If f is a real-valued differentiable function such that f(x)f' (x) < 0 for all real x, then
f(x) must be an increasing function
f(x) must be a decreasing function
must be an increasing function
must be a decreasing function
Rolle's theorem is applicable in the interval [- 2, 2] for the function
f(x) = x3
f(x) = 4x4
f(x) = 2x3 + 3
f(x) =
B.
f(x) = 4x4
If we take f(x) = 4x4, then
(i) f(x) is continuous in (- 2 2)
(ii) f (x) is differentiable in (- 2 2)
(iii) f(- 2) = f(2)
So, f(x) = 4x4 satisfies all the conditions of Rolle's theorem therefore J a point c such that f' (c) = 0
The system of linear equations x + y + z = 3, x - y - 2z = 6, - x + y + z = µ has
infinite number of solutions for -1 and all µ
infinite number of solutions for = - 1 and = 3
no solution for
unique solution for = - 1 and = 3
If f(x) and g(x) are twice differentiable functions on (0, 3) satisfying f"(x) = g''(c), f'(1) = 4g'(D) = 6, f(2) = 3, g(2) = 9, then f(1) - g(1) is
4
- 4
0
- 2
Two coins are available, one fair and the other two headed. Choose a coin and toss it once; assume that the unbiased coin is chosen with probability . Given that the outcome is head, 4 the probability that the two headed coin was chosen, is