Quotient map from $X$ to $Y$ is continuous and surjective with a property : $f^{-1}(U)$ is open in $X$ iff $U$ is open in $Y$.
But when it is open map? What condition need?
Quotient map from $X$ to $Y$ is continuous and surjective with a property : $f^{-1}(U)$ is open in $X$ iff $U$ is open in $Y$.
But when it is open map? What condition need?
The definition of a quotient space:
A topological space $(Y,U)$ is called a quotient space of $(X,T)$ if there exists an equivalence relation $R$ on $X$ so that $(Y,U)$ is homeomorphic to $(X/R,T/R)$.
This definition is equivalent to:
$ (Y,U) $ is a quotient space of $(X,T)$ if and only if there exists a final surjective mapping $f: X \rightarrow Y$.
The previous statement says that $f$ should be final, which means that $U $ is the topology induced by the final structure,
$ U = \{A \subset Y | f^{-1}(A) \in T \} $
This is the largest collection that makes the mapping continuous, which is equivalently stated in your definition with the "if and only if" statement.
However, if the map is open:
If $f: X \rightarrow Y$ is a continuous open surjective map, then it is a quotient map.
Note that this also holds for closed maps. So in the case of open (or closed) the "if and only if" part is not necessary. If $f^{-1}(A)$ is open in $X$, then by using surjectivity of the map $f (f^{-1}(A))=A$ is open since the map is open. And the other side of the "if and only if" follows from continuity of the map.