (arcEG)] (ii) [Inscribed angle theorem]

âˆ FGH = 1/2m(arcFH) (iii) [Inscribed angle theorem]

âˆ´ m(arcEG) = m (are FH) [From (i), (ii) and (iii)]

âˆ´ chord EG â‰… chord FH The chords corresponding to congruent arcs of a circle are congruent

**Question 18.In the adjoining figure, P is the point of contact.i. If m (arc PR) = 140Â°, L POR = 36Â°, find m (arc PQ)ii. If OP = 7.2, OQ = 3.2, find OR and QRiii. If OP = 7.2, OR = 16.2, find QR.Solution:**

i. âˆ PQR m(arc PR) [Inscribed angle theorem]

= 1/2 Ã— 140Â° = 70Â°

âˆ PQR is the exterior angle of âˆ†POQ. [Remote interior angle theorem]

âˆ´ âˆ PQR = âˆ POQ + âˆ QPO [R â€“ Q â€“ O]

âˆ´ 70Â° = âˆ POR + âˆ QPO

âˆ´ 70 = 36Â° + âˆ QPO

âˆ´ âˆ QPO = 70Â° â€“ 36Â° = 340

Now, ray OP is tangent at point P and segment PQ is a secant.

âˆ´ âˆ QPO = 1/2 m(arcPQ) [Theorem of angle between tangent and secant]

âˆ´ 34Â° = 1/2 m(arc PQ)

âˆ´ m(arc PQ) = 68Â°

ii. Here, OP = 7.2, OQ = 3.2

Line OP is the tangent at point P [Given]

and seg OR is the secant.

âˆ´ OP

^{2}= OQ Ã— OR [Tangent secant segments theorem]

âˆ´ 7.2

^{2}= 3.2 Ã— OR

âˆ´ 51.84 = 3.2 Ã— OR

âˆ´ OR 51.84/3.2

âˆ´ OR = 16.2 units

Now, OR = OQ + QR [O â€“ Q â€“ R]

âˆ´ 16.2,= 3.2 + QR

âˆ´ QR = 16.2 â€“ 3.2

âˆ´ QR = 13 units

iii. Here, OP = 7.2, OR = 16.2

OP

^{2}= OQ Ã— OR [Tangent secant segments theorem]

âˆ´ 7.2

^{2}= OQ Ã— 16.2

âˆ´ OQ =

âˆ´ OQ = 3.2 units

Now, OR = OQ + QR [O â€“ Q â€“ R]

âˆ´ 16.2 = 3.2 + QR

âˆ´ QR = 16.2 â€“ 3.2

âˆ´ QR = 13 units

**Question 19.In the adjoining figure, circles with centres C and D touch internally at point E. D lies on the inner circle. Chord EB of the outer circle intersects inner circle at point A. Prove that, seg EA â‰… seg AB.Given: Circles with centres C and D touch each other internally.To prove: seg EA â‰… seg ABConstruction: Join seg ED and seg DA.Proof:**

E â€“ C â€“ D [Theorem of touching circles]

seg ED is the diameter of smaller circle.

âˆ´âˆ EAD = 90Â° [Angle inscribed in a semicircle]

âˆ´ seg AD âŠ¥ chord EB

âˆ´ seg EA â‰… seg AB [Perpendicular drawn from the centre of the circle to the chord bisects the chord]

**Question 20.In the adjoining figure, seg AB is a diameter of a circle with centre O. The bisector of âˆ ACB intersects the circle at point D. Prove that, seg AD â‰… seg BD. Complete the following proof by filling the blanks.Given: seg AB is a diameter, seg CD bisects âˆ ACB.To prove: seg AD â‰… seg BDConstruction: Draw seg OD.Proof:**

âˆ ACB = 90Â° [Angle inscribed in a semicircle]

âˆ DCB = âˆ DCA = 45Â° [CD is the bisector of âˆ C]

m(arcDB) = 2âˆ DCA = 90Â° [Inscribed angle theorem]

âˆ DOB = m(arc DB) = 90Â° â€¦â€¦â€¦â€¦ (i) [Definition of measure of arc]

segOA â‰… segOB â€¦â€¦â€¦â€¦. (ii) [[Radii of the same circle]

âˆ´ line OD is the perpendicular biscctor of [From (i) and (ii)]

seg AB.

âˆ´ seg AD â‰… seg BD

**Question 21.In the adjoining figure, seg MN is a chord of a circle with centre O. MN = 25, L is a point on chord MN such that ML = 9 and d(0, L) = 5. Find the radius of the circle.Construction: Draw seg OK âŠ¥ chord MN. Join OM.Solution:**

seg OK âŠ¥chord MN [Construction]

âˆ´ MK = 1/2 MN [Perpendicular drawn from the centre of the circle to the chord bisects the chord]

= 1/2 Ã— 25

= 12.5 units

MK = ML + LK [M â€“ L â€“ K]

âˆ´ 12.5 = 9 + LK

âˆ´ LK= 12.5 â€“ 9 = 3.5 units

In âˆ†OKL, âˆ OKL = 90Â°

âˆ´ OL

^{2}= KL

^{2}+ OK

^{2}[Pythagoras theorem]

âˆ´ 5

^{2}= 3.5

^{2}+ OK

^{2}

âˆ´ OK

^{2}= 25 â€“ 12.25 = 12.75

Now, in âˆ†OKM, âˆ OKM = 90Â°

âˆ´ OM

^{2}= OK

^{2}+ MK

^{2}

= 12.75 + 12.52

= 12.75 + 156.25

= 169

= 13 units [Taking square root of both sides]

âˆ´ The radius of the given circle is 13 units.

**Question 22.In the adjoining figure, two circles intersect each other at points S and R. Their common tangent PQ touches the circle at points P, Q.Prove that, âˆ PRQ + âˆ PSQ = 180Â°.Given: Two circles intersect each other at points S and R.line PQ is a common tangent.To prove: âˆ PRQ + âˆ PSQ = 180Â°Proof:**

Line PQ is the tangent at point P and seg PR is a secant.

âˆ´ [âˆ RPQ = âˆ PSR â€¦â€¦â€¦â€¦. (i)

and âˆ PQR = âˆ QSR] â€¦â€¦â€¦â€¦ (ii) [Tangent secant theorem]

In âˆ† PQR,

âˆ PQR + âˆ PRQ + âˆ RPQ = 180Â° [Sum of the measures of angles of a triangle is 180Â°]

âˆ´ âˆ QSR + âˆ PRQ + âˆ PSR = 180Â° [From (i) and (ii)]

âˆ´ âˆ PRQ + âˆ QSR + âˆ PSR = 180Â°

âˆ´ âˆ PRQ + âˆ PSQ = 180Â° [Angle addition property]

**Question 23.In the adjoining figure, two circles intersect at points M and N. Secants drawn through M and N intersect the circles at points R, S and P, Q respectively. Prove that: seg SQ || seg RP.Given: Two circles intersect each other at points M and N.To prove: seg SQ || seg RPConstruction: Join seg MN.Proof:**

â–¡RMNP is a cyclic quadrilateral.

âˆ´ âˆ MRP = âˆ MNQ â€¦â€¦â€¦â€¦. (i) [Corollary of cyclic quadrilateral theorem]

Also, â–¡MNQS is a cyclic quadrilateral.

âˆ´ âˆ MNQ+ âˆ MSQ = 180Â° [Theorem of cyclic quadrilateral]

âˆ´ âˆ MRP + âˆ MSQ = 180Â° [From (i)]

But, they are a pair of interior angles on the sarpe side of transversal RS on lines SQ and RP.

âˆ´ seg SQ || seg RP [Interior angles test]

**Question 24.In the adjoining figure, two circles intersect each other at points A and E. Their common secant through E intersects the circles at points B and D. The tangents of the circles at points B and D intersect each other at point C. Prove that â–¡ABCD is cyclic.Given: Two circles intersect each other at A and E. seg BC and seg CD are the tangents to the circles.To prove: â–¡ABCD is cyclic.Construction: Draw AB, AE and AD.Proof:**

[âˆ EBC = âˆ BAE (i)

âˆ EDC = âˆ DAE ] (ii) [Tangent secant theorem]

In âˆ†BCD,

âˆ DBC + âˆ BDC + âˆ BCD = 180Â° [Sum of the measures of angles of a triangle is 180Â°]

âˆ´ âˆ EBC + âˆ EDC + âˆ BCD = 180Â° (iii) [B â€“ E â€“ D]

âˆ´ âˆ BAE + âˆ DAE + âˆ BCD = 180Â° [From (i), (ii) and (iii)]

âˆ´ âˆ BAD + âˆ BCD = 180Â° [Angle addition property]

âˆ´ â–¡ABCD is cyclic. [Converse of cyclic quadrilateral theorem]

**Question 25.In the adjoining figure, seg AD âŠ¥ side BC, seg BE âŠ¥ side AC, seg CF âŠ¥ side AB. Point O is the orthocentre. Prove that, point O is the incentre of âˆ†DEF.Given: seg AD âŠ¥ side BC,seg BE âŠ¥ side AC,seg CF âŠ¥ side AB.To prove: Point O is the incentre of âˆ†DEF.Construction: Draw DE, EF and DF.Proof:**

âˆ OFA = âˆ OEA = 90Â° [Given]

Now, âˆ OFA + âˆ OEA = 90Â° + 90Â°

âˆ´ âˆ OFA + âˆ OEA = 180Â°

âˆ´ â–¡OFAE is a cyclic quadrilateral. [Converse of cyclic quadrilateral theorem]

âˆ´ Points O, F, A, E are concyclic points.

âˆ´ seg 0E subtends equal angles âˆ OFE and âˆ OAE on the same side of OE.

âˆ´ âˆ OFE = âˆ OAE â€¦â€¦â€¦ (i)

âˆ OFB âˆ ODB = 90Â° [Given]

Now, âˆ OFB + âˆ ODB = 90Â° + 90Â°

âˆ´ âˆ OFB + âˆ ODB = 180Â°

âˆ´ ê ¸OFBD is a cyclic quadrilateral. [Converse of cyclic quadrilateral theorem]

âˆ´ Points O, F, B, D are concyclic points.

âˆ´ seg OD subtends equal angles âˆ OFD and

âˆ OBD on the same side of OD.

âˆ OFD = âˆ OBD â€¦â€¦â€¦â€¦.. (ii)

In âˆ†AEO and âˆ†BDO,

âˆ AEO = âˆ BDO [Each angle is 90Â°]

âˆ AOE = âˆ BOD [Vertically opposite angles]

âˆ´ âˆ†AEO ~ âˆ†BDO [AA test of similarity]

âˆ´ âˆ OAE = âˆ OBD â€¦â€¦â€¦â€¦â€¦.. (iii) [Corresponding angles of similar triangles]

âˆ´ âˆ OFE = âˆ OFD [From (i), (ii) and (iii)]

âˆ´ ray FO bisects âˆ EFD.

Similarly, we can prove ray EO and ray DO bisects âˆ FED and âˆ FDE respectively.

âˆ´ Point O is the intersection of angle bisectors of âˆ D, âˆ E and âˆ F of âˆ†DEF.

âˆ´ Point O is the incentre of âˆ†DEF.