Question

If the (a+1)th ,7th ,and (b+1)th terms of an A.P, are in G.P with a,6,b being in H.P, then the 4th term of this A.P is ? (A) -7/2 (B) 7/2 (C) 0 (D) 3

Answer 1

(C) 0.

Explanation:

For the AP in Question, suppose the `n^(th)` term and

the common difference are , resp., `t_n and d!=0`.

If `t_1=x," then, "t_n=x+(n-1)d, n in NN`.

Given that, `t_(a+1), t_7, t_(b+1)` are in GP.

`:. (x+ad), (x+6d), (x+bd)` are in GP.

`:. (x+6d)^2=(x+ad)(x+bd)`.

`:. cancel(x^2)+12xd+36d^2=cancel(x^2)+(a+b)xd+abd^2`.

Dividing by `d!=0, 12x+36d=(a+b)x+abd......(star)`.

Here, `a,6,b` are in HP, or, `1/a, 1/6, 1/b` in B

`:. 2*(1/6)=1/a+1/b, i.e., 1/3=(a+b)/(ab)`.

`:. a+b=1/3ab`.

Sub.ing in `(star), 12x+36d=1/3abx+abd=1/3ab(x+3d)`

`:. 12(x+3d)-1/3ab(x+3d)=0`

`:. (x+3d)(12-1/3ab)=0`.

`:. (x+3d)=0, or, ab=36`.

In case, `ab=36," then "a+b=1/3ab=12`.

Solving these for `a and b`, we get, `a=b=6`.

But, in that event, `t_(a+1)=t_(b+1)=t_7` will make `d=0`.

So, let us discard that possibility.

We are now left with `x+3d=0`, which is, in fact, `t_4`.

Hence, the Right Option is (C) 0.

Enjoy Maths!