Let g(x) be the inverse of an invertible function f(x), which is differentiable for all x, then `g''f(x)` is equal to

Let g(x) be the inverse of an invertible function f(x) which is differentiable at x=c . Then g^(prime)(f(x)) equal. (a) f^(prime)(c) (b) 1/(f^(prime)(c)) (c) f(c) (d) none of these

Statement I f(x) = |x| sin x is differentiable at x = 0. Statement II If g(x) is not differentiable at x = a and h(x) is differentiable at x = a, then g(x).h(x) cannot be differentiable at x = a

Let f and g be differentiable functions satisfying g(a) = b,g' (a) = 2 and fog =I (identity function). then f' (b) is equal to

Let g be the inverse function of f and f'(x)=(x^(10))/(1+x^(2)). If g(2)=a then g'(2) is equal to

f(x)= x + tan x and f is an inverse function of g then g'(x)= ……..

f(x)= x + tan x and f is an inverse function of g then g'(x)= ……..

If f(x)= int_(0)^(x)(f(t))^(2) dt, f:R rarr R be differentiable function and f(g(x)) is differentiable at x=a , then

Let f be a differentiable function satisfying [f(x)]^(n)=f(nx)" for all "x inR. Then, f'(x)f(nx)

Let alpha in R . prove that a function f: R-R is differentiable at alpha if and only if there is a function g:R-R which is continuous at alpha and satisfies f (x) -f(alpha) = g (x) (x-alpha), AA x in R.

Let f(x) = ||x|-1|, then points where, f(x) is not differentiable is/are