Calculuser said:
The first question's solution:
[itex]f(x)=cos(e^{-x})[/itex]
If we take [itex]lim_{x\rightarrow+∞}cos(e^{-x})\approx1[/itex]. However if we take [itex]lim_{x\rightarrow-∞}cos(e^{-x})[/itex] the function takes values on closed interval -1 and 1 [itex]\left[-1,1\right][/itex]. That's why we can easily say that [itex]f:ℝ\rightarrow\left[-1,1\right][/itex].
Limits? Why would you care about limits? The question is about the function and its values on its defined domain, not about the values of some hypothetical extension onto some hypothetical extended domain that includes plus or minus infinity.
What is an inverse of f(x) = [itex]cos(e^{-x})[/itex]?
It's a fairly easy inverse to define -- at least symbolically.
The inverse of cos is arccos.
The inverse of e^x is log
The inverse of - is -
Now you only have the problem of taking the log of a number that may not be strictly positive. But that can be dealt with.
HINT: The inverse of cos is multi-valued. You can pick which inverse you want.
Second one:
[itex]g(x)=\left|2x-1\right|/sin(\frac{\pi}{2}x-\pi)[/itex]
For this function denominator can not be zero [itex]sin(\frac{\pi}{2}x-\pi)\neq0[/itex] So that, we have to except the such x values [itex]x=\left\{x:x=2k,k\in Z\right\}[/itex] that make it zero. That was easy part. The hard one is to find the set of range of this g(x) function. I'm actually stuck in that. Help for [itex]g:ℝ-\left\{x:x=2k,k\in Z\right\}\rightarrow?[/itex] ??
mfb has given a hint about a problem with the second one. The numerator is non-negative. The denominator is bounded by [-1,1]. The only way to get a small result is for the numerator to be small.
If the numerator is small, what can be said about the denominator? In particular, what is its sign? What does that imply about small values of f(x).
On the bright side, the function is continuous and piecewise differentiable. You are searching for an extremum. If you can enumerate the local extrema and pick out the right ones then perhaps you can find a global extremum in a particular range?
I have not tried to solve the rest of the problem myself. If it's an exercise in a textbook then it ought to be tractable.