Let `f : R rarr R` be a defferentiable function such that `f(0) = 0 , f(pi/2) = 3`, and `f'(0) = 1`. If
`g(x) = int_(x)^(pi/2)[f'(t)cosect-cott cosect f(t)]dt` for `x in (0, pi/2]` then `lim_(x rarr 0) g(x) = `

Let f:R rarr R be a differentiable function such that f(0)=0,f(((pi)/(2)))=3 and f'(0)=1 If g(x)=int_(x)^((pi)/(2))[f'(t)cos ect-cot t cos ectf(t)]dt for x in(0,(pi)/(2)] then lim_(x rarr0)g(x)=

Let f:R rarr R be a differentiable function such that f(0),f((pi)/(2))=3 and f'(0)=1. If g(x)=int_(x)^((pi)/(2))[f'(t)csc t-cot t csc tf(t)]dt for x in(0,(pi)/(2)] then lim_(x rarr0)g(x)=

Let f:R rarr R be a differentiable and strictly decreasing function such that f(0)=1 and f(1)=0. For x in R, let F(x)=int_(0)^(x)(t-2)f(t)dt

Let f:R rarr R be a twice differentiable function such that f(x+pi)=f(x) and f'(x)+f(x)>=0 for all x in R. show that f(x)>=0 for all x in R .

If f'(x)=f(x) and f(0)=1 then lim_(x rarr0)(f(x)-1)/(x)=

f(x)=e^x then lim_(x rarr 0) f(f(x))^(1/{f(x)} is

Let f:R rarr R be a differentiable function such that its derivative f 'is continuous and f(pi)=-6. If F:[0,1]rarr R is defined by F(x)=int_(0)^(x)f(t)dt and if int(f'(x)+F(x))cos xdx=2 ,then the value of f(0) is

Let f:R rarr[0,oo) be a differentiable function so that f'(x) is continuous function then int((f(x)-f'(x))e^(x))/((e^(x)+f(x))^(2))dx is equal to

Let R to R be a differentiable functions such that its derivative f' is continuous and f(pi) = - 6 . If F : [0,pi] to R is defined by F(x) int_(0)^(x) f(t) dt , and int_(0)^(x) f(t) dt and if int_(0)^(pi) (f'(x) +F(x))cos xdx = 2 then the value of f(0) is _________