If `phi(x)` is a differential real-valued function satisfying `phi'(x)+2phi(x)le1,` then the value of `2phi(x)` is always less than or equal to …….

If phi(x) is a diferential real-valuted function satisfying phi'(x)+2phi(x)le1. prove that phi(x)-(1)/(2) is a non-incerasing function of x.

Find the period of the real-valued function satisfying f(x)+f(x+4)=f(x+2)+f(x+6).

If d/(dx)(phi(x))=f(x) , then

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

If tan theta=1/2 and tan phi=1/3 , then the value of (theta + phi) is :

Let g\ :[1,6]->[0,\ ) be a real valued differentiable function satisfying g^(prime)(x)=2/(x+g(x)) and g(1)=0, then the maximum value of g cannot exceed

Value of x, satisfying x^2 + 2x = -1 is :

If f is a real valued differentiable function satisfying | f (x) - f (y) | le (x - y) ^(2) for all real x and y and f (0) =0 then f (1) equals :

For x in R , the functions f(x) satisfies 2f(x)+f(1-x)=x^(2) . The value of f(4) is equal to

There exists a positive real number of x satisfying "cos"(tan^(-1)x)=xdot Then the value of cos^(-1)((x^2)/2)i s