Exercise: 10.1
1. How many tangents can a
circle have?
Answer:
There can be infinite tangents to a circle. A circle is made up of infinite
points which are at an equal distance from a point. Since there are infinite
points on the circumference of a circle, infinite tangents can be drawn from
them.
2. Fill in the blanks:
(i) A tangent to a circle
intersects it in ............... point(s).
(ii) A line intersecting a
circle in two points is called a .............
(iii) A circle can have
............... parallel tangents at the most.
(iv) The common point of a
tangent to a circle and the circle is called ............
Answer:
(i)
A tangent to a circle
intersects it in one point(s).
(ii)
A line intersecting a
circle in two points is called a secant.
(iii)
A circle can have two parallel
tangents at the most.
(iv)
The common point of a
tangent to a circle and the circle is called the point of contact.
3.
A tangent PQ at a point P of a circle of radius 5 cm meets a line through the
centre O at a point Q so that OQ = 12 cm. Length PQ is :
(A) 12 cm
(B) 13 cm
(C) 8.5 cm
(D) √119 cm
Answer:
In the above figure, the line
that is drawn from the centre of the given circle to the tangent PQ is
perpendicular to PQ.
And so, OP ⊥ PQ
Using Pythagoras theorem in
triangle ΔOPQ we get,
OQ2 = OP2+PQ2
(12)2 = 52+PQ2
PQ2 = 144-25
PQ2 = 119
PQ = √119 cm
So, option
D i.e. √119 cm is the length of PQ.
4.
Draw a circle and two lines parallel to a given line such that one is a tangent
and the other, a secant to the circle.
Answer:
In the above figure, XY and AB
are two the parallel lines. The line segment AB is the tangent at point C while the line segment XY is the
secant.
Exercise:
10.2
In
Q.1 to 3, choose the correct option and give justification.
1. From a point Q, the length of the tangent to
a circle is 24 cm and the distance of Q from the centre is 25 cm. The radius of
the circle is
(A) 7 cm
(B) 12 cm (C) 15 cm
(D) 24.5 cm
Answer:
First, draw a perpendicular from
the center O of the triangle to a point P on the circle which is touching the
tangent. This line will be perpendicular to the tangent of the circle.
So,
OP is perpendicular to PQ i.e. OP ⊥
PQ
From the above figure, it is also
seen that △OPQ is a right
angled triangle.
It is given that
OQ = 25 cm and PQ = 24 cm
By using Pythagoras theorem in △OPQ,
OQ2 = OP2 +PQ2
(25)2 = OP2+(24)2
OP2 = 625-576
OP2 = 49
OP = 7 cm
So, option A i.e. 7 cm is the
radius of the given circle.
2. In Fig. 10.11, if TP and TQ are the two
tangents to a circle with centre O so that ∠POQ =
110°,
then ∠PTQ is equal to
(A) 60°
(B) 70°
(C) 80°
(D) 90°
Answer:
From the question, it is clear
that OP is the radius of the circle to the tangent PT and OQ is the radius to
the tangents TQ.
So, OP ⊥ PT and TQ ⊥ OQ
∴∠OPT
= ∠OQT = 90°
Now, in the quadrilateral POQT,
we know that the sum of the interior angles is 360°
So, ∠PTQ+∠POQ+∠OPT+∠OQT = 360°
Now, by putting the respective values we get,
∠PTQ +90°+110°+90° = 360°
∠PTQ = 70°
So, ∠PTQ is 70° which is option B.
3. If tangents PA and PB from a point P to a
circle with centre O are inclined to each other at angle of 80°, then ∠ POA is equal to
(A) 50°
(B) 60°
(C) 70°
(D) 80°
Answer:
First, draw the diagram according
to the given statement.
Now, in the above diagram, OA is
the radius to tangent PA and OB is the radius to tangents PB.
So, OA is perpendicular to PA and
OB is perpendicular to PB i.e. OA ⊥
PA and OB ⊥ PB
So,
∠OBP = ∠OAP = 90°
Now, in the quadrilateral AOBP,
The sum of all the interior
angles will be 360°
So, ∠AOB+∠OAP+∠OBP+∠APB
= 360°
Putting their values, we get,
∠AOB + 260° = 360°
∠AOB = 100°
Now, consider the triangles △OPB and △OPA. Here,
AP = BP (Since the tangents from
a point are always equal)
OA = OB (Which are the radii of
the circle)
OP = OP (It is the common side)
Now, we can say that triangles
OPB and OPA are similar using SSS congruency.
∴△OPB
≅ △OPA
So, ∠POB = ∠POA
∠AOB = ∠POA+∠POB
2 (∠POA) = ∠AOB
By putting the respective values,
we get,
=>∠POA
= 100°/2 = 50°
As
angle ∠POA is 50° option A is the correct option.
4. Prove that the tangents
drawn at the ends of a diameter of a circle are parallel.
Answer:
First, draw a circle and connect
two points A and B such that AB becomes the diameter of the circle. Now, draw
two tangents PQ and RS at points A and B respectively.
Now, both radii i.e. AO and OP
are perpendicular to the tangents.
So, OB is perpendicular to RS and
OA perpendicular to PQ
So, 
OAP = 
OAQ = OBR = 
OBS = 90°
From the above figure, angles OBR
and OAQ are alternate interior angles.
Also, 
OBR = OAQ and OBS = OAP (Since they are also
alternate interior angles)
So, it can be said that line PQ
and the line RS will be parallel to each other. (Hence Proved).
5. Prove that the
perpendicular at the point of contact to the tangent to a circle passes through
the center.
Solution:
First, draw a circle with center
O and draw a tangent AB which touches the radius of the circle at point P.
To Proof: PQ passes through point O.
Now, let us consider that PQ
doesn't pass through point O. Also, draw a CD parallel to AB through O. Here,
CD is a straight line and AB is the tangent. Refer the diagram now.
From the above diagram, PQ
intersects CD and AB at R and P respectively.
AS, CD ∥ AB,
Here, the line segment PQ is the
line of intersection.
Now angles ORP and RPA are equal
as they are alternate interior angles
So, ∠ORP = ∠RPA
And,
∠RPA = 90° (Since,
PQ is perpendicular to AB)
∠ORP = 90°
Now, ∠ROP+∠OPA = 180° (Since they are
co-interior angles)
∠ROP+90° = 180°
∠ROP = 90°
Now, it is seen that the △ORP has two right angles which are
∠ORP and ∠ROP. Since this condition is impossible, it can be said
the supposition we took is wrong.
6. The length of a tangent from a point A at
distance 5 cm from the centre of the circle is 4 cm. Find the radius of the
circle.
Answer:
Draw the diagram as shown
below.
Here, AB is the tangent that is
drawn on the circle from a point A.
So, the radius OB will be
perpendicular to AB i.e. OB ⊥
AB
We know, OA = 5cm and AB = 4
cm
Now, In △ABO,
OA2 =AB2+BO2
(Using Pythagoras theorem)
52 =
42+BO2
BO2 = 25-16
BO2 = 9
BO = 3
So,
the radius of the given circle i.e. BO is 3 cm.
7.
Two concentric circles are of radii 5 cm and 3 cm. Find the length of the chord
of thelarger circle which touches the smaller circle.
Answer:
Draw two concentric circles with
the center O. Now, draw a chord AB in the larger circle which touches the
smaller circle at a point P as shown in the figure below.
From the above diagram, AB is
tangent to the smaller circle to point P.
∴
OP ⊥ AB
Using Pythagoras theorem in
triangle OPA,
OA2= AP2+OP2
52 = AP2+32
AP2 = 25-9
AP = 4
Now, as OP ⊥ AB,
Since the perpendicular from the
center of the circle bisects the chord, AP will be equal to PB
So, AB = 2AP = 2×4 = 8 cm
So, the length of the chord of the larger
circle is 8 cm.
8.
A quadrilateral ABCD is drawn to circumscribe a circle (see Fig. 10.12). Prove
that AB + CD = AD + BC
Answer:
The figure given is:
From this figure we can conclude
a few points which are:
(i)
DR = DS
(ii)
BP = BQ
(iii)
AP = AS
(iv)
CR = CQ
Since they are tangents on the
circle from points D, B, A, and C respectively.
Now, adding the LHS and RHS of
the above equations we get,
DR+BP+AP+CR = DS+BQ+AS+CQ
By rearranging them we get,
(DR+CR) + (BP+AP) = (CQ+BQ) +
(DS+AS)
By
simplifying,
AD+BC= CD+AB
9.
In Fig. 10.13, XY and X′Y′ are two parallel tangents to a circle with centre O
and another tangent AB with point of contact C intersecting XY at A and X′Y′ at
B. Prove that ∠ AOB = 90°.
Answer:
From the figure given in the
textbook, join OC. Now, the diagram will be as-
Now the triangles △OPA and △OCA are similar using SSS congruency as:
(i)
OP = OC →They are the radii of the same
circle
(ii)
AO = AO → It is the common side
(iii)
AP = AC → These are the tangents from
point A
So,
△OPA ≅ △OCA
Similarly,
△OQB
≅ △OCB
So,
∠POA
= ∠COA … (Equation i)
And, ∠QOB = ∠COB
… (Equation ii)
Since the line POQ is a straight
line, it can be considered as a diameter of the circle.
So, ∠POA +∠COA
+∠COB +∠QOB = 180°
Now, from equations (i) and
equation (ii) we get,
2∠COA+2∠COB = 180°
∠COA+∠COB
= 90°
∴∠AOB
= 90°
10. Prove that the angle between the two tangents
drawn from an external point to a circle is supplementary to the angle
subtended by the line-segment joining the points of contact at the center.
Answer:
First, draw a circle with centre
O. Choose an external point P and draw two tangents PA and PB at point A and
point B respectively. Now, join A and B to make AB in a way that it subtends ∠AOB at the center of the circle.
The diagram is as follows:
From the above diagram, it is
seen that the line segments OA and PA are perpendicular.
So, ∠OAP = 90°
In a similar way, the line
segments OB ⊥ PB and so,∠OBP = 90°
Now, in the quadrilateral
OAPB,
∴∠APB+∠OAP +∠PBO +∠BOA
= 360° (since the sum of all interior angles will be 360°)
By
putting the values we get,
∠APB + 180° + ∠BOA = 360°
So, ∠APB + ∠BOA
= 180° (Hence proved).
11.
Prove that the parallelogram circumscribing a circle is a rhombus.
Answer:
Consider a parallelogram ABCD
which is circumscribing a circle with a center O. Now, since ABCD is a
parallelogram, AB = CD and BC = AD.
From the above figure, it is seen
that,
(i)
DR = DS
(ii)
BP = BQ
(iii)
CR = CQ
(iv)
AP = AS
These are the tangents to the
circle at D, B, C, and A respectively.
Adding all these we get,
DR+BP+CR+AP = DS+BQ+CQ+AS
By rearranging them we get,
(BP+AP)+(DR+CR)
= (CQ+BQ)+(DS+AS)
Again
by rearranging them we get,
AB+CD
= BC+AD
Now, since AB = CD and BC = AD,
the above equation becomes
2AB = 2BC
∴
AB = BC
Since AB = BC = CD = DA, it can
be said that ABCD is a rhombus.
12.
A triangle ABC is drawn to circumscribe a circle of radius 4 cm such that the
segments BD and DC into which BC is divided by the point of contact D are of
lengths 8 cm and 6 cm respectively (see Fig. 10.14). Find the sides AB and AC.
Answer:
The figure given is as follows:
Consider the triangle ABC,
We know that the length of any
two tangents which are drawn from the same point to the circle is equal.
So,
(i)
CF = CD = 6 cm
(ii)
BE = BD = 8 cm
(iii)
AE = AF = x
Now, it can be observed that,
(i)
AB = EB+AE = 8+x
(ii)
CA = CF+FA = 6+x
(iii)
BC = DC+BD = 6+8 = 14
Now the semi perimeter “s” will
be calculated as follows
2s
= AB+CA+BC
By putting the respective values
we get,
2s = 28+2x
s
= 14+x
By solving this we get,
= √(14+x)48x ......... (i)
Again, the area of △ABC = 2 × area of (△AOF + △COD + △DOB)
=
2×[(½×OF×AF)+(½×CD×OD)+(½×DB×OD)]
= 2×½(4x+24+32) = 56+4x ..............(ii)
Now from (i) and (ii) we get,
√(14+x)48x = 56+4x
Now, square both the sides,
48x(14+x) = (56+4x)2
48x = [4(14+x)]2/(14+x)
48x = 16(14+x)
48x = 224+16x
32x = 224
x = 7 cm So, AB = 8+x
i.e. AB = 15 cm
And, CA = x+6 =13 cm.
13. Prove that opposite sides of a quadrilateral
circumscribing a circle subtend supplementary angles at the centre of the
circle.
Answer:
First draw a quadrilateral ABCD
which will circumscribe a circle with its centre O in a way that it touches the
circle at point P, Q, R, and S. Now, after joining the vertices of ABCD we get
the following figure:
Now, consider the triangles OAP
and OAS,
AP = AS (They are the tangents
from the same point A)
OA = OA (It is the common side)
OP = OS (They are the radii of the circle) So, by SSS congruency △OAP ≅ △OAS So, ∠POA = ∠AOS
Which
implies that∠1 = ∠8
Similarly, other angles will be,
∠4
= ∠5
∠2
= ∠3
∠6
= ∠7
Now by adding these angles we
get,
∠1+∠2+∠3
+∠4 +∠5+∠6+∠7+∠8 = 360°
Now
by rearranging,
(∠1+∠8)+(∠2+∠3)+(∠4+∠5)+(∠6+∠7)
= 360°
2∠1+2∠2+2∠5+2∠6
= 360°
Taking
2 as common and solving we get,
(∠1+∠2)+(∠5+∠6) = 180°
Thus, ∠AOB+∠COD
= 180°
Similarly, it can be proved that ∠BOC+∠DOA
= 180°
Therefore, the opposite sides of
any quadrilateral which is circumscribing a given circle will subtend
supplementary angles at the center of the circle.
Comments
Post a Comment