Question

Suppose \(A \subset \mathbb{R}^n\) is an open connected set, we want to prove that given a point \(p \in A\) for any \(x \in A\) there is a broken-line path from \(x\) to \(p\). I propose a solution below. Please comment on it.

Answer 1

Step 1)
First we show that given \(p \in A\) the set, \(P\), of all \(x \in A\) such that there is a broken-line path between \(p\) and \(x\) is open. So we need to show that if for some \(x\) there is a broken-line path between \(x\) and \(p\), then there exists some epsilon ball \(B_{\varepsilon}(x) \subset P\). This is easy to see. Since \(A\) is open there is certainly a ball \(B_{\varepsilon}(x) \subset A\). So we must show that every point in the ball is also broken-line connected to \(p\). Since we already know there is a broken-line path from \(p\) to \(x\) we can simply add a line segment from \(x\) to any point in the sphere. So if \(B_{\varepsilon}(x) \subset A\) then \(B_{\varepsilon}(x) \subset P\). Therefore \(P\) is open.

Step 2)
We prove the contrapositive. Let \(A\) be open, take some \(p \in A\) and consider the set \(P\) consisting of all \(x \in A\) such that there is a broken-line path between \(p\) and \(x\). We show that if there exists some \(y \in A\) where \(y \not\in P\) then \(A\) is disconnected. To prove this we show that \(Q = A - P\) is open, since then there would be open disjoint sets \(P \cup Q = A\). So consider some \(y \in Q\) we show there is a ball \(B_{\varepsilon}(y) \subset Q\). Suppose there wasn't such a ball. That would mean for every ball \(B_{\varepsilon}(y)\) there is some point in the ball that is broken-line path connected to \(p\) but then there would be line segment from that point to \(y\). So then \(y\) would be broken-line path connected to \(p\) contradicting our initial assumption. Since there is such a ball \(Q\) is open. So we have disjoint open \(P, Q\) such that \(P \cup Q = A\). So \(A\) is disconnected

Answer 2

Sorry I had to make corrections for minor typos.

Answer 3

Tbh this looks like another language to me can you explain it differently please

Answer 4

That would be a bit difficult. Unless the reader has some familiarity with topology on \(\mathbb{R}^n\) these concepts are difficult to express.

Answer 5

You can start here perhaps: http://en.wikipedia.org/wiki/Connected_space

Answer 6

okay i think i got it is the answer 15.67