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Page No 5.24:

Question 1:

In each of the following, one of the six trigonometric ratios is given. Find the values of the other trigonometric ratios.

(i) sin A=23
(ii) cos A=45
(iii) tan θ = 11
(iv) sin θ=1115
(v) tan α=512
(vi) sin θ=32
(vii) cos θ=725
(viii) tan θ=815
(ix) cot θ=125
(x) sec θ=135
(xi) cosec θ=10
(xii) cos θ=1215

Answer:

(i) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Perpendicular side = 2 and

Hypotenuse = 3

Therefore, by Pythagoras theorem,

Now we substitute the value of perpendicular side (BC) and hypotenuse (AC) and get the base side (AB)

Therefore,

Hence, Base =

Now,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(ii) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 4 and

Hypotenuse = 5

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and hypotenuse (AC) and get the perpendicular side (BC)

Hence, Perpendicular side = 3

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(iii) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 1 and

Perpendicular side = 5

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and the perpendicular side (BC) and get hypotenuse (AC)

Hence, Hypotenuse =

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(iv) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Perpendicular side = 11 and

Hypotenuse = 15

Therefore,

By Pythagoras theorem,

Now we substitute the value of perpendicular side (BC) and hypotenuse(AC) and get the base side (AB)

Hence, Base =

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(v) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 12 and

Perpendicular side = 5

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and the perpendicular side (BC) and get hypotenuse (AC)

Hence, Hypotenuse = 13

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(vi) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Perpendicular side = and

Hypotenuse = 2

Therefore,

By Pythagoras theorem,

Now we substitute the value of perpendicular side (BC) and hypotenuse(AC) and get the base side (AB)

Hence, Base = 1

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(vii) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 7 and

Hypotenuse = 25

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and hypotenuse (AC) and get the perpendicular side (BC)

Hence, Perpendicular side = 24

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(viii) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 15 and

Perpendicular side = 8

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and the perpendicular side (BC) and get hypotenuse (AC)

Hence, Hypotenuse = 17

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(ix) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 12 and

Perpendicular side = 5

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and the perpendicular side (BC) and get hypotenuse (AC)

Hence, Hypotenuse = 13

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(x) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 5 and

Hypotenuse = 13

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and hypotenuse (AC) and get the perpendicular side (BC)


Hence, Perpendicular side = 12

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

(xi) Given:

…… (1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Perpendicular side = 1 and

Hypotenuse =

Therefore,

By Pythagoras theorem,

Now we substitute the value of perpendicular side (BC) and hypotenuse (AC) and get the base side (AB)

Hence, Base side = 3

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

 

(xii) Given: ……(1)

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Base = 12 and

Hypotenuse = 15

Therefore,

By Pythagoras theorem,

Now we substitute the value of base side (AB) and hypotenuse (AC) and get the perpendicular side (BC)

Hence, Perpendicular side = 9

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,

Now,

Therefore,



Page No 5.25:

Question 2:

In a ∆ABC, right angled at B, AB = 24 cm, BC = 7 cm. Determine

(i) sin A, cos A
(ii) sin C, cos C

Answer:

(i) The given triangle is below:-

Given: In ,

To Find:

In this problem, Hypotenuse side is unknown

Hence we first find Hypotenuse side by Pythagoras theorem

By Pythagoras theorem,

We get,

By definition,

By definition,

Answer:

(ii) The given triangle is below:

Given: In ΔABC,

To Find:

In this problem, Hypotenuse side is unknown

Hence we first find Hypotenuse side by Pythagoras theorem

By Pythagoras theorem,

We get,

By definition,

By definition,

Answer:

Page No 5.25:

Question 3:

In the given figure, find tan P and cot R. Is tan P = cot R?
 

Answer:

The given figure is below:

To Find:

In the given right angled ΔPQR, length of side QR is unknown.

Therefore, to find length of side QR we use Pythagoras Theorem

Hence, by applying Pythagoras theorem in ΔPQR,

We get,

Now, we substitute the length of given side PR and PQ in the above equation

By definition, we know that

… (1)

Also, by definition, we know that

… (2)

Comparing equation (1) and (2) , we come to know that R.H.S of both the equation are equal

Therefore, L.H.S of both the equation are also equal

Answer:

Page No 5.25:

Question 4:

If sin A=941, compute cos A and tan A.

Answer:

Given: ……(1)

To Find:

By definition,

…... (2)

By Comparing (1) and (2)

We get,

Perpendicular side = 9 and

Hypotenuse = 41

Now using the perpendicular side and hypotenuse we can construct as shown below

Length of side AB is unknown in right angled ,

To find length of side AB, we use Pythagoras theorem.

Therefore, by applying Pythagoras theorem in ,

We get,

Hence, length of side AB = 40

Now,

By definition,

Now,

By definition,

Answer: and

Page No 5.25:

Question 5:

Given 15 cot A = 8, find sin A and sec A.

Answer:

Given: 15 = 8

To Find:

Since

By taking 15 on R.H.S

We get,

By definition,

Hence,

Comparing equation (1) and (2)

We get,

= 8

= 15

can be drawn as shown below using above information

Hypotenuse side AC is unknown.

Therefore, we find side AC of by Pythagoras theorem.

So, by applying Pythagoras theorem to

We get,

Therefore, Hypotenuse = 17

Now by definition,

Substituting values of sides from the above figure

By definition,

Hence,

Answer: and

Page No 5.25:

Question 6:

In ∆PQR, right angled at Q, PQ = 4 cm and RQ = 3 cm. Find the values of sin P, sin R, sec P and sec R.

Answer:

Given:

is right angled at vertex Q.

To find:

Given is as shown below

Hypotenuse side PR is unknown.

Therefore, we find side PR of by Pythagoras theorem

By applying Pythagoras theorem to

We get,

Hence, Hypotenuse = 5

Now by definition,

Substituting values of sides from the above figure

Now by definition,

Substituting values of sides from the above figure

By definition,

By definition,

Substituting values of sides from the above figure

Answer: , , and

Page No 5.25:

Question 7:

If cot θ=78, evaluate :

(i) 1+ sin θ 1- sin θ1+cos θ 1-cos θ
(ii) cot2 θ

Answer:

(i) Given:

To evaluate:

…… (1)

We know the following formula

By applying the above formula in the numerator of equation (1) ,

We get,

… (Where a = 1 and b = )

…… (2)

Similarly,

By applying formula in the denominator of equation (1) ,

We get,

… (Where a = 1 and b = )

…… (3)

Substituting the value of numerator and denominator of equation (1) ,from equation (2) and(3)

Therefore,

…… (4)

Since,

Therefore,

Putting the value of and in Equation (4)

We get,

We know that,

Since,

Therefore,

Answer:

(ii) Given:

To evaluate:

Squaring on both sides,

We get,

Answer:

Page No 5.25:

Question 8:

If 3 cot A = 4, check whether 1-tan2 A1+tan2 A=cos2 A-sin2 A or not.

Answer:

Given:

To check whether or not

Dividing by 3 on both sides,

We get,

…… (1)

By definition,

Therefore,

…… (2)

Comparing Equation (1) and (2)

We get,

= 4

= 3

Hence, is as shown in figure below

In, Hypotenuse is unknown

Hence, It can be found by using Pythagoras theorem

Therefore by applying Pythagoras theorem in

We get

Hence, Hypotenuse = 5

To check whether or not

We get the values of

By definition,

Substituting the value from Equation (1)

We get,

….… (3)

Now by definition,

…… (4)

Now by definition,

…… (5)

Now we first take L.H.S of Equation

Substituting value of from equation (3)

We get,

Taking L.C.M on both numerator and denominator

We get,

…… (6)

Now we take R.H.S of Equation

Substituting value of and from equation (4) and (5)

We get,

…… (7)

Comparing Equation (6) and (7)

We get,

Answer: Yes

Page No 5.25:

Question 9:

If tan θ=ab, find the value of cos θ+sin θ cos θ-sin θ.

Answer:

Given:

…… (1)

Now, we know that

Therefore equation (1) becomes as follows

Now, by applying invertendo

We get,

Now, by applying Compenendo-dividendo

We get,

Therefore,

Page No 5.25:

Question 10:

If 3 tan θ = 4, find the value of 4 cos θ-sin θ2 cos θ+sin θ.

Answer:

Given:

Therefore,

…… (1)

Now, we know that

Therefore equation (1) becomes

…… (2)

Now, by applying Invertendo to equation (2)

We get,

…… (3)

Now, multiplying by 4 on both sides

We get,

Therefore

Now by applying dividendo in above equation

We get,

…… (4)

Now, multiplying by 2 on both sides of equation (3)

We get,

Therefore

Now by applying componendo in above equation

We get,

…… (5)

Now, by dividing equation (4) by equation (5)

We get,

Therefore,

Therefore, on L.H.S cancels and we get,

Therefore,

Hence,

Page No 5.25:

Question 11:

If 3 cot θ = 2, find the value of 4 sin θ-3 cos θ2 sin θ+6 cos θ.

Answer:

Given:

Therefore,

…… (1)

Now, we know that

Therefore equation (1) becomes

…… (2)

Now, by applying Invertendo to equation (2)

We get,

…… (3)

Now, multiplying by on both sides

We get,

Therefore, 3 cancels out on R.H.S and

We get,

Now by applying dividendo in above equation

We get,

…… (4)

Now, multiplying by on both sides of equation (3)

We get,

Therefore, 2 cancels out on R.H.S and

We get,

Now by applying componendo in above equation

We get,

…… (5)

Now, by dividing equation (4) by equation (5)

We get,

Therefore,

Therefore, on L.H.S cancels out and we get,

Now, by taking 2 in the numerator of L.H.S on the R.H.S

We get,

Therefore, 2 cancels out on R.H.S. and

We get,

Hence,

Page No 5.25:

Question 12:

If tan θ=ab, prove that a sin θ+b cos θa sin θ+b cos θ=a2-b2a2+b2.

Answer:

Given:

…… (1)

Now, we know that

Therefore equation (1) becomes

…… (2)

Now, multiplying by on both sides of equation (2)

We get,

Therefore,

…... (3)

Now by applying dividendo in above equation (3)

We get,

…… (4)

Now by applying componendo in equation (3)

We get,

…… (5)

Now, by dividing equation (4) by equation (5)

We get,

Therefore,

Therefore, and cancels on L.H.S and R.H.S respectively and we get,

Hence, it is proved that

Page No 5.25:

Question 13:

If sec θ=135, show that 2 sin θ-3 cos θ4 sin θ- 9 cos θ=3.

Answer:

Given:

To show that

Now, we know that

Therefore,

Therefore,

…… (1)

Now, we know that

…… (2)

Now, by comparing equation (1) and (2)

We get,

= 5

And

Hypotenuse = 13

Therefore from above figure

Base side

Hypotenuse

Side AB is unknown, It can be determined by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore,

…… (4)

Now L.H.S. of the equation to be proved is as follows

Substituting the value of and from equation (1) and (4) respectively

We get,

Therefore,

Hence proved that,

Page No 5.25:

Question 14:

If cos θ=1213, show that sin θ (1 − tan θ)=35156.

Answer:

Given: ……(1)

To show that

Now, we know that …… (2)

Therefore, by comparing equation (1) and (2)

We get,

= 12

And

Hypotenuse = 13

Therefore from above figure

Base side

Hypotenuse

Side AB is unknown and it can be determined by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore,

…… (4)

Now, we know that

Now from figure (a)

We get,

Therefore,

…… (5)

Now L.H.S. of the equation to be proved is as follows

…… (6)

Substituting the value of and from equation (4) and (5) respectively

We get,

Taking L.C.M inside the bracket

We get,

Therefore,

Now, by opening the bracket and simplifying

We get,

…… (7)

From equation (6) and (7) , it can be shown that

Page No 5.25:

Question 15:

If cot θ=13, show that 1-cos2 θ2-sin2 θ=35.

Answer:

Given: ……(1)

To show that

Now, we know that

Since

Therefore,

Therefore,

…… (2)

Comparing Equation (1) and (2)

We get,

= 1

Therefore, Triangle representing angle is as shown below

Hypotenuse AC is unknown and it can be found by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (4)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (5)

Now, L.H.S of the equation to be proved is as follows

Substituting the value of and from equation (4) and (5)

We get,

Now by taking L.C.M. in numerator as well as denominator

We get,

Therefore,

Therefore,

Therefore,

Hence proved that



Page No 5.26:

Question 16:

If tan θ=17, show that cosec2 θ-sec2 θcosec2 θ+sec2 θ=34

Answer:

Given: ……(1)

To show that

Now, we know that

Since ……(2)

Therefore,

Comparing Equation (1) and (2)

We get,

Therefore, Triangle representing angle is as shown below

Hypotenuse AC is unknown and it can be found by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (4)

Now, we know that

Therefore, from equation (4)

We get,

Therefore,

…… (5)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (6)

Now, we know that

Therefore, from equation (6)

We get,

Therefore,

…… (7)

Now, L.H.S of the equation to be proved is as follows

Substituting the value of and from equation (6) and (7)

We get,

Now by taking L.C.M. in numerator as well as denominator

We get,

Therefore,

Therefore,

Therefore,

Hence proved that

Page No 5.26:

Question 17:

If sin θ=1213, find the value of sin2 θ-cos2 θ2 sin θ cos θ×1tan2 θ.

Answer:

Given: ……(1)

To Find: The value of expression

Now, we know that

…… (2)

Now when we compare equation (1) and (2)

We get,

= 12

And

Hypotenuse = 13

Therefore, Triangle representing angle is as shown below

Base side BC is unknown and it can be found by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (4)

Now we know that,

Therefore, substituting the value of and from equation (1) and (4)

We get,

Therefore 13 gets cancelled and we get

…… (5)

Now we substitute the value of , and from equation (1) , (4) and (5) respectively in the expression below

Therefore,

We get,

Therefore by further simplifying we get,

 

Now 169 gets cancelled and gets reduced to

Therefore

Therefore the value of is

That is

Page No 5.26:

Question 18:

If sec θ=54, find the value of sin θ-2 cos θtan θ-cot θ.

Answer:

Given: ……(1)

To find the value of

Now we know that

Therefore,

Therefore from equation (1)

…… (2)

Also, we know that cos2θ+sin2θ=1

Therefore,

Substituting the value of from equation (2)

We get,

        

Therefore

…… (3)

Also, we know that sec2θ=1+tan2θ.

Therefore,

tan2θ=sec2θ-1

Therefore

tan2θ=542-1       =2516-1       =916

Therefore,

tanθ=916      =34

Therefore,

tanθ=34 …… (4)

Also cotθ=1tanθ

Therefore, from equation (4)

We get,

cotθ=134

 cotθ=43…… (5)

Substituting the value of,,and from equation (2) (3) (4) and (5) respectively in the expression below

We get,

sinθ-2cosθtanθ-cotθ=35-24534-43                    =35-853×3-4×44×3                    =35-853×3-4×44×3                    =3-859-164×3                    =-55-712                    =127

 

Therefore,

Page No 5.26:

Question 19:

If cos θ=513, find the value of sin2 θ-cos2 θ2 sin θ cos θ×1tan2 θ.

Answer:

Given: ……(1)

To Find:

The value of expression

Now, we know that

…… (2)

Now when we compare equation (1) and (2)

We get,

= 512

And

Hypotenuse = 13

Therefore, Triangle representing angle is as shown below

Perpendicular side AB is unknown and it can be found by using Pythagoras theorem

Therefore by applying Pythagoras theorem

We get,

Therefore by substituting the values of known sides

We get,

Therefore,

Therefore,

…… (3)

Now, we know that

Now from figure (a)

We get,

Therefore from figure (a) and equation (3) ,

…… (4)

Now we know that,

Therefore, substituting the value of and from equation (1) and (4)

We get,

Therefore 13 gets cancelled and we get

…… (5)

Now we substitute the value of, and from equation (1) , (4) and (5) respectively in the expression below

Therefore,

We get,

Therefore by further simplifying we get,

Now 169 gets cancelled and gets reduced to

Therefore

Therefore the value of is

That is

Page No 5.26:

Question 20:

If tan θ=1213, find the value of 2 sin θ cos θcos2 θ-sin2 θ

Answer:

Given: ……(1)

To find the value of

Now, we know the following trigonometric identity

Therefore, by substituting the value of from equation (1) ,

We get,

By taking L.C.M. on the R.H.S,

We get,

Therefore

Therefore

…… (2)

Now, we know that

Therefore,

Therefore

…… (3)

Now, we know the following trigonometric identity

Therefore,

Now by substituting the value of from equation (3)

We get,

Therefore, by taking L.C.M on R.H.S

We get,

Now, by taking square root on both sides

We get,

Therefore,

…… (4)

Substituting the value of and from equation (3) and (4) respectively in the expression below

Therefore,

Therefore,

Page No 5.26:

Question 21:

If cos θ=35, find the value of sin θ-1tan θ2 tan θ.

Answer:

Given: ……(1)

To find the value of

Now, we know the following trigonometric identity

Therefore, by substituting the value of from equation (1) ,

We get,

Therefore,

Therefore by taking square root on both sides

We get,

Therefore,

…… (2)

Now, we know that

Therefore by substituting the value of and from equation (2) and (1) respectively

We get,

…… (4)

Now, by substituting the value of and from equation (2) and (4) respectively in the expression below

We get,

Therefore,

Therefore,

Page No 5.26:

Question 22:

If sin θ=35, evaluate cos θ-1tan θ2 cot θ.

Answer:

Given: ……(1)

To find the value of

Now, we know the following trigonometric identity

Therefore, by substituting the value of from equation (1) ,

We get,

Therefore,

Now by taking L.C.M

We get,

Therefore by taking square root on both sides

We get,

Therefore,

…… (2)

Now, we know that

Therefore by substituting the value of and from equation (1) and (2) respectively

We get,

…… (3)

Also, we know that

Therefore from equation (4) ,

We get,

Therefore,

…… (4)

Now, by substituting the value of, and from equation (2) , (3) and (4) respectively in the expression below

We get,

Therefore,

Page No 5.26:

Question 23:

If sec A=54, verify that 3 sin A-4 sin3 A4 cos3 A-3 cos A=3 tan A-tan3 A1-3 tan2 A.

Answer:

Given:

…… (1)

To verify:

…… (2)

Now we know that

Therefore

Now, by substituting the value of from equation (1)

We get,

Therefore,

…… (3)

Now, we know the following trigonometric identity

Therefore,

Now by substituting the value of from equation (3)

We get,

Now by taking L.C.M

We get,

Now, by taking square root on both sides

We get,

Therefore,

…… (4)

Now, we know that

Now by substituting the value of and from equation (3) and (4) respectively

We get,

Therefore

…… (5)

Now from the expression of equation (2)

Now by substituting the value of and from equation (3) and (4)

We get,

Therefore,

Now by taking L.C.M of both numerator and denominator

We get,

…… (6)

Now from the expression of equation (2)

Now by substituting the value of from equation (5)

We get,

Now by taking L.C.M

We get,

Now,

Therefore,

Therefore,

…… (7)

Now by comparing equation (6) and (7)

We get,

Page No 5.26:

Question 24:

If sin θ=34, prove that cosec2 θ-cot2 θsec2 θ-1=73.

Answer:

Given:

 …… (1)

To prove:

…… (2)

By definition,

…… (3)

By Comparing (1) and (3)

We get,

Perpendicular side = 3 and

Hypotenuse = 4

Side BC is unknown.

So we find BC by applying Pythagoras theorem to right angled,

Hence,

Now we substitute the value of perpendicular side (AB) and hypotenuse (AC) and get the base side (BC)

Therefore,

Hence, Base side BC = …… (3)

Now,

Therefore from fig. a and equation (3)

Therefore,

…… (4)

Now,

Therefore from fig. a and equation (1) ,

…… (5)

Now,

Therefore from fig. a and equation (4) ,

…… (6)

Now,

Therefore by substituting the values from equation (1) and (4) ,

We get,

Therefore,

…… (7)

Now by substituting the value of , and from equation (5) ,(6) and (7) respectively in the L.H.S of expression (2) ,

We get,

Therefore,

Hence it is proved that

Page No 5.26:

Question 25:

If sec A=178, verify that 3-4 sin2 A4 cos2 A-3=3-tan2 A1-3 tan2 A.

Answer:

Given:

…… (1)

To verify:

…… (2)

Now we know that

Therefore

Now, by substituting the value of from equation (1)

We get,

Therefore,

…… (3)

Now, we know the following trigonometric identity

Therefore,

Now by substituting the value of from equation (3)

We get,

Now by taking L.C.M

We get,

Now, by taking square root on both sides

We get,

Therefore,

…… (4)

Now, we know that

Now by substituting the value of and from equation (3) and (4) respectively

We get,

Therefore

…… (5)

Now from the expression of equation (2)

Now by substituting the value of and from equation (3) and (4)

We get,

Therefore,

Now by taking L.C.M of both numerator and denominator

We get,

Therefore,

…… (6)

Now from the expression of equation (2)

Now by substituting the value of from equation (5)

We get,

Now by taking L.C.M

We get,

Therefore

Therefore,

…… (7)

Now by comparing equation (6) and (7)

We get,

Page No 5.26:

Question 26:

If cot θ=34, prove that sec θ-cosec θsec θ+cosec θ=17.

Answer:

Given:

…… (1)

To prove:

Now we know is defined as follows

…… (2)

Now by comparing equation (1) and (2)

We get,

= 3

= 4

Therefore triangle representing angle is as shown below

Side AC is unknown and can be found using Pythagoras theorem

Therefore,

Now by substituting the value of known sides from figure

We get,

Now by taking square root on both sides

We get,

Therefore Hypotenuse side AC = 5 …… (3)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (4)

Now we know

Therefore by substituting the value of from equation (4)

We get,

Therefore,

…… (5)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (6)

Now we know

Therefore by substituting the value of from equation (6)

We get,

Therefore,

…… (7)

Now, in expression, by substituting the value of andfrom equation (6) and (7) respectively, we get,

L.C.M of 3 and 4 is 12

Now by taking L.C.M in above expression

We get,

Now 12 gets cancelled and we get,

Now

Therefore,

Now 5 gets cancelled and we get,

Therefore, it is proved that

Page No 5.26:

Question 27:

If tan θ=247, find that sin θ + cos θ.

Answer:

Given:

…… (1)

To find:

Now we know is defined as follows

…… (2)

Now by comparing equation (1) and (2)

We get

= 24

= 7

Therefore triangle representing angle is as shown below

Side AC is unknown and can be found using Pythagoras theorem

Therefore,

Now by substituting the value of known sides from figure

We get,

Now by taking square root on both sides

We get,

Therefore Hypotenuse side AC = 25 …… (3)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (4)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (5)

Now we need to find the value of expression

Therefore by substituting the value of andfrom equation (4) and (5) respectively, we get,

Hence

Page No 5.26:

Question 28:

If sin θ=ab, find sec θ + tan θ in terms of a and b.

Answer:

Given:

…… (1)

To find:

Now we know, is defined as follows

…… (2)

Now by comparing (1) and (2)

We get,

= a

and

Hypotenuse = b

Therefore triangle representing angle is as shown below

Here side BC is unknown

Now we find side BC by applying Pythagoras theorem to right angled

Therefore,

Now by substituting the value of sides AB and AC from figure (a)

We get,

Therefore,

Now by taking square root on both sides

We get,

Therefore,

Base side …… (3)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (4)

Now we know,

Therefore,

Therefore,

…… (5)

Now we know,

Now by substituting the values from equation (1) and (3)

We get,

Therefore,

…… (6)

Now we need to find

Now by substituting the value of and from equation (5) and (6) respectively

We get,

…… (7)

Now we have the following formula which says

Therefore by applying above formula in equation (7)

We get,

Now by substituting in above expression

We get,


Now present in the numerator as well as denominator of above expression gets cancels and we get,

Square root is present in the numerator as well as denominator of above expression

Therefore we can place both numerator as well as denominator under a common square root sign

Therefore,

Page No 5.26:

Question 29:

If 8 tan A = 15, find sin A − cos A.

Answer:

Given:

Therefore,

…… (1)

To find:

Now we know is defined as follows

…… (2)

Now by comparing equation (1) and (2)

We get

= 15

= 8

Therefore triangle representing angle A is as shown below

Side AC is unknown and can be found using Pythagoras theorem

Therefore,

Now by substituting the value of known sides from figure (a)

We get,

Now by taking square root on both sides

We get,

Therefore Hypotenuse side AC = 17 …… (3)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (4)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (5)

Now we need to find the value of expression

Therefore by substituting the value of andfrom equation (4) and (5) respectively, we get,

Hence

Page No 5.26:

Question 30:

If 3 cos θ − 4 sin θ = 2 cos θ + sin θ, find tan θ.

Answer:

Given:

To find:

Now consider the given expression

Now by dividing both sides of the above expression by

We get,

Now by separating the denominator for each terms

We get,

Now in the above expression present in both numerator and denominator gets cancelled

Therefore,

…… (1)

Now we know that,

Therefore by substituting in equation (1)

We get,

Now by taking on L.H.S

We get,

Therefore,

Hence

Page No 5.26:

Question 31:

If tan θ=2021, show that 1-sin θ+cos θ1+sin θ+cos θ=37.

Answer:

Given:

…… (1)

To show that:

Now we know is defined as follows

…… (2)

Now by comparing equation (1) and (2)

We get

= 20

= 21

Therefore triangle representing angle is as shown below

Side AC is unknown and can be found using Pythagoras theorem

Therefore,

Now by substituting the value of known sides from figure (a)

We get,

Now by taking square root on both sides

We get,

Therefore Hypotenuse side AC = 29 …… (3)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (4)

Now we know, is defined as follows

Therefore from figure (a) and equation (3)

We get,

…… (5)

Now we need to find the value of expression

Therefore by substituting the value of andfrom equation (4) and (5) respectively, we get,

Now by taking L.C.M on R.H.S of above equation

We get


Now as 10 is present in numerator as well as denominator of R.H.S of above equation, it gets cancelled and we get

Hence

Page No 5.26:

Question 32:

If cosec A = 2, find the value of 1tan A+sin A1+cos A.

Answer:

Given:

…… (1)

To find:

Now we know is defined as below

Therefore,

Now by substituting the value of from equation (1)

We get,

…… (2)

Now by substituting the value of in the following identity of trigonometry

We get,

Now by taking L.C.M we get

Now by taking square root on both sides

We get,

Therefore,

…… (3)

Now is defined as follows

Now by substituting the value of and from equation (2) and (3) respectively we get,

Therefore,

…… (4)

Now by substituting the value of, and from equation (2) , (3) and (4) respectively we get,

Now by taking L.C.M we get

Now 2 gets cancelled and we get

Now by taking L.C.M, we get,

Now by opening the brackets in the numerator

We get,

Therefore,

Now by taking 2 common

We get,


 

Now as is present in both numerator as well as denominator, it gets cancelled

Therefore,



Page No 5.27:

Question 33:

If ∠A and ∠B are acute angles such that cos A = cos B, then show that ∠A = ∠B.

Answer:

Given:

…… (1)

To show:

is as shown in figure below

Now since ……from (1)

Therefore

Now observe that denominator of above equality is same that is AB

Hence only when

Therefore …… (2)

We know that when two sides of a triangle are equal, then angle opposite to the sides are also equal.

Therefore from equation (2)

We can say that

Angle opposite to side AC = Angle opposite to side BC

Therefore,

Hence,

Page No 5.27:

Question 34:

If ∠A and ∠P are acute angles such that tan A = tan P, then show that ∠A = ∠P.

Answer:

Given:

To show:

Consider two right angled triangles ABC and PQR such that

Therefore we have,

and

Since it is given that

Therefore,

Now by interchanging position of AB and QR by cross multiplication

We get,

Let (say) …… (1)

Now by cross multiplication

and …… (2)

Now by using Pythagoras theorem in triangles ABC and PQR

We have,

and

Therefore

and

Now

Now using equation (2)

We get,

Now by taking common

We get,

Therefore,

Now gets cancelled

Therefore,

…… (3)

From (1) and (3)

Therefore,

Hence,

Page No 5.27:

Question 35:

In a ∆ABC, right angled at A, if tan C=3, find the value of sin B cos C + cos B sin C.

Answer:

Given:

To find:

The givenis as shown in figure below

Side BC is unknown and can be found using Pythagoras theorem

Therefore,

Now by substituting the value of known sides from figure (a)

We get,

Now by taking square root on both sides

We get,

Therefore Hypotenuse side BC = 2 …… (1)

Now

Therefore,

Now by substituting the values from equation (1) and figure (a)

We get,

…… (2)

Now

Therefore,

Now by substituting the values from equation (1) and figure (a)

We get,

…… (3)

Now

Therefore,

Now by substituting the values from equation (1) and figure (a)

We get,

…… (4)

Now by definition,

Therefore,

Now by substituting the value of and from equation (4) and given data respectively

We get,

Now gets cancelled as it is present in both numerator and denominator

Therefore,

…… (5)

Now by substituting the value of and from equation (2) , (3) , (4) and (5) respectively in

We get,

Page No 5.27:

Question 36:

State whether the following are true or false. Justify your answer.

(i) The value of tan A is always less than 1.
(ii) sec A=125 for some value of angle A.
(iii) cos A is the abbreviation used for the cosecant of angle A.
(iv) cot A is the product of cot and A.
(v) sin θ=43for some angle θ.

Answer:

(i) In, is acute an angle

Therefore,

Minimum value of is 0° and

Maximum value of is 90°

We know that and

tan90° =

Therefore the statement that;

“The value of is always less than1” is false

(ii)

In and, is acute angle

Therefore,

Minimum value of is 0°and

Maximum value of is

We know that cos0° = 1 and

cos90° = 0

Now,

Therefore minimum value of is …… (1)

Now,

Therefore maximum value of is …… (2)

Now consider the given value

Here,

This value 2.4 lies in between 1 and

Now from equation (1) and (2) , we can say that the value lies in between minimum value of (that is 1) and maximum value of (that is)

Hence, , for some value of angle A is true

(iii) Cosecant of angle A is defined as

Also, is defined as

Therefore,

…… (1)

And

is defined as …… (2)

Therefore from equation (1) and (2) , it is clear that and (that is cosecant of angle A) are two different trigonometric angles

Hence, is the abbreviation used for cosecant of angle A is False

(iv) cot A is a trigonometric ratio which means cotangent of angle A

Hence, is the product of cot and A is False

(v)

The value

In, is acute an angle

Therefore,

Minimum value of is 0° and

Maximum value of is 90°

We know that and

sin90° = 1

Therefore the value of should lie between 0 and 1 and must not exceed 1

Hence the given value for (that is) is not possible

Therefore, , for some angle = False



Page No 5.42:

Question 1:

Evaluate each of the following

sin 45° sin 30° + cos 45° cos 30°

Answer:

We have,

…… (1)

Now

So by substituting above values in equation (1)

We get,

Therefore,

Page No 5.42:

Question 2:

Evaluate each of the following

sin 60 cos 30° + cos 60° sin 30°

Answer:

We have to find the value of the expression

…… (1)

Now,

So by substituting above values in equation (1)

We get,

Therefore,

Page No 5.42:

Question 3:

Evaluate each of the following

cos 60° cos 45° − sin 60° sin 45°

Answer:

We have to find the value of the following expression

…… (1)

Now,,

So by substituting above values in equation (1)

We get,

Therefore,

Page No 5.42:

Question 4:

Evaluate each of the following

sin2 30° + sin2 45° + sin260° + sin2 60° + sin2 90°

Answer:

We have to find

…… (1)

Now,

,, ,

So by substituting above values in equation (1)

We get,

Now by taking denominator 4 together and simplifying

We get,

Now by taking LCM

We get,

Therefore,

Page No 5.42:

Question 5:

Evaluate each of the following

cos2 30° + cos2 45° + cos2 60° + cos2 90°

Answer:

We have to find the following expression

…… (1)

Now,

,, ,

So by substituting above values in equation (1)

We get,

Now by taking denominator 4 together and simplifying

We get,

Now by taking LCM

We get,

Therefore,

Page No 5.42:

Question 6:

Evaluate each of the following

tan2 30° + tan2 60° + tan2 45°

Answer:

We have to find the following expression

…… (1)

Now,

,,

So by substituting above values in equation (1)

We get,

Now by taking LCM

We get,

Therefore,

Page No 5.42:

Question 7:

Evaluate each of the following

2 sin2 30° − 3 cos2 45° + tan260°

Answer:

We have to find the following expression

…… (1)

Now,

,,

So by substituting above values in equation (1)

We get,

In the above equation the first term gets reduced to

Therefore,

In the above equation the first term gets reduced to

Therefore,

Therefore,

Page No 5.42:

Question 8:

Evaluate each of the following

sin2 30° cos2 45° + 4 tan2 30° + 12 sin2 90°-2 cos2 90°+124 cos2 0°

Answer:

We have,

…… (1)

Now,

,, ,,

So by substituting above values in equation (1)

We get,

LCM of 8, 3, 2 and 24 is 48

Therefore by taking LCM

We get,

In the above equation the first term gets reduced to

Therefore,



Page No 5.43:

Question 9:

Evaluate each of the following

4 (sin460° + cos4 30°) − 3 (tan2 60° − tan2 45°) + 5 cos2 45°

Answer:

We have,

…… (1)

Now,

,, ,

So by substituting above values in equation (1)

We get,

Now, gets reduced to

Therefore,

Now, gets reduced to

Therefore,

Now by taking LCM

We get,

Therefore,

Page No 5.43:

Question 10:

Evaluate each of the following

(cosec2 45° sec2 30°) (sin2 30° + 4 cot2 45° − sec2 60°)

Answer:

We have,

…… (1)

Now,

, , , ,

So by substituting above values in equation (1)

We get,

Now, in above equation 4 cancel 8 and 2 remains

Hence,

Therefore,

Page No 5.43:

Question 11:

Evaluate each of the following

cosec3 30° cos 60° tan3 45° sin2 90° sec2 45° cot 30°

Answer:

We have,

…… (1)

Now,

, , , , ,

So by substituting above values in equation (1)

We get,

Now, 2 gets cancelled and we get,

Page No 5.43:

Question 12:

Evaluate each of the following

cot2 30°-2 cos2 60°-34sec2 45°-4 sec2 30°

Answer:

We have,

…… (1)

Now,

,, ,

So by substituting above values in equation (1)

We get,

Now, in the third term 4 gets cancelled by 2 and 2 remains

Therefore,

Now in the second term, 4 gets cancelled by 2 and 2 remains

Therefore,

Now, LCM of denominator in the above expression is 6

Therefore by taking LCM

We get,

Now in the above expression, gets reduced to

Therefore,

Page No 5.43:

Question 13:

Evaluate each of the following

(cos 0° + sin 45° + sin 30°) (sin 90° − cos 45° + cos 60°)

Answer:

We have,

…… (1)

Now,

,,

So by substituting above values in equation (1)

We get,

Now, LCM of both the product terms in the above expression is

Therefore we get,

Now by rearranging terms in the numerator of above expression

We get,

Now, by applying formula in the numerator of the above expression we get,

 …… (2)

Now, we know that

Therefore,

Now, by substituting the above value of in equation (2)

We get,

Now gets reduced to

Therefore,

Hence,

Page No 5.43:

Question 14:

Evaluate each of the following

sin 30°-sin 90°+2 cos 0°tan 30° tan 60°

Answer:

We have,

…… (1)

Now,

,,,

So by substituting above values in equation (1)

We get,

Now, present in the denominator of above expression gets cancelled and we get,

Now by taking LCM in the above expression we get,

Therefore,

Page No 5.43:

Question 15:

Evaluate each of the following

4cot2 30°+1sin2 60°-cos2 45°

Answer:

We have,

…… (1)

Now,

, ,

So by substituting above values in equation (1)

We get,

Now LCM of denominator of above expression is 6

Therefore by taking LCM we get,

Hence,

Page No 5.43:

Question 16:

Evaluate each of the following

4(sin4 30° + cos2 60°) − 3(cos2 45° − sin2 90°) − sin2 60°

Answer:

We have,

…… (1)

Now,

,, ,

So by substituting above values in equation (1)

We get,

LCM of 16 and 4 in the first term of above expression is 16 and

Similarly LCM of 2 and 1 in the second term of above expression is 2

Therefore,

Now in the second term of the above expression

Therefore,

Now, in the above expression 4 cancels 16 and 4 remains in the denominator of first term

Therefore,

Now by taking LCM =4 in the above expression

We get,

Now, in the above expression gets reduced to 2

Therefore,

Page No 5.43:

Question 17:

Evaluate each of the following

tan2 60°+4 cos2 45°+3 sec2 30°+5 cos2 90°cosec 30°+sec 60°-cot2 30°

Answer:

We have,

…… (1)

Now,

, , , , ,

So by substituting above values in equation (1)

We get,

Now,

3 gets cancel in numerator and we get,

Now, in the numerator get reduced to 2and we get,

Therefore,

Page No 5.43:

Question 18:

Evaluate each of the following

sin 30°sin 45°+tan 45°sec 60°-sin 60°cot 45°-cos 30°sin 90°

Answer:

We have,

…… (1)

Now,

,, ,, ,

So by substituting above values in equation (1)

We get,

Now by further simplifying

We get,

Since,

Therefore,

Now, one gets cancelled and

We get,

Now, by taking LCM

We get,

Therefore,

Page No 5.43:

Question 19:

Evaluate each of the following

tan 45°cosec 30°+sec 60°cot 45°-5 sin 90°2 cos 0°

Answer:

We have,

…… (1)

Now,

,,

So by substituting above values in equation (1)

We get,

Now by taking terms with denominator 2 together and solving

We get,

Now gets reduced to -2

Therefore,

Therefore,

Page No 5.43:

Question 20:

Find the value of x in each of the following :

2 sin 3x=3

Answer:

We have,

Since,

Therefore,

Therefore,

Page No 5.43:

Question 21:

Find the value of x in each of the following :

2 sin x2=1

Answer:

We have,

Since,

Therefore,

Therefore,

Page No 5.43:

Question 22:

Find the value of x in each of the following :

3 sin x=cos x

Answer:

We have,

Now by cross multiplying we get,

…… (1)

Now we know that

…… (2)

Therefore from equation (1) and (2)

We get,

…… (3)

Since,

…… (4)

Therefore, by comparing equation (3) and (4) we get,

Therefore,

Page No 5.43:

Question 23:

Find the value of x in each of the following :

tan x = sin 45° cos 45° + sin 30°

Answer:

We have,

…… (1)

Now we know that

and

Now by substituting above values in equation (1), we get,

Therefore,

…… (2)

Since,

…… (3)

Therefore by comparing equation (2) and (3)

We get,

Therefore,

Page No 5.43:

Question 24:

Find the value of x in each of the following :

3 tan 2x=cos 60°+sin 45° cos 45°

Answer:

We have,

…… (1)

Now we know that

and

Now by substituting above values in equation (1), we get,

Therefore,

…… (2)

Since,

…… (3)

Therefore by comparing equation (2) and (3)

We get,

Therefore,

Page No 5.43:

Question 25:

Find the value of x in each of the following :

cos 2x = cos 60° cos 30° + sin 60° sin 30°

Answer:

We have,

…… (1)

Now we know that

and

Now by substituting above values in equation (1), we get,

Therefore,

Now gets reduced to

Therefore,

…… (2)

Since,

…… (3)

Therefore by comparing equation (2) and (3)

We get,

Therefore,

Page No 5.43:

Question 26:

If θ = 30°, verify that

(i) tan 2θ=2 tan θ1-tan2 θ
(ii) sin 2θ=2 tan θ1+tan2 θ
(iii) cos2 θ=1-tan2 θ1+tan2 θ
(iv) cos 3θ = 4 cos3 θ − 3 cos θ

Answer:

(i) Given:

…… (1)

To verify:

…… (2)

Now consider LHS of the expression to be verified in equation (2)

Therefore,

Now by substituting the value of from equation (1) in the above expression

We get,

Now by substituting the value of from equation (1) in the expression

We get,

…… (4)

Now by comparing equation (3) and (4)

We get,

Hence

(ii) Given:

…… (1)

To verify:

…… (2)

Now consider right hand side

Hence it is verified that,

(iii) Given:

…… (1)

To verify:

…… (2)

Now consider left hand side of the equation (2)

Therefore,

Now consider right hand side of equation (2)

Therefore,

Hence it is verified that,

(iv) Given:

…… (1)

To verify:

…… (2)

Now consider left hand side of the expression in equation (2)

Therefore

Now consider right hand side of the expression to be verified in equation (2)

Therefore,

Hence it is verified that,

Page No 5.43:

Question 27:

If A = B = 60°, verify that

(i) cos (A − B) = cos A cos B + sin A sin B
(ii) sin (A − B) = sin A cos B − cos A sin B
(iii) tan A-B=tan A-tan B1+tan A tan B

Answer:

(i) Given:

…… (1)

To verify:

…… (2)

Now consider left hand side of the expression to be verified in equation (2)

Therefore,

Now consider right hand side of the expression to be verified in equation (2)

Therefore,

Hence it is verified that,

(ii) Given:

…… (1)

To verify:

…… (2)

Now consider LHS of the expression to be verified in equation (2)

Therefore,

Now by substituting the value of A and B from equation (1) in the above expression

We get,

Hence it is verified that,

(iii) Given:

…… (1)

To verify:

…… (2)

Now consider LHS of the expression to be verified in equation (2)

Therefore,

Now consider RHS of the expression to be verified in equation (2)

Therefore,

Now by substituting the value of A and B from equation (1) in the above expression

We get,

Hence it is verified that,

Page No 5.43:

Question 28:

If A = 30° and B = 60°, verify that

(i) sin (A + B) = sin A cos B + cos A sin B
(ii) cos (A + B) = cos A cos B − sin A sin B

Answer:

(i) Given

and …… (1)

To verify:

…… (2)

Now consider LHS of the expression to be verified in equation (2)

Therefore,

Now consider RHS of the expression to be verified in equation (2)

Therefore;
sinAcosB+cosAsinB=sin30°cos60°+cos30°sin60°=12×12+32×32=1+34=1

Hence it is verified that,

(ii) Given:

and …… (1)

To verify:

…… (2)

Now consider LHS of the expression to be verified in equation (2)

Therefore,

Now consider RHS of the expression to be verified in equation (2)

Therefore,

Hence it is verified that,

Page No 5.43:

Question 29:

If sin (AB) = sin A cos B − cos A sin B and cos (AB) = cos A cos B + sin A sin B, find the values of sin 15° and cos 15°.

Answer:

Given:

…… (1)

…… (2)

To find:

The values of and

In this problem we need to find and

Hence to get angle we need to choose the value of A and B such that

So If we choose and

Then we get,

Therefore by substituting and in equation (1)

We get,

Therefore,

…… (3)

Now we know that,

, ,

Now by substituting above values in equation (3)

We get,

Therefore,

…… (4)

Now by substituting and in equation (2)

We get,

Therefore,

…… (5)

Now we know that,

, ,

Now by substituting above values in equation (5)

We get,

Therefore,

…… (6)

Therefore from equation (4) and (6)

Page No 5.43:

Question 30:

In a right triangle ABC, right angled at C, if ∠B = 60° and AB = 15 units. Find the remaining angles and sides.

Answer:

We are given the following triangle with related information

It is required to find , and length of sides AC and BC

is right angled at C

Therefore,

Now we know that sum of all the angles of any triangle is

Therefore,

…… (1)

Now by substituting the values of known angles and in equation (1)

We get,

Therefore,

Therefore,

Now,

We know that,

Now we have,

AB=15 units and

Therefore by substituting above values in equation (2)

We get,

Now by cross multiplying we get,

Therefore,

…… (3)

Now,

We know that,

Now we have,

AB=15 units and

Therefore by substituting above values in equation (4)

We get,

Now by cross multiplying we get,

Therefore,

Hence,



Page No 5.44:

Question 31:

If ∆ABC is a right triangle such that ∠C = 90°, ∠A = 45° and BC = 7 units. Find ∠B, AB and AC.

Answer:

We are given the following information in the form of the triangle

It is required to find and length of sides AB and AC

In

Now we know that sum of all the angles of any triangle is

Therefore,

…… (1)

Now by substituting the values of known angles and in equation (1)

We get,

Therefore,

Therefore,

…… (2)

Now,

We know that,

Now we have,

BC = 7 units and

Therefore by substituting above values in equation (3)

We get,

Now by cross multiplying we get,

Therefore,

…… (4)

Now,

We know that,

……(5)

Now we have,

and

Therefore by substituting above values in equation (5)

We get,

Now by cross multiplying we get,

Therefore,

…… (6)

Therefore,

From equation (2), (4) and (6)

, ,

Page No 5.44:

Question 32:

In a rectangle ABCD, AB = 20 cm, ∠BAC = 60°, calculate side BC and diagonals AC and BD.

Answer:

We have drawn the following figure

Since ABCD is a rectangle

Therefore,

Now, consider

We know that sum of all the angles of any triangle is

Therefore,

…… (1)

Now by substituting the values of known angles and in equation (1)

We get,

Now in

We know that,

Now we have,

AB = 20cm and

Therefore by substituting above values in equation (2)

We get,

Now by cross multiplying we get,

Therefore,

…… (3)

Now in

We know that,

Now we have from equation (3),

AC=40cm and

Therefore by substituting above values in equation (4)

We get,

Now by cross multiplying we get,

Therefore,

…… (5)

Since ABCD is a rectangle

Therefore,

…… (6)

And

…… (7)

Now in

We know that,

Now by substituting the values of sides from equation (6) and (7)

We get,

Since

Therefore,

That is in

…… (8)

Now in

We know that,

From equation (7)and (8)

Since

Therefore,

Now by cross multiplying we get,

Therefore,

…… (9)

Hence from equation (3), (5) and (9)

Page No 5.44:

Question 33:

If sin (A + B) = 1 and cos (A − B) = 1, 0° < A + B ≤ 90°, A ≥ B find A and B.

Answer:

Given:

…… (1)

…… (2)

We know that,

…… (3)

…… (4)

Now by comparing equation (1) and (3)

We get,

…… (5)

Now by comparing equation (2) and (4)

We get,

…… (6)

Now to get the values of A and B, let us solve equation (5) and (6) simultaneously

Therefore by adding equation (5) and (6)

We get,

Therefore,

Hence

Now by subtracting equation (6) from equation (5)

We get,

Therefore,

Hence

Therefore the values of A and B are as follows

and

Page No 5.44:

Question 34:

If tan A-B=13 and tan A+B=3, 0° < A+B90°, A>B find A and B.

Answer:

Given:

…… (1)

…… (2)

We know that,

…… (3)

…… (4)

Now by comparing equation (1) and (3)

We get,

…… (5)

Now by comparing equation (2) and (4)

We get,

…… (6)

Now to get the values of A and B, let us solve equation (5) and (6) simultaneously

Therefore by adding equation (5) and (6)

We get,

Therefore,

Hence

Now by subtracting equation (5) from equation (6)

We get,

Therefore,

Hence

Therefore the values of A and B are as follows

and

Page No 5.44:

Question 35:

If sin A-B=12 and cos A+B=12, 0° <A+B90°, A<B find A and B.

Answer:

Given:

…… (1)

…… (2)

We know that,

…… (3)

…… (4)

Now by comparing equation (1) and (3)

We get,

…… (5)

Now by comparing equation (2) and (4)

We get,

…… (6)

Now to get the values of A and B, let us solve equation (5) and (6) simultaneously

Therefore by adding equation (5) and (6)

We get,

Therefore,

Hence

Now by subtracting equation (5) from equation (6)

We get,

Therefore,

Hence

Therefore the values of A and B are as follows

and

Page No 5.44:

Question 36:

In a ∆ABC right angled at B, ∠A = ∠C. Find the values of

(i) sin A cos C + cos A sin C
(ii) sin A sin B + cos A cos B

Answer:

(i) We have drawn the following figure related to given information

To find:

…… (1)

Now we have,

,

,

Now by substituting the above values in equation (1)

We get,

Therefore,

…… (2)

Now in right angled

By applying Pythagoras theorem

We get,

Now, by substituting above value of AC2 in equation (2)

We get,

Now both numerator and denominator contains

Therefore it gets cancelled and 1 remains

Hence

(ii) We have drawn the following figure

e

To find:

…… (1)

Now we know that sum of all the angles of any triangle is 180°

Therefore,

Since and

Therefore,

It is given that

Therefore,

…… (2)

Now we have,

,

,

Now by substituting the above values in equation (1)

We get,

Since

Therefore

Page No 5.44:

Question 37:

Find acute angles A and B, if sin A+2B=32 and cos A+4B=0, A>B.

Answer:

Given:

…… (1)

…… (2)

We know that,

…… (3)

…… (4)

Now by comparing equation (1) and (3)

We get,

…… (5)

Now by comparing equation (2) and (4)

We get,

…… (6)

Now to get the values of A and B, let us solve equation (5) and (6) simultaneously

Therefore by subtracting equation (5) from (6)

We get,

Therefore,

Hence

Now by multiplying equation (5) by 2

We get,

…… (7)

Now by subtracting equation (6) from (7)

We get,

Therefore,

Hence

Therefore the values of A and B are as follows and

Page No 5.44:

Question 38:

If A and B are acute angles such that tan A=12, tan B=13 and tan A+B=tan A+tan B1-tan A tan B, find A + B.

Answer:

Given:

…… (1)

…… (2)

…… (3)

Now by substituting the value of and from equation (1) and (2) in equation (3)

We get,

Therefore,

…… (3)

Now we know that

…… (4)

Now by comparing equation (3) and (4)

We get,

Page No 5.44:

Question 39:

In ∆PQR, right-angled at Q, PQ = 3 cm and PR = 6 cm. Determine ∠P and ∠R.

Answer:

We are given the following information in the form of triangle

To find: and

Now, in

…… (1)

Now we know that

…… (2)

Now by comparing equation (1) and (2)

We get,

…… (3)

Now we have

Now we know that

Therefore,

Now by cross multiplying

We get,

Therefore,

cm …… (4)

Now we know that

Now we know,

…… (6)

Now by comparing equation (5) and (6)

We get,

…… (7)

Hence from equation (3) and (7)

and



Page No 5.53:

Question 1:

Evaluate the following :

(i) sin 20°cos 70°
(ii) cos 19°sin 71°
(iii) sin 21°cos 69°
(iv) tan 10°cot 80°
(v) sec 11°cosec 79°

Answer:

(i) Given that

Since

Therefore

(ii) Given that

Since

Therefore

(iii) Given that

Since

(iv) We are given that

Since

Therefore

(v) Given that

Since

Therefore

Page No 5.53:

Question 2:

Evaluate the following :

(i) sin 49°cos 41°2+cos 41°sin 49°2
(ii) cos 48° − sin 42°
(iii) cot 40°tan 50°-12 cos 35°sin 55°
(iv) sin 27°cos 63°2-cos 63°sin 27°2
(v) tan 35°cot 55°+cot 78°tan 12°-1
(vi) sec 70°cosec 20°+sin 59°cos 31°
(vii) cosec 31° − sec 59°
(viii) (sin 72° + cos 18°) (sin 72° − cos 18°)
(ix) sin 35° sin 55° − cos 35° cos 55°
(x) tan 48° tan 23° tan 42° tan 67°
(xi) sec50° sin 40° + cos40° cosec 50°

Answer:

(i) We have to find:

Since and

So

So value of is

(ii) We have to find:

Since .So

So value of is

(iii) We have to find:

Since and

So value of is

(iv) We have to find:

Since and

So value of is

(v) We have to find:

Since and

So value of is

(vi) We have to find:

Sinceand

So

So value of is

(vii) We have to find:

Since.So

So value of is

(viii) We have to find:

Since.So

So value of is

(ix) We find:

Sinceand

So value of is

(x) We have to find

Since.So

So value of is

(xi) We find to find

Since, and .So

So value of is



Page No 5.54:

Question 3:

Express each one of the following in terms of trigonometric ratios of angles lying between 0° and 45°

(i) sin 59° + cos 56°
(ii) tan 65° + cot 49°
(iii) sec 76° + cosec 52°
(iv) cos 78° + sec 78°
(v) cosec 54° + sin 72°
(vi) cot 85° + cos 75°
(vii) sin 67° + cos 75°

Answer:

(i) We have and.So

Thus the desired expression is

(ii) We knowand.So

Thus the desired expression is

(iii) We know thatand.So

Thus the desired expression is

(iv) We knowand

Thus the desired expression is

(v) We know and.So

Thus the desired expression is

(vi) We know thatand.So

Thus the desired expression is

(vii) We know thatand.So

Thus the desired expression is

Page No 5.54:

Question 4:

Express cos 75° + cot 75° in terms of angles between 0° and 30°.

Answer:

Given that:

Hence the correct answer is

Page No 5.54:

Question 5:

If sin 3A = cos (A − 26°), where 3A is an acute angles, find the value of A.

Answer:

We are given 3A is an acute angle

We have:

Hence the correct answer is

Page No 5.54:

Question 6:

If A, B, C are the interior angles of a triangle ABC, prove that

(i) tan C+A2=cot B2
(ii) sin B+C2=cos A2

Answer:

(i) We have to prove:

Since we know that in triangle

Proved

 

(ii) We have to prove:

Since we know that in triangle

Proved

Page No 5.54:

Question 7:

Prove that :

(i) tan 20° tan 35° tan 45° tan 55° tan 70° = 1
(ii) sin 48° sec 42° + cos 48° cosec 42° = 2
(iii) sin 70°cos 20°+cosec 20°sec 70°-2 cos 70° cosec 20°=0
(iv) cos 80°sin 10°+cos 59° cosec 31°=2

Answer:

We are asked to find the value of

(i) Therefore

Proved

(ii) We will simplify the left hand side

Proved

(iii) We have,

So we will calculate left hand side

Proved

(iv) We have

We will simplify the left hand side

Proved

Page No 5.54:

Question 8:

Prove the following :

(i) sin θ sin (90° − θ) − cos θ cos (90° − θ) = 0
(ii) cos 90°-θ sec 90°-θ tan θcosec 90°-θ sin 90°-θ cot 90°-θ+tan 90°-θcot θ=2
(iii) tan 90°-A cot Acosec2 A-cos2 A=0
(iv) cos 90°-A sin 90°-Atan 90°-A=sin2 A
(v) sin (50° − θ) − cos (40° − θ) + tan 1° tan 10° tan 20° tan 70° tan 80° tan 89° = 1

Answer:

(i) We have to prove:

Left hand side

=Right hand side

Proved

(ii) We have to prove:

Left hand side

= right hand side

Proved

(iii) We have to prove:

Left hand side

= right hand side

Proved

(iv) We have to prove:

Left hand side

= Right hand side

Proved

(v) We have to prove:

Left hand side

Since .So

=Right hand side

Proved

Page No 5.54:

Question 9:

Evaluate :

(i) 23 cos4 30-sin4 45°-3sin2 60°-sec2 45°+14cot2 30°
(ii) 4sin4 30°+cos4 60°-23sin2 60°-cos2 45°+12 tan2 60°
(iii) sin 50°cos 40°+cosec 40°sec 50°-4 cos 50° cosec 40°
(iv) tan 35° tan 40° tan 45° tan 50° tan 55°
(v) cosec (65° + θ) − sec (25° − θ) − tan (55° − θ) + cot (35° + θ)
(vi) tan 7° tan 23° tan 60° tan 67° tan 83°
(vii) 2 sin 68°cos 22°-2 cot 15°5 tan 75°-3 tan 45° tan 20° tan 40° tan 50° tan 70°5
(viii) 3 cos 55°7 sin 35°-4cos 70° cosec 20°7tan 5° tan 25° tan 45° tan 65° tan 85°
(ix) sin 18°cos 72°+3 tan 10° tan 30° tan 40° tan 50° tan 80°
(x) cos 58°sin 32°+sin 22°cos 68°-cos 38° cosec 52°tan 18° tan 35° tan 60° tan 72° tan 55°

Answer:

We have to evaluate the following values-

(i) We will use the values of known angles of different trigonometric ratios.

(ii) We will use the values of known angles of different trigonometric ratios.

(iii) We will use the properties of complementary angles.

(iv) We will use the properties of complementary angles.

(v) We will use the properties of complementary angles.

(vi) We will use the properties of complementary angles.

(vii) We will use the properties of complementary angles.

(viii) We will use the properties of complementary angles.

(ix) We will use the properties of complementary angles.

(x) We will use the properties of complementary angles.



Page No 5.55:

Question 10:

If sin θ = cos (θ − 45°), where θ and θ − 45° are acute angles, find the degree measure of θ.

Answer:

Given that: where and are acute angles

We have to find

Therefore

Page No 5.55:

Question 11:

If A, B, C are the interior angles of a ∆ABC, show that :

(i) sin B+C2=cos A2
(ii) cos B+C2=sin A2

Answer:

(i) We have to prove:

Since we know that in triangle

Dividing by 2 on both sides, we get

Proved

(ii) We have to prove:

Since we know that in triangle

Dividing by 2 on both sides, we get

Proved

Page No 5.55:

Question 12:

If 2θ + 45° and 30° − θ are acute angles, find the degree measure of θ satisfying sin (2θ + 45°) = cos (30° − θ).

Answer:

Given that: where and are acute angles

We have to find

So we have

Hence the value of is

Page No 5.55:

Question 13:

If θ is a positive acute such that sec θ = cosec 60°, find the value of 2 cos2 θ − 1.

Answer:

We have: where is positive acute angle

Now we have to find

Put

Hence the value of is

Page No 5.55:

Question 14:

If cos 2θ = sin 4θ, where 2θ and 4θ are acute angles, find the value of θ.

Answer:

We have:

Given in question and are acute angles. We have to find

Now we have

Page No 5.55:

Question 15:

If sin 3 θ = cos (θ − 6°), where 3 θ and θ − 6° are acute angles, find the value of θ.

Answer:

We have: where and are acute angles

We have to find

Now we proceed as to find

Therefore 

Page No 5.55:

Question 16:

If sec 4A = cosec (A − 20°), where 4A is an acute angles, find the value of A.

Answer:

Given: and is an acute angle

We have to find

Now

Hence the value of is

Page No 5.55:

Question 17:

If sec 2A = cosec (A − 42°), where 2A is an acute angles, find the value of A.

Answer:

Given: and is an acute angle

We have to find

So we proceed as follows to calculate

Hence the value of is



Page No 5.56:

Question 1:

Write the maximum and minimum values of sin θ.

Answer:

The maximum value of is and the minimum value of is because value of lies between −1 and 1

 

Page No 5.56:

Question 2:

Write the maximum and minimum values of cos θ.

Answer:

The maximum value of is and the minimum value of is because value of lies between −1 and 1

 

Page No 5.56:

Question 3:

What is the maximum value of 1sec θ?

Answer:

The maximum value of is because the maximum value of is that is

 

Page No 5.56:

Question 4:

What is the maximum value of 1cosec θ?

Answer:

The maximum value of is because the maximum value of is that is

 

Page No 5.56:

Question 5:

If tan θ=45, find the value of cos θ-sin θcos θ+sin θ.

Answer:

 

It is given that .

We have to find .

 

 

Page No 5.56:

Question 6:

If cos θ=23, find the value of sec θ-1sec θ+1.

Answer:

Given in question:

We have to find

Hence the value of is

 

Page No 5.56:

Question 7:

If 3 cot θ = 4, find the value of 4 cos θ-sin θ2 cos θ+sin θ.

Answer:

We have:

Since we know that in right angle triangle

Now, we find

Hence the value of is

 

Page No 5.56:

Question 8:

Given tan θ=15, what is the value of cosec2 θ-sec2 θcosec2 θ+sec2 θ?

Answer:

Given: ,

We know that:

Now we find,

Hence the value of is

 

Page No 5.56:

Question 9:

If cot θ=13, write the value of 1-cos2 θ2-sin2 θ.

Answer:

Given:

Now we find,

Hence the value of is

 

Page No 5.56:

Question 10:

If tan A=34 and A+B=90°, then what is the value of cot B?

Answer:

Given that:

Hence the value of is

 

Page No 5.56:

Question 11:

If A + B = 90° and cos B=35, what is the value of sin A?

Answer:

We have:

Hence the value of is

 

Page No 5.56:

Question 12:

Write the acute angle θ satisfying 3 sin θ=cos θ.

Answer:

We have:

Hence the acute angle is

 

 

Page No 5.56:

Question 13:

Write the value of cos 1° cos 2° cos 3° ....... cos 179° cos 180°.

Answer:

Given that:

Hence the value of is

 



Page No 5.57:

Question 14:

Write the value of tan 10° tan 15° tan 75° tan 80°?

Answer:

We have to find:

Hence the value of is

 

 

Page No 5.57:

Question 15:

If A + B = 90° and tan A=34, what is cot B?

Answer:

Given in question:

Hence the value of is

 

Page No 5.57:

Question 16:

If tan A=512, find the value of (sin A + cos A) sec A.

Answer:

Given:

We know that:

Now we find,

Hence the value of is

 

Page No 5.57:

Question 1:

If θ is an acute angle such that cos θ=35, then sin θ tan θ-12 tan2 θ=

(a) 16625
(b) 136
(c) 3160
(d) 1603

Answer:

Given: and we need to find the value of the following expression

We know that:

So we find,

Hence the correct option is

 

Page No 5.57:

Question 2:

If tan θ=ab, then a sin θ+b cos θa sin θ-b cos θis equal to

(a) a2+b2a2-b2
(b) a2-b2a2+b2
(c) a+ba-b
(s) a-ba+b

Answer:

Given:

We have to find the value of following expression in terms of a and b

We know that:

Now we find,

Hence the correct option is

 

Page No 5.57:

Question 3:

If 5 tan θ − 4 = 0, then the value of 5 sin θ-4 cos θ5 sin θ+4 cos θ is

(a) 53
(b) 56
(c) 0
(d) 16

Answer:

Given that:.We have to find the value of the following expression

Since

We know that:

Since and

Now we find

Hence the correct option is

 

Page No 5.57:

Question 4:

If 16 cot x = 12, then sin x-cos xsin x+cos x equals

(a) 17
(b) 37
(c) 27
(d) 0

Answer:

We are given .We are asked to find the following

We know that:

Now we have

,

We knowand

Now we find

Hence the correct option is

 

Page No 5.57:

Question 5:

If 8 tan x = 15, then sin x − cos x is equal to

(a) 817
(b) 177
(c) 117
(d) 717

Answer:

Given that:

We know that and

We find:

Hence the correct option is

 

Page No 5.57:

Question 6:

If tan θ=17, then cosec2 θ-sec2 θcosec2 θ+sec2 θ=

(a) 57
(b) 37
(c) 112
(d) 34

Answer:

Given that:

We are asked to find the value of the following expression

Since

We know that and

We find:

Hence the correct option is

 

Page No 5.57:

Question 7:

If tan θ=34, then cos2 θ − sin2 θ =

(a) 725
(b) 1
(c) -725
(d) 425

Answer:

Given that:

Since

We know that and

We find:

Hence the correct option is

 



Page No 5.58:

Question 8:

If θ is an acute angle such that tan2 θ=87, then the value of 1+sin θ 1-sin θ 1+cos θ 1-cos θis

(a) 78
(b) 87
(c) 74
(d) 6449

Answer:

Given that: andis an acute angle

We have to find the following expression

Since

 

Since

We know thatand

We find:

Hence the correct option is

 

Page No 5.58:

Question 9:

If 3 cos θ = 5 sin θ, then the value of 5 sin θ-2 sec3 θ+2 cos θ5 sin θ+2 sec3 θ-2 cos θis

(a) 271979
(b) 3162937
(c) 5422937
(d) None of these

Answer:

We have,

So we can manipulate it as,

So now we can get the values of other trigonometric ratios,

So now we will put these values in the equation,

So the answer is (a).

 

Page No 5.58:

Question 10:

If tan2 45° − cos2 30° = x sin 45° cos 45°, then x =

(a) 2
(b) −2
(c) -12
(d) 12

Answer:

We are given:

We have to find x

We know that

Hence the correct option is

 

Page No 5.58:

Question 11:

The value of cos2 17° − sin2 73° is

(a) 1
(b) 13
(c) 0
(d) −1

Answer:

We have:

Hence the correct option is

 

Page No 5.58:

Question 12:

The value of cos3 20°-cos3 70°sin3 70°-sin3 20°is

(a) 12
(b) 12
(c) 1
(d) 2

Answer:

We have to evaluate the value. The formula to be used,

So,

Now using the properties of complementary angles,

So the answer is

 

Page No 5.58:

Question 13:

If x cosec2 30° sec2 45°8 cos2 45° sin2 60°=tan2 60°-tan2 30°, then x =

(a) 1
(b) −1
(c) 2
(d) 0

Answer:

We have:

Here we have to find the value of

As we know that

So

Hence the correct option is

 

Page No 5.58:

Question 14:

If A and B are complementary angles, then

(a) sin A = sin B
(b) cos A = cos B
(c) tan A = tan B
(d) sec A = cosec B

Answer:

Given: and are are complementary angles

Since

Hence the correct option is

 

Page No 5.58:

Question 15:

If x sin (90° − θ) cot (90° − θ) = cos (90° − θ), then x =

(a) 0
(b) 1
(c) −1
(d) 2

Answer:

We have:

Here we have to find the value of

We know that

Hence the correct option is

 

 

Page No 5.58:

Question 16:

If x tan 45° cos 60° = sin 60° cot 60°, then x is equal to

(a) 1
(b) 3
(c) 12
(d) 12

Answer:

Given that:

Here we have to find the value of

We know that

Hence the correct option is

 

Page No 5.58:

Question 17:

If angles A, B, C to a ∆ABC from an increasing AP, then sin B =

(a) 12
(b) 32
(c) 1
(d) 12

Answer:

Let the angles of a triangleberespectively which constitute an A.P.As we know that sum of all the three angles of a triangle is. So,

So,

Therefore,

Hence,

So answer is

 

Page No 5.58:

Question 18:

If θ is an acute angle such that sec2 θ = 3, then the value of tan2 θ-cosec2 θtan2 θ+cosec2 θis

(a) 47
(b) 37
(c) 27
(d) 17

Answer:

Given that:

We need to find the value of the expression

.So

Here we have to find:

Hence the correct option is

 

Page No 5.58:

Question 19:

The value of tan 1° tan 2° tan 3° ...... tan 89° is

(a) 1
(b) −1
(c) 0
(d) None of these

Answer:

Here we have to find:

Hence the correct option is

 

Page No 5.58:

Question 20:

The value of cos 1° cos 2° cos 3° ..... cos 180° is

(a) 1
(b) 0
(c) −1
(d) None of these

Answer:

Here we have to find:

Hence the correct option is

 



Page No 5.59:

Question 21:

The value of tan 10° tan 15° tan 75° tan 80° is

(a) −1
(b) 0
(c) 1
(d) None of these

Answer:

Here we have to find:

Now

Hence the correct option is

 

Page No 5.59:

Question 22:

The value of cos 90°-θ sec 90°-θ tan θcosec 90°-θ sin 90°-θ cot 90°-θ+tan 90°-θcot θ is

(a) 1
(b) − 1
(c) 2
(d) −2

Answer:

We have to find:

So

Hence the correct option is

 

Page No 5.59:

Question 23:

If θ and 2θ − 45° are acute angles such that sin θ = cos (2θ − 45°), then tan θ is equal to

(a) 1
(b) −1
(c) 3
(d) 13

Answer:

Given that: and are acute angles

We have to find

Where and are acute angles

Since

Now

Put

Hence the correct option is

 

Page No 5.59:

Question 24:

If 5θ and 4θ are acute angles satisfying sin 5θ = cos 4θ, then 2 sin 3θ − 3 tan 3θ is equal to

(a) 1
(b) 0
(c) −1
(d) 1+3

Answer:

We are given that and are acute angles satisfying the following condition

.We are asked to find

Where and are acute angles

Now we have to find:

Hence the correct option is

 

Page No 5.59:

Question 25:

If A + B = 90°, then tan A tan B+tan A cot Bsin A sec B-sin2 Bcos2 A is equal to

(a) cot2 A
(b) cot2 B
(c) −tan2 A
(d) −cot2 A

Answer:

We have:

We have to find the value of the following expression

So

Hence the correct option is

 

Page No 5.59:

Question 26:

2 tan 30°1+tan2 30° is equal to

(a) sin 60°
(b) cos 60°
(c) tan 60°
(d) sin 30°

Answer:

We have to find the value of the following expression

Hence the correct option is

 

Page No 5.59:

Question 27:

1-tan2 45°1+tan2 45° is equal to

(a) tan 90°
(b) 1
(c) sin 45°
(d) sin 0°

Answer:

We have to find the value of the following

So

We know that

Hence the correct option is

 

Page No 5.59:

Question 28:

Sin 2A = 2 sin A is true when A =

(a) 0°
(b) 30°
(c) 45°
(d) 60°

Answer:

We are given

So

Hence the correct option is

 

Page No 5.59:

Question 29:

2 tan 30°1-tan2 30° is equal to

(a) cos 60°
(b) sin 60°
(c) tan 60°
(d) sin 30°

Answer:

We are asked to find the value of the following

We know that

Hence the correct option is

 

Page No 5.59:

Question 30:

If A, B and C are interior angles of a triangle ABC, then sin B+C2=

(a) sin A2
(b) cos A2
(c) -sin A2
(d) -cos A2

Answer:

We know that in triangle

So

Hence the correct option is

 

Page No 5.59:

Question 31:

If cos θ=23, then 2 sec2 θ + 2 tan2 θ − 7 is equal to

(a) 1
(b) 0
(c) 3
(d) 4

Answer:

Given that:

We have to find

As we are given

We know that:

Now we have to find: .So

Hence the correct option is

 

Page No 5.59:

Question 32:

tan 5° ✕ tan 30° ✕ 4 tan 85° is equal to

(a) 43
(b) 43
(c) 1
(d) 4

Answer:

We have to find

We know that

So

Hence the correct option is

 

Page No 5.59:

Question 33:

The value of tan 55°cot 35°+ cot 1° cot 2° cot 3° .... cot 90°, is

(a) −2
(b) 2
(c) 1
(d) 0

Answer:

We have to find the value of the following expression

Hence the correct option is

 



Page No 5.60:

Question 34:

In Fig. 5.47, the value of cos Ï• is



(a) 54
(b) 53
(c) 35
(d) 45

Answer:

We should proceed with the fact that sum of angles on one side of a straight line is.

So from the given figure,

So, …… (1)

Now from the triangle,

Now we will use equation (1) in the above,

Therefore,

So the answer is

 

Page No 5.60:

Question 35:

In Fig. 5.48, AD = 4 cm, BD = 3 cm and CB = 12 cm, find the cot θ.



(a) 125
(b) 512
(c) 1312
(d) 1213

Answer:

We have the following given data in the figure,

Now we will use Pythagoras theorem in,

Therefore,

So the answer is

 



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