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Sequences and Series

Multiple Choice Questions

191.

If x and y are digits such that 17! = 3556xy428096000, then x + y equals

192.

Let f(x) = x + 1/2. Then, the number of real values of x for which the three unequal terms f(x), f(2x), f(4x) are in HP is

193.

The value of the sum ${({}^{n}C_{1})}^{2} + {({}^{n}C_{2})}^{2} + {({}^{n}C_{3})}^{2} + . . . + {({}^{n}C_{n})}^{2}$ is

${({}^{2 n}C_{n})}^{2}$
${}^{2 n}C_{n}$
${}^{2 n}C_{n} + 1$
${}^{2 n}C_{n} - 1$

194.

The remainder obtained when 1! + 2! + 3! + ... + 11! is divided by 12 is

195.

Let S = $\frac{2}{1} {}^{n}C_{0} + \frac{2^{2}}{2} {}^{n}C_{1} + \frac{2^{3}}{3} {}^{n}C_{2} + . . . + \frac{2^{n + 1}}{n + 1} {}^{n}C_{n}$ . Then, S equals

$\frac{2^{n + 1} - 1}{n + 1}$
$\frac{3^{n + 1} - 1}{n + 1}$
$\frac{3^{n} - 1}{n}$
$\frac{2^{n} - 1}{n}$

196.

If a, b and c are positive numbers in a GP, then the roots of the quadratic equation

$(\log_{e} (a)) x^{2} - (2 \log_{e} (b)) x + \log_{e} (c) = 0$ are

$- 1 and \frac{\log_{e} (c)}{\log_{e} (a)}$
$1 and - \frac{\log_{e} (c)}{\log_{e} (a)}$
$1 and \log_{a} (c)$
$- 1 and \log_{c} (a)$

197.

The sum of the series $\sum_{n = 1}^{\infty} \sin (\frac{n! π}{720})$ is

$\sin (\frac{π}{180}) + \sin (\frac{π}{360}) + \sin (\frac{π}{540})$
$\sin (\frac{π}{6}) + \sin (\frac{π}{30}) + \sin (\frac{π}{120}) + \sin (\frac{π}{360})$
$\sin (\frac{π}{6}) + \sin (\frac{π}{30}) + \sin (\frac{π}{120}) + \sin (\frac{π}{360}) + \sin (\frac{π}{720})$
$\sin (\frac{π}{180}) + \sin (\frac{π}{360})$

198.
The coefficient of x³ in the infinite series expansion of
$\frac{2}{(1 - x) (2 - x)}, for |x| < 1$ , is

$- \frac{1}{16}$

$\frac{15}{8}$

$- \frac{1}{8}$

$\frac{15}{16}$

$\frac{15}{8}$

Given expression can be rewritten as,

$2 {(1 - x)}^{- 1} \times 2^{- 1} {(1 - \frac{x}{2})}^{- 1} = [1 + x + x^{2} + x^{3} + . . .] [1 + (\frac{x}{2}) + {(\frac{x}{2})}^{2} + {(\frac{x}{2})}^{3} + . . .]$

$∴$ Coefficient of x³ in the above expression is

$= [{(\frac{1}{2})}^{3} + {(\frac{1}{2})}^{2} + (\frac{1}{2}) + 1] = [\frac{1}{8} + \frac{1}{4} + \frac{1}{2} + 1] = [\frac{1 + 2 + 4 + 8}{8}] = \frac{15}{8}$

199.

For every real number x,

let f(x) = $\frac{x}{1!} + \frac{3}{2!} x^{2} + \frac{7}{3!} x^{3} + \frac{15}{4!} x^{4} + . . .$ Then, the equation f(x) = 0 has

no real solution
exactly one real solution
exactly two real solutions
infinite number of real solutions

200.

Let S denote the sum of the infinite series $1 + \frac{8}{2!} + \frac{21}{3!} + \frac{40}{4!} + \frac{65}{5!} + . . .$

$S < 8$
$S > 12$
8 < S < 12
S = 8

Previous Year Papers

Test Series

Test Yourself

Multiple Choice Questions

198. The coefficient of x3 in the infinite series expansion of 21 - x2 - x, for x < 1, is - 116 158 - 18 1516

198.
The coefficient of x³ in the infinite series expansion of
$\frac{2}{(1 - x) (2 - x)}, for |x| < 1$ , is

$- \frac{1}{16}$

$\frac{15}{8}$

$- \frac{1}{8}$

$\frac{15}{16}$