Q1: Evaluate (101)4 using the binomial theorem.
Ans: Given: (101)4.
Here, 101 can be written as the sum or the difference of two numbers, such that the binomial theorem can be applied.
Therefore, 101 = 100+1
Hence, (101)4 = (100+1)4
Now, by applying the binomial theorem, we get:
(101)4 = (100+1)4 = 4C0(100)4 + 4C1 (100)3(1) + 4C2(100)2(1)2 +4C3(100)(1)3 + 4C4(1)4
(101)4 = (100)4 + 4(100)3 + 6(100)2 + 4(100) + (1)4
(101)4 = 100000000 + 4000000 + 60000 + 400+1
(101)4 = 104060401
Hence, the value of (101)4 is 104060401.
Q2: Find the value of r, If the coefficients of (r – 5)th and (2r – 1)th terms in the expansion of (1 + x)34 are equal.
Ans: For the given condition, the coefficients of (r – 5)th and (2r – 1)th terms of the expansion (1 + x)34 are 34Cr-6 and 34C2r-2 respectively.
Since the given terms in the expansion are equal,
34Cr-6 = 34C2r-2
From this, we can write it as either
r-6=2r-2
(or)
r-6=34 -(2r-2) [We know that, if nCr = nCp , then either r = p or r = n – p
So, we get either r = – 4 or r = 14.
We know that r being a natural number, the value of r = – 4 is not possible.
Hence, the value of r is 14.
Q3: Expand the expression (2x-3)6 using the binomial theorem.
Ans: Given Expression: (2x-3)6
By using the binomial theorem, the expression (2x-3)6 can be expanded as follows:
(2x-3)6 = 6C0(2x)6 –6C1(2x)5(3) + 6C2(2x)4(3)2 – 6C3(2x)3(3)3 + 6C4(2x)2(3)4 – 6C5(2x)(3)5 + 6C6(3)6
(2x-3)6 = 64x6 – 6(32x5 )(3) +15(16x4 )(9) – 20(8x3 )(27) +15(4x2 )(81) – 6(2x)(243) + 729
(2x-3)6 = 64x6 -576x5 + 2160x4 – 4320x3 + 4860x2 – 2916x + 729
Thus, the binomial expansion for the given expression (2x-3)6 is 64x6 -576x5 + 2160x4 – 4320x3 + 4860x2 – 2916x + 729.
Q4: Using the binomial theorem, show that 6n–5n always leaves remainder 1 when divided by 25
Ans: Assume that, for any two numbers, say x and y, we can find numbers q and r such that x = yq + r, then we say that b divides x with q as quotient and r as remainder. Thus, in order to show that 6n – 5n leaves remainder 1 when divided by 25, we should prove that 6n – 5n = 25k + 1, where k is some natural number.
We know that,
(1 + a)n = nC0 + nC1 a + nC2 a2 + … + nCn an
Now for a=5, we get:
(1 + 5)n = nC0 + nC1 5 + nC2 (5)2 + … + nCn 5n
Now the above form can be written as:
6n = 1 + 5n + 52 nC2 + 53 nC3 + ….+ 5n
Now, bring 5n to the L.H.S, we get
6n – 5n = 1 + 52 nC2 + 53 nC3 + ….+ 5n
6n – 5n = 1 + 52 (nC2 + 5 nC3 + ….+ 5n-2)
6n – 5n = 1 + 25 (nC2 + 5 nC3 + ….+ 5n-2)
6n – 5n = 1 + 25 k (where k = nC2 + 5 nC3 + ….+ 5n-2)
The above form proves that, when 6n–5n is divided by 25, it leaves the remainder 1.
Hence, the given statement is proved.
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