Let $$A_{1},A_{2},.....A_{n}$$ be then points on the straight - line y = px + q. The coordinates of $$A_{k}is(X_{k},Y_{k})$$, where k = 1, 2, ...n such that $$X_{1},X_{2}....X_{n}$$ are in arithmetic progression. The coordinates of $$A_{2}$$ is (2,–2) and $$A_{24}$$ is (68, 31).
The number of point(s) satisfying the above mentioned characteristics and not in the first quadrant is/are
$$x_1 , x_2 , x_3,......., x_n$$ are in A.P. Let the first term be $$a$$ and common difference be $$d$$
Also, $$x_2 = a + d = 2$$
and $$x_{24} = a + 23d = 68$$
Solving above equations, we get : $$a = -1$$ and $$d = 3$$
=> x coordinates = {$$x_1 , x_2 , x_3, x_4 , x_5 ,.......$$} = {$${-1 , 2 , 5 , 8 , 11 , 14 ,......}$$} -------------(i)
To find y coordinates, we will use $$y = px + q$$
$$\because A_2 (2, -2)$$ and $$A_{24} (68, 31)$$
Substituting in above equation, => $$-2 = 2p + q$$
and $$31 = 68p + q$$
Solving above equations, we get : $$p = \frac{1}{2}$$ and $$q = -3$$
=> $$y_1 = px_1 + q = \frac{1}{2}(-1) + (-3) = -3.5$$
Similarly, y coordinates = {$$y_1 , y_2 , y_3, y_4 , y_5 ,.......$$} = {$${-3.5 , -2 , \frac{-1}{2} , 1 ,......}$$} -------(ii)
From (i) and (ii),
=> $$A_1 = (-1 , -3.5)$$
$$A_2 = (2 , -2)$$
$$A_3 = (5 , \frac{-1}{2})$$
$$A_4 = (8 , 1)$$
For the points to lie in the first quadrant, the coordinates of both $$(x_k , y_k)$$ must be positive.
Since, $$d$$ is positive and $$y$$ is a linear relation in $$x$$, the corresponding coordinates of $$A_k$$ i.e. $$A_5$$ onwards will be increasing.
Thus, only for $$A_1 , A_2$$ and $$A_3$$ we do not have both coordinates positive.
$$\therefore$$ Only 3 points do not lie in the first quadrant.
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