The question is:
$0\leq\alpha\leq \frac{1}{4}$, We'll define $a_1=\alpha$, $a_{n+1}=\alpha+a_n^2$. Prove $(a_n)_{n=1}^\infty$ is converging and find it's limit.
I'm really confused about it, so I tried taking the private case of $\alpha=\frac{1}{4}$ but I still don't really understand it.
$a_1=\frac{1}{4}$
$a_2=\frac{5}{16}$
$a_3=\frac{89}{256}$
And I'm not really sure where this is going to or what I'm supposed to do with it.
Well, there is a way that often works on problems like this. First, suppose that the sequence does converge and find its limit. Hint: if $(a_n) \to x$, then $x = \frac{1}{4} + x^2$.
Next, when you've found the supposed limit value $x$, you'll just need to prove that $a_n - x \to 0$, and the problem will be solved. In the actual solution you can even omit the part where you determine the value of $x$. You can just say out of the blue something like "Let's show that $(a_n)$ converges to <here you name the limit>", and then go on proving that $a_n - x \to 0$. This looks cool and makes people think that you've come up with the limit value using your incredible intuition )).
Prove that the sequence is increasing and bounded. Both using induction.
Then find the limit as Dan Shved proposed.
