Binomial Theorem

To find: Expansion of (1 – 2x)⁵

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (1 – 2x)⁵

⇒ [ ⁵C₀(1)⁵] + [⁵C₁(1)^5-1(-2x)¹] + [⁵C₂(1)^5-2(-2x)²] + [⁵C₃(1)^5-3(-2x)³]+ [⁵C₄(1)^5-4(-2x)⁴] + [⁵C₅(-2x)⁵]

⇒ 1 – 5(2x) + 10(4x²) – 10(8x³) + 5(16x⁴) – 1(32x⁵)

⇒ 1 – 10x + 40x² – 80x³ + 80x⁴ – 32x⁵

On rearranging

Ans) –32x⁵ + 80x⁴ – 80x³ + 40x² – 10x + 1

To find: Expansion of (2x – 3)⁶

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (2x – 3)⁶

⇒  [⁶C₀(2x)⁶]+[⁶C₁(2x)^6-1(-3)¹]+[⁶C₂(2x)^6-2(-3)²]+[⁶C₃(2x)^6-3(-3)³]+ [⁶C₄(2x)^6-4(-3)⁴] + [⁶C₅(2x)^6-5(-3)⁵] + [⁶C₆(-3)⁶]

⇒ [(1) (64x⁶)] – [(6)(32x⁵)(3)] + [15(16x⁴)(9)] – [20(8x³)(27)] + [15(4x²)(81)] – [(6)(2x)(243)] + [(1)(729)]

⇒ 64x⁶ – 576x⁵ + 2160x⁴ – 4320x³ + 4860x² – 2916x + 729

Ans) 64x⁶ – 576x⁵ + 2160x⁴ – 4320x³ + 4860x² – 2916x + 729

To find: Expansion of (3x + 2y)⁵

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (3x + 2y)⁵

⇒  [⁵C₀(3x)^5-0] + [⁵C₁(3x)^5-1(2y)¹] + [⁵C₂(3x)^5-2(2y)²] + [⁵C₃(3x)^5-3(2y)³]+ [⁵C₄(3x)^5-4(2y)⁴] + [⁵C₅(2y)⁵]

⇒ [1(243x⁵)] + [5(81x⁴)(2y)] + [10(27x³)(4y²)] + [10(9x²)(8y³)] + [5(3x)(16y⁴)] + [1(32y⁵)]

⇒ 243x⁵ + 810x⁴y + 1080x³y² + 720x²y³ + 240xy⁴ + 32y⁵

Ans) 243x⁵ + 810x⁴y + 1080x³y² + 720x²y³ + 240xy⁴ + 32y⁵

To find: Expansion of (2x – 3y)⁴

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (2x – 3y)⁴

⇒  [⁴C₀(2x)^4-0] + [⁴C₁(2x)^4-1(-3y)¹] + [⁴C₂(2x)^4-2(-3y)²] + [⁴C₃(2x)^4-3(-3y)³]+ [⁴C₄(-3y)⁴]

⇒ [1(16x⁴)] – [4(8x³)(3y)] + [6(4x²)(9y²)] – [4(2x)(27y³)] + [1(81y⁴)]

⇒ 16x⁴ – 96x³y + 216x²y² – 216xy³ + 81y⁴

Ans) 16x⁴ – 96x³y + 216x²y² – 216xy³ + 81y⁴

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,  

Ans)

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,

Ans)

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,

⇒  ⁵C₀(x)^5-0 + ⁵C₁(x)^5-1 + ⁵C₂(x)^5-2 + ⁵C₃(x)^5-3+ ⁵C₄(x)^5-4+ ⁵C₅

⇒

Ans)

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,

We can write as and as

Now, we have to solve for

Ans) + 8 + 28 + 56 + 70+ 56+ 28(x)¹(y)³ + 8 + (y)⁴

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,

We can write as and as

Now, we have to solve for

Ans)

To find: Expansion of (1 + 2x – 3x²)⁴

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (1 + 2x – 3x²)⁴

Let (1+2x) = a and (-3x²) = b … (i)

Now the equation becomes (a + b)⁴

⇒ [ ⁴C₀(a)^4-0] + [⁴C₁(a)^4-1(b)¹] + [⁴C₂(a)^4-2(b)²] + [⁴C₃(a)^4-3(b)³]+ [⁴C₄(b)⁴]

⇒ [⁴C₀(a)⁴] + [⁴C₁(a)³(b)¹] + [⁴C₂(a)²(b)²] + [⁴C₃(a)(b)³]+ [⁴C₄(b)⁴]

(Substituting value of b from eqn. i )

(Substituting value of b from eqn. i )

… (ii)

We need the value of a⁴,a³ and a², where a = (1+2x)

For (1+2x)⁴, Applying Binomial theorem

(1+2x)⁴⇒  

⇒ 1 + 8x + 24x² + 32x³ + 16x⁴

We have (1+2x)⁴ = 1 + 8x + 24x² + 32x³ + 16x⁴ … (iii)

For (a+b)³ , we have formula a³+b³+3a²b+3ab²

For, (1+2x)³ , substituting a = 1 and b = 2x in the above formula

⇒ 1³+ (2x) ³+3(1)²(2x) +3(1) (2x) ²

⇒ 1 + 8x³ + 6x + 12x²

⇒ 8x³ + 12x² + 6x + 1 … (iv)

For (a+b)² , we have formula a²+2ab+b²

For, (1+2x)² , substituting a = 1 and b = 2x in the above formula

⇒ (1)² + 2(1)(2x) + (2x)²

⇒ 1 + 4x + 4x²

⇒ 4x² + 4x + 1 … (v)

Putting the value obtained from eqn. (iii),(iv) and (v) in eqn. (ii)

⇒ 1 + 8x + 24x² + 32x³ + 16x⁴ - 96x⁵ - 144x⁴ - 72x³ - 12x² + 216x⁶ + 216x⁵ + 54x⁴ -108x⁶ - 216x⁷ + 81x⁸

On rearranging

Ans) 81x⁸ - 216x⁷ + 108x⁶ + 120x⁵ - 74x⁴ - 40x³ + 12x² +8x+ 1

To find: Expansion of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have,

Let = a and = b … (i)

Now the equation becomes (a + b)⁴

(Substituting value of b from eqn. i )

(Substituting value of a from eqn. i )

…(ii)

We need the value of a⁴,a³ and a², where a =

For , Applying Binomial theorem

=

On rearranging the above eqn.

We have, = + x³ + x² + 2x + 1

For, (a+b)³ , we have formula a³+b³+3a²b+3ab²

For, , substituting a = 1 and b = in the above formula

For, (a+b)² , we have formula a²+2ab+b²

For, , substituting a = 1 and b = in the above formula

… (v)

Putting the value obtained from eqn. (iii),(iv) and (v) in eqn. (ii)

On rearranging

Ans) + + - +

To find: Expansion of (3x² – 2ax + 3a²)³

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

We have, (3x² – 2ax + 3a²)³

Let, (3x² – 2ax) = p … (i)

The equation becomes (p + 3a²)³

Substituting the value of p from eqn. (i)

… (ii)

We need the value of p³ and p², where p = 3x² – 2ax

For, (a+b)³ , we have formula a³+b³+3a²b+3ab²

For, (3x² – 2ax)³ , substituting a = 3x² and b = –2ax in the above formula

⇒ 27x⁶ – 8a³x³ – 54ax⁵ + 36a²x⁴ … (iii)

For, (a+b)² , we have formula a²+2ab+b²

For, (3x² – 2ax)³ , substituting a = 3x² and b = –2ax in the above formula

⇒ 9x⁴ – 12x³a + 4a²x² … (iv)

Putting the value obtained from eqn. (iii) and (iv) in eqn. (ii)

⇒ 27x⁶ – 8a³x³ – 54ax⁵ + 36a²x⁴ + 81a²x⁴ – 108x³a³ + 36a⁴x² + 81a⁴x² – 54a⁵x + 27a⁶

On rearranging

Ans) 27x⁶ – 54ax⁵ + 117a²x⁴ – 116x³a³ + 117a⁴x² – 54a⁵x + 27a⁶

To find: Value of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(a+1)⁶ =

⇒ ⁶C₀a⁶ + ⁶C₁a⁵ + ⁶C₂a⁴ + ⁶C₃a³ + ⁶C₄a² + ⁶C₅a + ⁶C₆ … (i)

(a-1)⁶ =

⇒ ⁶C₀a⁶ - ⁶C₁a⁵ + ⁶C₂a⁴ - ⁶C₃a³ + ⁶C₄a² - ⁶C₅a + ⁶C₆ … (ii)

Adding eqn. (i) and (ii)

(a+1)⁶ + (a-1)⁶ = [⁶C₀a⁶ + ⁶C₁a⁵ + ⁶C₂a⁴ + ⁶C₃a³ + ⁶C₄a² + ⁶C₅a + ⁶C₆] + [⁶C₀a⁶ - ⁶C₁a⁵ + ⁶C₂a⁴ - ⁶C₃a³ + ⁶C₄a² - ⁶C₅a + ⁶C₆]

⇒ 2[⁶C₀a⁶ + ⁶C₂a⁴ + ⁶C₄a² + ⁶C₆]

⇒ 2

⇒ 2[(1)a⁶ + (15)a⁴ + (15)a² + (1)]

⇒ 2[a⁶ + 15a⁴ + 15a² + 1] = (a+1)⁶ + (a-1)⁶

Putting the value of a = in the above equation

= 2[⁶ + 15⁴ + 15² + 1]

⇒ 2[8 + 15(4) + 15(2) + 1]

⇒ 2[8 + 60 + 30 + 1]

⇒ 2[99]

⇒ 198

Ans) 198

To find: Value of

Formula used: (I)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(a+1)⁵ = ⁵C₀a⁵ + ⁵C₁a^5-11 + ⁵C₂a^5-21² + ⁵C₃a^5-31³ + ⁵C₄a^5-41⁴ + ⁵C₅1⁵

⇒ ⁵C₀a⁵ + ⁵C₁a⁴ + ⁵C₂a³ + ⁵C₃a² + ⁵C₄a + ⁵C₅… (i)

(a-1)⁵

⇒ ⁵C₀a⁵ - ⁵C₁a⁴ + ⁵C₂a³ - ⁵C₃a² + ⁵C₄a - ⁵C₅ … (ii)

Substracting (ii) from (i)

(a+1)⁵ - (a-1)⁵ = [⁵C₀a⁵ + ⁵C₁a⁴ + ⁵C₂a³ + ⁵C₃a² + ⁵C₄a + ⁵C₅] - [⁵C₀a⁵ - ⁵C₁a⁴ + ⁵C₂a³ - ⁵C₃a² + ⁵C₄a - ⁵C₅]

⇒ 2[⁵C₁a⁴ + ⁵C₃a² + ⁵C₅]

⇒ 2

⇒ 2[(5)a⁴ + (10)a² + (1)]

⇒ 2[5a⁴ + 10a² + 1] = (a+1)⁵ - (a-1)⁵

Putting the value of a = in the above equation

= 2[5⁴ + 10² + 1]

⇒ 2[(5)(9) + (10)(3) + 1]

⇒ 2[45+30+1]

⇒ 152

Ans) 152

To find: Value of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(a+b)⁷ =

⇒ ⁷C₀a⁷ + ⁷C₁a⁶b + ⁷C₂a⁵b² + ⁷C₃a⁴b³ + ⁷C₄a³b⁴ + ⁷C₅a²b⁵ + ⁷C₆a¹b⁶ + ⁷C₇b⁷ … (i)

(a-b)⁷ =

⇒ ⁷C₀a⁷ - ⁷C₁a⁶b + ⁷C₂a⁵b² - ⁷C₃a⁴b³ + ⁷C₄a³b⁴ - ⁷C₅a²b⁵ + ⁷C₆a¹b⁶ - ⁷C₇b⁷ … (ii)

Adding eqn. (i) and (ii)

(a+b)⁷ + (a-b)⁷ = [⁷C₀a⁷ + ⁷C₁a⁶b + ⁷C₂a⁵b² + ⁷C₃a⁴b³ + ⁷C₄a³b⁴ + ⁷C₅a²b⁵ + ⁷C₆a¹b⁶ + ⁷C₇b⁷] + [⁷C₀a⁷ - ⁷C₁a⁶b + ⁷C₂a⁵b² - ⁷C₃a⁴b³ + ⁷C₄a³b⁴ - ⁷C₅a²b⁵ + ⁷C₆a¹b⁶ - ⁷C₇b⁷]

⇒ 2[⁷C₀a⁷ + ⁷C₂a⁵b² + ⁷C₄a³b⁴ + ⁷C₆a¹b⁶]

⇒ 2

⇒ 2[(1)a⁷ + (21)a⁵b² + (35)a³b⁴ + (7)ab⁶]

⇒ 2[a⁷ + 21a⁵b² + 35a³b⁴ + 7ab⁶] = (a+b)⁷ + (a-b)⁷

Putting the value of a = 2 and b = in the above equation

= 2

= 2[128 + 21(32)(3)+ 35(8)(9) + 7(2)(27)]

= 2[128 + 2016 + 2520 + 378]

= 10084

Ans) 10084

To find: Value of

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(a+b)⁶ = ⁶C₀a⁶ + ⁶C₁a^6-1b + ⁶C₂a^6-2b² + ⁶C₃a^6-3b³ + ⁶C₄a^6-4b⁴ + ⁶C₅a^6-5b⁵ + ⁶C₆b⁶

⇒ ⁶C₀a⁶ + ⁶C₁a⁵b + ⁶C₂a⁴b² + ⁶C₃a³b³ + ⁶C₄a²b⁴ + ⁶C₅ab⁵ + ⁶C₆b⁶ … (i)

(a-b)⁶

⇒ ⁶C₀a⁶ - ⁶C₁a⁵b + ⁶C₂a⁴b² - ⁶C₃a³b³ + ⁶C₄a²b⁴ - ⁶C₅ab⁵ + ⁶C₆b⁶ … (ii)

Substracting (ii) from (i)

(a+b)⁶ - (a-b)⁶ = [⁶C₀a⁶ + ⁶C₁a⁵b + ⁶C₂a⁴b² + ⁶C₃a³b³ + ⁶C₄a²b⁴ + ⁶C₅ab⁵ + ⁶C₆b⁶] – [⁶C₀a⁶ - ⁶C₁a⁵b + ⁶C₂a⁴b² - ⁶C₃a³b³ + ⁶C₄a²b⁴ - ⁶C₅ab⁵ + ⁶C₆b⁶]

= 2[⁶C₁a⁵b + ⁶C₃a³b³ + ⁶C₅ab⁵]

= 2

= 2[(6)a⁵b + (20)a³b³ + (6)ab⁵]

⇒ (a+b)⁶ - (a-b)⁶ = 2[(6)a⁵b + (20)a³b³ + (6)ab⁵]

Putting the value of a = and b = in the above equation

⇒ 2

⇒ 2

⇒

Ans)

To prove:

Formula used:

Proof: In the above formula if we put a = 1 and b = 3, then we will get

Therefore,

Hence Proved.

(i) (101)⁴

To find: Value of (101)⁴

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

101 = (100+1)

Now (101)⁴ = (100+1)⁴

(100+1)⁴ =  

= 104060401

Ans) 104060401

(ii) (98)⁴

To find: Value of (98)⁴

Formula used: (I)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

98 = (100-2)

Now (98)⁴ = (100-2)⁴

(100-2)⁴

= 92236816

Ans) 92236816

(iii) (1.2)⁴

To find: Value of (1.2)⁴

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

1.2 = (1 + 0.2)

Now (1.2)⁴ = (1 + 0.2)⁴

(1+0.2)⁴

= 2.0736

Ans) 2.0736

To prove: (2³ⁿ - 7n -1) is divisible by 49, where n N

Formula used: (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(2³ⁿ - 7n -1) = (2³)ⁿ – 7n – 1

⇒ 8ⁿ - 7n – 1

⇒ (1+7)ⁿ – 7n – 1

⇒ ⁿC₀1ⁿ + ⁿC₁1^n-17 + ⁿC₂1^n-27² + …… +ⁿC_n-17^n-1 + ⁿC_n7ⁿ – 7n – 1

⇒ ⁿC₀ + ⁿC₁7 + ⁿC₂7² + …… +ⁿC_n-17^n-1 + ⁿC_n7ⁿ – 7n – 1

⇒ 1 + 7n + 7²[ⁿC₂ + ⁿC₃7 + … + ⁿC_n-1 7^n-3 + ⁿC_n 7^n-2] -7n -1

⇒ 7²[ⁿC₂ + ⁿC₃7 + … + ⁿC_n-1 7^n-3 + ⁿC_n 7^n-2]

⇒ 49[ⁿC₂ + ⁿC₃7 + … + ⁿC_n-1 7^n-3 + ⁿC_n 7^n-2]

⇒ 49K, where K = (ⁿC₂ + ⁿC₃7 + … + ⁿC_n-1 7^n-3 + ⁿC_n7^n-2)

Now, (2³ⁿ - 7n -1) = 49K

Therefore (2³ⁿ - 7n -1) is divisible by 49

To prove:

Formula used: (i)

(ii) (a+b)ⁿ =   ⁿC₀aⁿ + ⁿC₁a^n-1b + ⁿC₂a^n-2b² + …… +ⁿC_n-1ab^n-1 + ⁿC_nbⁿ

(a+b)⁴ = ⁴C₀a⁴ + ⁴C₁a^4-1b + ⁴C₂a^4-2b² + ⁴C₃a^4-3b³ + ⁴C₄b⁴

⇒ ⁴C₀a⁴ + ⁴C₁a³b + ⁴C₂a²b² + ⁴C₃a¹b³ + ⁴C₄b⁴ … (i)

(a-b)⁴ = ⁴C₀a⁴ + ⁴C₁a^4-1(-b) + ⁴C₂a^4-2(-b)² +⁴C₃a^4-3(-b)³+⁴C₄(-b)⁴

⇒ ⁴C₀a⁴ - ⁴C₁a³b + ⁴C₂a²b² - ⁴C₃ab³ + ⁴C₄b⁴ … (ii)

Adding (i) and (ii)

(a+b)⁴ + (a-b)⁷ = [⁴C₀a⁴ + ⁴C₁a³b + ⁴C₂a²b² + ⁴C₃a¹b³ + ⁴C₄b⁴] + [⁴C₀a⁴ - ⁴C₁a³b + ⁴C₂a²b² - ⁴C₃ab³ + ⁴C₄b⁴]

⇒ 2[⁴C₀a⁴ + ⁴C₂a²b² + ⁴C₄b⁴]

⇒ 2

⇒ 2[(1)a⁴ + (6)a²b² + (1)b⁴]

⇒ 2[a⁴ + 6a²b² + b⁴]

Therefore, (a+b)⁴ + (a-b)⁷ = 2[a⁴ + 6a²b² + b⁴]

Now, putting a = 2 and b = in the above equation.

= 2[(2)⁴ + 6(2)² ()² + ()⁴]

= 2(16+24x+x²)

Hence proved.

To find: 7^th term in the expansion of

Formula used: (i)

(ii) T_r+1 = ⁿC_r a^n-r b^r

For 7^th term, r+1=7

⇒ r = 6

In,

7^th term = T₆₊₁

⇒ (28)

⇒

Ans)

To find: 9^th term in the expansion of

Formula used: (i)

(ii) T_r+1 = ⁿC_r a^n-r b^r

For 9^th term, r+1=9

⇒ r = 8

In,

9^th term = T₈₊₁

⇒ ¹²C₈

⇒

⇒ 495

⇒

Ans)

To find: 16^th term in the expansion of

Formula used: (i)

(ii) T_r+1 = ⁿC_r a^n-r b^r

For 16^th term, r+1=16

⇒ r = 15

In,

16^th term = T₁₅₊₁

⇒ -136x
Ans) -136x

To find: 13^th term in the expansion of

Formula used: (i)

(ii) T_r+1 = ⁿC_r a^n-r b^r

For 13^th term, r+1=13

⇒ r = 12

In,

13^th term = T₁₂₊₁

⇒ 18564

To find : coefficients of x⁷ and x⁸

Formula :

Here, a=2,

We have,

To get a coefficient of x⁷, we must have,

x⁷ = x^r

• r = 7

Therefore, the coefficient of x⁷

And to get the coefficient of x⁸ we must have,

x⁸ = x^r

• r = 8

Therefore, the coefficient of x⁸

Conclusion :

• coefficient of x⁷

• coefficient of x⁸

To Find: the ratio of the coefficient of x¹⁵ to the term independent of x

Formula :

Here, a=x², and n=15

We have a formula,

To get coefficient of x¹⁵ we must have,

(x)^30-3r = x¹⁵

• 30 - 3r = 15

• 3r = 15

• r = 5

Therefore, coefficient of x¹⁵

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^30-3r = x⁰

• 30 - 3r = 0

• 3r = 30

• r = 10

Therefore, coefficient of x⁰

But ……….

Therefore, the coefficient of x⁰

Therefore,

Hence, coefficient of x¹⁵ : coefficient of x⁰ = 1:32

Conclusion : The ratio of coefficient of x¹⁵ to coefficient of x⁰ = 1:32

To Prove : coefficient of x¹⁰ in (1-x²)¹⁰: coefficient of x⁰ in = 1:32

For (1-x²)¹⁰ ,

Here, a=1, b=-x² and n=15

We have formula,

To get coefficient of x¹⁰ we must have,

(x)^2r = x¹⁰

• 2r = 10

• r = 5

Therefore, coefficient of x¹⁰

For ,

Here, a=x, and n=10

We have a formula,

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^10-2r = x⁰

• 10 - 2r = 0

• 2r = 10

• r = 5

Therefore, coefficient of x⁰

Therefore,

Hence,

coefficient of x¹⁰ in (1-x²)¹⁰: coefficient of x⁰ in = 1:32

To Find : term independent of x, i.e. coefficient of x⁰

Formula :

We have a formula,

Therefore, the expansion of is given by,

Now,

Multiplying the second bracket by 91 , x and 2x³

In the first bracket, there will be a 6^th term of x⁰ having coefficient

While in the second and third bracket, the constant term is absent.

Therefore, the coefficient of term independent of x, i.e. constant term in the above expansion

=-91(2)⁵ (252)

Conclusion : coefficient of term independent of x =-91(2)⁵ (252)

To Find : coefficient of x

Formula :

We have a formula,

Therefore, expansion of (1-x)¹⁶ is given by,

Now,

Multiplying the second bracket by 1 , (-3x) and 7x²

In the above equation terms containing x are

and -3x

Therefore, the coefficient of x in the above expansion

=-16-3

=-19

Conclusion : coefficient of x =-19

(i) Here, a=x, b=3 and n=8

We have a formula,

To get coefficient of x⁵ we must have,

(x)^8-r = x⁵

• 8 - r = 5

• r = 3

Therefore, coefficient of x⁵

= 1512

(ii) Here, a=3x², and n=9

We have a formula,

To get coefficient of x⁶ we must have,

(x)^18-3r = x⁶

• 18 - 3r = 6

• 3r = 12

• r = 4

Therefore, coefficient of x⁶

= 126×3

= 378

(iii) Here, a=3x², and n=10

We have a formula,

To get coefficient of x^-15 we must have,

(x)^20-5r = x^-15

• 20 - 5r = -15

• 5r = 35

• r = 7

Therefore, coefficient of x^-15

But ……….

Therefore, qthe coefficient of x^-15

(iv) Here, a=a, b=-2b and n=12

We have formula,

To get coefficient of a⁷b⁵ we must have,

(a)^12-r (b)^r = a⁷b⁵

• r = 5

Therefore, coefficient of a⁷b⁵

= 792. (-32)

= -25344

For ,

a=3x, and n=8

We have a formula,

To get coefficient of x³ we must have,

(x)^8-2r = (x)³

• 8 - 2r = 3

• 2r = 5

• r = 2.5

As is not possible

Therefore, the term containing x³ does not exist in the expansion of

For ,

a=2x², and n=20

We have a formula,

To get coefficient of x⁹ we must have,

(x)^40-3r = (x)⁹

• 40 - 3r = 9

• 3r = 31

• r = 10.3333

As is not possible

Therefore, the term containing x⁹ does not exist in the expansion of

For ,

a=x², and n=12

We have a formula,

To get coefficient of x^-1 we must have,

(x)^24-3r = (x)^-1

• 24 - 3r = -1

• 3r = 25

• r = 8.3333

As is not possible

Therefore, the term containing x^-1 does not exist in the expansion of

To Find : General term, i.e. t_r+1

For (x² - y)⁶

a=x², b=-y and n=6

General term t_r+1 is given by,

Conclusion : General term

To Find : 5^th term from the end

Formulae :

•

•

For ,

a=x, and n=12

As n=12 ,therefore there will be total (12+1)=13 terms in the expansion

Therefore,

5^th term from the end = (13-5+1)^th i.e. 9^th term from the starting.

We have a formula,

For t₉ , r=8

……….

Therefore, a 5^th term from the end

Conclusion : 5^th term from the end

To Find : 4^th term from the end

Formulae :

•

•

For ,

, and n=9

As n=9 ,therefore there will be total (9+1)=10 terms in the expansion

Therefore,

4^th term from the end = (10-4+1)^th, i.e. 7^th term from the starting.

We have a formula,

For t₇ , r=6

……….

Therefore, a 4^th term from the end

Conclusion : 4^th term from the end

To Find :

I. 4^th term from the beginning

II. 4^th term from the end

Formulae :

•

•

For ,

, and n=9

As n=n ,therefore there will be total (n+1) terms in the expansion

Therefore,

I. For the 4^th term from the starting.

We have a formula,

For t₄ , r=3

Therefore, a 4^th term from the starting

Now,

II. For the 4^th term from the end

We have a formula,

For t_(n-2) , r = (n-2)-1 = (n-3)

……….

Therefore, a 4^th term from the end

Conclusion :

I. 4^th term from the beginning

II. 4^th term from the end

(i) For (3 + x)⁶,

a=3, b=x and n=6

As n is even, is the middle term

Therefore, the middle term

General term t_r+1 is given by,

Therefore, for 4^th , r=3

Therefore, the middle term is

= (20). (27) x³

= 540 x³

(ii) For ,

, b=3y and n=8

As n is even, is the middle term

Therefore, the middle term

General term t_r+1 is given by,

Therefore, for 5^th , r=4

Therefore, the middle term is

= (70). x⁴ y⁴

(iii) For ,

, and n=10

As n is even, is the middle term

Therefore, the middle term

General term t_r+1 is given by,

Therefore, for 6^th , r=5

Therefore, the middle term is

= -252

(iv) For ,

a=x², and n=10

As n is even, is the middle term

Therefore, the middle term

General term t_r+1 is given by,

Therefore, for the 6^th middle term, r=5

Therefore, the middle term is

= -252 (32) x⁵

= -8064 x⁵

For (x² + a²)⁵,

a= x², b= a² and n=5

As n is odd, there are two middle terms i.e.

I. and II.

General term t_r+1 is given by,

I. The first, middle term is

Therefore, for the 3^rd middle term, r=2

Therefore, the first middle term is

= 10. a⁴. x⁶

II. The second middle term is

Therefore, for the 4^th middle term, r=3

Therefore, the second middle term is

………

= 10. a⁶. x⁴

For ,

a= x⁴, and n=11

As n is odd, there are two middle terms i.e.

II. and II.

General term t_r+1 is given by,

I. The first middle term is

Therefore, for the 6^th middle term, r=5

Therefore, the first middle term is

= - 462. x⁹

II. The second middle term is

Therefore, for the 7^th middle term, r=6

Therefore, the second middle term is

………

= 462. x²

For ,

, and n=9

As n is odd, there are two middle terms i.e.

I. and II.

General term t_r+1 is given by,

I. The first middle term is

Therefore, for 5^th middle term, r=4

Therefore, the first middle term is

= 126p. x^-1

II. The second middle term is

Therefore, for the 6^th middle term, r=5

Therefore, the second middle term is

………

For ,

a=3x, and n=9

As n is odd, there are two middle terms i.e.

I. and II.

General term t_r+1 is given by,

I. The first middle term is

Therefore, for 5^th middle term, r=4

Therefore, the first middle term is

II. The second middle term is

Therefore, for the 6^th middle term, r=5

Therefore, the second middle term is

………

To Find : term independent of x, i.e. x⁰

For

a=2x, and n=9

We have a formula,

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^9-3r = x⁰

• 9 - 3r = 0

• 3r = 9

• r = 3

Therefore, coefficient of x⁰

Conclusion : coefficient of x⁰

To Find : term independent of x, i.e. x⁰

For

, and n=6

We have a formula,

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^12-3r = x⁰

• 12 - 3r = 0

• 3r = 12

• r = 4

Therefore, coefficient of x⁰

………

Conclusion : coefficient of x⁰

To Find : term independent of x, i.e. x⁰

For

a=x, and N=3n

We have a formula,

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^3n-3r = x⁰

• 3n - 3r = 0

• 3r = 3n

• r = n

Therefore, coefficient of x⁰

Conclusion : coefficient of x⁰

To Find : term independent of x, i.e. x⁰

For

a=3x, and n=15

We have a formula,

Now, to get coefficient of term independent of xthat is coefficient of x⁰ we must have,

(x)^15-3r = x⁰

• 15 - 3r = 0

• 3r = 15

• r = 5

Therefore, coefficient of x⁰

Conclusion : coefficient of x⁰

To Find : coefficient of x⁵

For (1+x)³

a=1, b=x and n=3

We have a formula,

For (1-x)⁶

a=1, b=-x and n=6

We have formula,

We have a formula ,

By using this formula, we get,×

Coefficients of x⁵ are

x⁰.x⁵ = 1× (-6)=-6

x¹.x⁴ = 3×15=45

x².x³ = 3×(-20)=-60

x³.x² = 1×15=15

Therefore, Coefficients of x⁵ = -6+45-60+15 = -6

Conclusion : Coefficients of x⁵ = -6

To Find : numerically greatest term

For (2+3x)⁹,

a=2, b=3x and n=9

We have relation,

t_r+1 ≥ t_r or

we have a formula,

At x = 3/2

• 90 ≥ 13r

• r ≤ 6.923

therefore, r=6 and hence the 7^th term is numerically greater.

By using formula,

Conclusion : the 7^th term is numerically greater with value

For (1 + x)²ⁿ

a=1, b=x and N=2n

We have,

For the 2^nd term, r=1

………

Therefore, the coefficient of 2^nd term = (2n)

For the 3^rd term, r=2

……….(n! = n. (n-1)!)

Therefore, the coefficient of 3^rd term = (n)(2n-1)

For the 4^th term, r=3

……….(n! = n. (n-1)!)

Therefore, the coefficient of 3^rd term

As the coefficients of 2^nd, 3^rd and 4^th terms are in A.P.

Therefore,

2×coefficient of 3^rd term = coefficient of 2^nd term + coefficient of the 4^th term

Dividing throughout by (2n),

• 3 (2n-1) = 3 + (2n-1)(n-1)

• 6n – 3 = 3 + (2n² - 2n – n + 1)

• 6n – 3 = 3 + 2n² - 3n + 1

• 3 + 2n² - 3n + 1 - 6n + 3 = 0

• 2n² - 9n + 7 = 0

Conclusion : If the coefficients of 2^nd, 3^rd and 4^th terms of (1 + x)²ⁿ are in A.P. then 2n² - 9n + 7 = 0

Given : 3^rd term from the end =45

To Find : 6^th term

For (y^1/2 + x^1/3)ⁿ,

a= y^1/2, b= x^1/3

We have,

As n=n, therefore there will be total (n+1) terms in the expansion.

3^rd term from the end = (n+1-3+1)^th i.e. (n-1)^th term from the starting

For (n-1)^th term, r = (n-1-1) = (n-2)

………..

Therefore 3^rd term from the end

Therefore coefficient 3^rd term from the end

• 90 = n (n-1)

• 10 (9) = n (n-1)

Comparing both sides, n=10

For 6^th term, r=5

Conclusion : 6^th term

Given :

To Find : value of a

For (2 + a)⁵⁰

A=2, b=a and n=50

We have,

For the 17^th term, r=16

For the 18^th term, r=17

As 17^th and 18^th terms are equal

……..

……..

• a = 1122

Conclusion : value of a = 1122

To Find : Coefficients of x⁴

For (1+x)ⁿ

a=1, b=x

We have a formula,

For (1-x)ⁿ

a=1, b=-x and n=n

We have formula,

Coefficients of x⁴ are

x⁰.x⁴ = C₀C₄

x¹.x³ = - C₁C₃

x².x² = C₂C₂

x³.x¹= - C₃C₁

x⁴.x⁰ = C₄C₀

Therefore, Coefficient of x⁴

= C₄C₀ - C₁C₃ + C₂C₂ - C₃C₁ + C₄C₀

Let us assume, n=4, it becomes

⁴C₄⁴C₀ - ⁴C₁⁴C₃ + ⁴C₂⁴C₂ - ⁴C₃⁴C₁ + ⁴C₄⁴C₀

We know that ,

By using above formula, we get,

⁴C₄⁴C₀ - ⁴C₁⁴C₃ + ⁴C₂⁴C₂ - ⁴C₃⁴C₁ + ⁴C₄⁴C₀

= (1)(1) – (4)(4) + (6)(6) – (4)(4) + (1)(1)

= 1 – 16 + 36 – 16 + 1

= 6

= ⁴C₂

Therefore, in general,

C₄C₀ - C₁C₃ + C₂C₂ - C₃C₁ + C₄C₀ = C₂

Therefore, Coefficient of x⁴ = C₂

Conclusion :

• Coefficient of x⁴ = C₂

• C₄C₀ - C₁C₃ + C₂C₂ - C₃C₁ + C₄C₀ = C₂

To Prove : coefficient of xⁿ in (1+x)²ⁿ = 2 × coefficient of xⁿ in (1+x)^2n-1

For (1+x)²ⁿ,

a=1, b=x and m=2n

We have a formula,

To get the coefficient of xⁿ, we must have,

xⁿ = x^r

• r = n

Therefore, the coefficient of xⁿ

………

………..

………cancelling n

Therefore, the coefficient of xⁿ in (1+x)²ⁿ………eq(1)

Now for (1+x)^2n-1,

a=1, b=x and m=2n-1

We have formula,

To get the coefficient of xⁿ, we must have,

xⁿ = x^r

• r = n

Therefore, the coefficient of xⁿ in (1+x)^2n-1

…..multiplying and dividing by 2

Therefore,

coefficient of xⁿ in (1+x)^2n-1 = � × coefficient of xⁿ in (1+x)²ⁿ

or coefficient of xⁿ in (1+x)²ⁿ = 2 × coefficient of xⁿ in (1+x)^2n-1

Hence proved.

Given : , b=2 and n=8

To find : middle term

Formula :

• The middle term

•

Here, n is even.

Hence,

Therefore, tthe erm is the middle term.

For , r=4

We have,

Conclusion : The middle term is .

To show: the term independent of x in the expansion of is -252.

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, , we get

T_r+1¹⁰C_r

For finding the term which is independent of x,

10-2r=5

r=5

Thus, the term which would be independent of x is T₆

T₆¹⁰C₅

T₆¹⁰C₅

T₆¹⁰C₅

T₆

T₆

T₆

T₆

T₆=252

Thus, the term independent of x in the expansion of is -252.

To prove: that. If the coefficients of x² and x³ in the expansion of (3 + px)⁹ are the same then .

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, (3 + px)⁹ , we get

T_r+1⁹C_r

For finding the term which has in it, is given by

r=2

Thus, the coefficients of x² are given by,

T₃⁹C₂

T₃⁹C₂

For finding the term which has in it, is given by

r=3

Thus, the coefficients of x³ are given by,

T₃⁹C₃

T₃⁹C₃

As the coefficients of x² and x³ in the expansion of (3 + px)⁹ are the same.

⁹C₃⁹C₂

⁹C₃⁹C₂

Thus, the value of p for which coefficients of x² and x³ in the expansion of (3 + px)⁹ are the same is

To show: that the coefficient of x^-3 in the expansion of is -330.

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, , we get

T_r+1¹¹C_r

For finding the term which has in it , is given by

11-2r=3

2r=14

r=7

Thus, the term which the term which has in it isT₈

T₈¹¹C₇

T₈¹¹C₇

T₈

T₆

T₆=-330

Thus, the coefficient of x^-3 in the expansion of is -330.

To show: that the middle term in the expansion of is 252.

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Total number of terms in the expansion is 11

Thus, the middle term of the expansion is T₆ and is given by,

T₆¹⁰C₅

T₆¹⁰C₅

T₆

T₆=252

Thus, the middle term in the expansion of is 252.

To show: that the coefficient of x⁴ in the expansion of is -330.

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, , we get

T_r+1¹⁰C_r

For finding the term which has in it, is given by

10-3r=4

3r=6

r=2

Thus, the term which has in it isT₃

T₃¹⁰C₂

T₃

T₃

T₃

Thus, the coefficient of x⁴ in the expansion of is

To prove: that there is no term involving x⁶ in the expansion of

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, , we get

T_r+1¹¹C_r

For finding the term which has in it, is given by

22-2r-r=6

3r=16

Since, is not possible as r needs to be a whole number

Thus, there is no term involving x⁶ in the expansion of.

To show: that the coefficient of x⁴ in the expansion of (1 + 2x + x²)⁵ is 212.

Formula Used:

We have,

(1 + 2x + x²)⁵=(1 +x+ x+ x²)⁵

=(1 +x+ x(1+x))⁵

=(1 +x)⁵(1 +x)⁵

=(1 +x)¹⁰

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where s

ⁿC_r

Now, finding the general term,

T_r+1¹⁰C_r

10-r=4

r=6

Thus, the coefficient of x⁴ in the expansion of (1 + 2x + x²)⁵ is given by,

¹⁰C₄

¹⁰C₄

¹⁰C₄=210

Thus, the coefficient of x⁴ in the expansion of (1 + 2x + x²)⁵ is 210

To find: the number of terms in the expansion of

Formula Used:

Binomial expansion of is given by,

Thus,

So, the no. of terms left would be 6

Thus, the number of terms in the expansion of is 6

To find: the term independent of x in the expansion of?

Formula Used:

A general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, , we get

T_r+1⁹C_r

T_r+1⁹C_r

T_r+1⁹C_r

For finding the term which is independent of x,

9-3r=0

r=3

Thus, the term which would be independent of x is T₄

Thus, the term independent of x in the expansion of is T₄ i.e 4^th term

To find: that the middle term in the expansion of is 252.

Formula Used:

A general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Total number of terms in the expansion is 11

Thus, the middle term of the expansion is T₆ and is given by,

T₆¹⁰C₅

T₆¹⁰C₅

T₆

T₆=252

Thus, the middle term in the expansion of is 252.

To find: the coefficient of x⁷y² in the expansion of (x + 2y)⁹

Formula Used:

A general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, (x + 2y)⁹, we get

T_r+1⁹C_r

The value of r for which coefficient of x⁷y² is defined

r=2

Hence, the coefficient of x⁷y² in the expansion of (x + 2y)⁹ is given by:

T₃⁹C₃

T₃⁹C₃

T₃

T₃

T₃=336

Thus, the coefficient of x⁷y² in the expansion of (x + 2y)⁹ is 336

To find: the value of r with respect to the binomial expansion of (1 + x)³⁴ where the coefficients of the (r – 5)th and (2r – 1)th terms are equal to each other

Formula Used:

The general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the (r – 5)th term, we get

T_r-5³⁴C_r-6

Thus, the coefficient of (r – 5)th term is ³⁴C_r-6

Now, finding the (2r – 1)th term, we get

T_2r-1³⁴C_2r-2

Thus, coefficient of (2r – 1)th term is ³⁴C_2r-2

As the coefficients are equal, we get

³⁴C_2r-2³⁴C_r-6

2r-2=r-6

r=-4

Value of r=-4 is not possible

2r-2+r-6=34

3r=42

r=14

Thus, value of r is 14

To find: 4^th term from the end in the expansion of

Formula Used:

A general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Total number of terms in the expansion is 8

Thus, the 4^th term of the expansion is T₅ and is given by,

T₅⁷C₅

T₅

T₅

T₅

Thus, a 4^th term from the end in the expansion of is T₅

To find: the coefficient of xⁿ in the expansion of (1 + x) (1 – x)ⁿ.

Formula Used:

Binomial expansion of is given by,

Thus,

Thus, the coefficient of is,

ⁿC_n-ⁿC_n-1 (If n is even)

-ⁿC_n+ⁿC_n-1 (If n is odd)

Thus, the coefficient of is,ⁿC_n-ⁿC_n-1 (If n is even)and -ⁿC_n+ⁿC_n-1 (If n is odd)

To find: the value of n with respect to the binomial expansion of (a + b)ⁿ where the coefficients of the 4^th and 13^th terms are equal to each other

Formula Used:

A general term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the 4^th term, we get

T₄ⁿC₃

Thus, the coefficient of a 4^th term is ⁿC₃

Now, finding the 13^th term, we get

T₁₃ⁿC₁₂

Thus, coefficient of 4^th term is ⁿC₁₂

As the coefficients are equal, we get

ⁿC₁₂= ⁿC₃

Also, ⁿC_r= ⁿC_n-r

ⁿC_n-12=ⁿC₃

n-12=3

n=15

Thus, value of n is 15

To find: the positive value of m for which the coefficient of x² in the expansion of (1 + x)^m is 6.

Formula Used:

General term, T_r+1 of binomial expansionis given by,

T_r+1ⁿC_r x^n-r y^r where

ⁿC_r

Now, finding the general term of the expression, (1 + x)^m , we get

T_r+1^mC_r

T_r+1^mC_r

The coefficient of is ^mC₂

^mC₂=6

=6

m=3,-2

Since m cannot be negative. Therefore,

m=3

Thus, positive value of m is 3 for which the coefficient of x2 in the expansion of (1 + x)^m is 6