If `f(x)` is continuous and derivable, `AA x in R` and `f'(c)=0` for exactly 2 real value of 'c'. Then the number of real and distinct value of 'd' for which `f(d)=0` can be

Suppose that f(0)=-3 and f'(x)<=5 for all real values of x. Then the largest value of f(2) can attain is

Let f(x)=a^(x)-x ln a,a>1. Then the complete set of real values of x for which f'(x)>0 is

If f(x) is a continuous function such that its value AA x in R is a rational number and f(1)+f(2)=6 , then the value of f(3) is equal to

let f:R rarr R be a continuous function AA x in R and f(x)=5,AA x in irrational. Then the value of f(3) is

If f(x)=x^(3)-3x+1, then the number of distinct real roots of the equation f(f(x))=0 is

Let f (x) is a real valued function defined on R such that f(x) = sqrt(4+sqrt(16x^2 - 8x^3 +x^4)) . The number of integral values of 'k' for which f(x) =k has exactly 2 distinct solutions for k in [0,5] is

If f is real-valued differentiable function such that f(x)f'(x)<0 for all real x, then

If a continous founction of defined on the real line R, assumes positive and negative values in R, then the equation f(x)=0 has a root in R. For example, if it is known that a continuous function f on R is positive at some point and its minimum values is negative, then the equation f(x)=0 has a root in R. Considetr f(x)=ke^(x)-x for all real x where k is real constant. The positive value of k for which ke^(x)-x=0 has only root is

If f(x)=cosx,0lexle(pi)/2 then the real number c of the mean value theorem is