Consider the equivalence relation $‘∼’ $on R × [0, 1] defined by $(x, t) ∼ (x + 1, t), x ∈ R$ and$ t ∈ [0, 1].$ Let $X =(R × [0, 1])/ ∼$ be the quotient space.
Prove that X is Hausdorff and compact.
i was thinking that ,If the quotient map is open, then $X/ \sim$ is a Hausdorff space if and only if $\sim$ is a closed subset of the product space $[0,1]\times X$.
as im very weak in topology and im newly learning topology
pliz help me
Let $f:\mathbb R\times[0,1]\to S^1\times[0,1]$ be prescribed by:$$\langle x,t\rangle\mapsto\langle\langle\cos2\pi x,\sin2\pi x\rangle,t\rangle$$
Then $f$ is continuous and surjective.
Further it can be shown that $f$ is a closed map, hence $f$ is a quotient map.
If $q:\mathbb R\times[0,1]\to X$ denotes the quotient map then it can be shown that $f$ and $q$ respect each other in the sense that $f(x,t)=f(y,s)\iff q(x,t)=q(y,s)$.
Based on these facts it can be shown that $X$ and $S^1\times[0,1]$ are homeomorphic, so it remains to prove now that $S^1\times[0,1]$ is compact and Hausdorff.