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Let $x_1=0 $ and for all n, $x_{n+1}$=$\sqrt{2+x_n}$

a)Prove: $x_n <2$

b)Prove: $x_{n+1} > x_n$

I made it through part a painlessly, however, b is giving me problems

Part a: If $ x_k<2 $ then $ x_{k+1}<2$

Attempt: $x_k+2<2+2$



$x_{k+1}<2$ substitution from initial statement

Part b: Prove: $x_{n+1} > x_n$

Scratch work: $x_{k+1}$=$\sqrt{2+x_k}$ using algebra


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Talk about "race condition" :-) – Asaf Karagila Oct 15 '11 at 23:59
arete: Are you sure $x_{n+1}<x_n$ and not $x_n<x_{n+1}$? – Asaf Karagila Oct 16 '11 at 0:01
arete: the race condition comment was about me and Arturo making the same edit at the same time. Nothing about the contents of your question. – Asaf Karagila Oct 16 '11 at 0:11
+1 for showing what you’ve done. – Brian M. Scott Oct 16 '11 at 0:24
up vote 1 down vote accepted

You can get parts (a) and (b) with a single induction.

By definition $x_1=0$ and $x_2=\sqrt{2+x_1}=\sqrt2$, so $0\le x_1<x_2<2$. Now assume that $0\le x_n<x_{n+1}<2$ for some $n\in\mathbb{Z}^+$. Then $$2<2+x_n<2+x_{n+1}<4\;,$$ so $$\sqrt2<\sqrt{2+x_n}<\sqrt{2+x_{n+1}}<2\;.\tag{1}$$ But $\sqrt{2+x_n}=x_{n+1}$, and $\sqrt{2+x_{n+1}}=x_{n+2}$, so $(1)$ immediately implies that $$0\le x_{n+1}<x_{n+2}<2\;,$$ and it follows by induction that $0\le x_n<x_{n+1}<2$ for all $n\in\mathbb{Z}^+$.

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