We will define the moduli functor in this post. So, a moduli space is a space (a scheme or a variety) whose points are in natural bijection with the isomorphism classes of families of objects (algebro-geometric objects such as those mentioned above). The meaning of 'space' depends on the context. Let us understand the meaning of the natural bijection. We need a functorial viewpoint here, and the Yoneda lemma would be handy. In algebraic geometry, we usually study objects over a base scheme $S$. But what about the objects under a base change? Hence, the language of functors.

A moduli functor is a contravariant functor $$F: \text{Sch}^{\text{op}} \to \text{Set}$$ which assigns to each scheme $S$ the set of isomorphism classes of families of objects over $S$, where for a map $f: S \to T$, we have $F(f): F(T) \to F(S)$ which is the pullback map from a family of objects over $T$ to $S$. So the moduli functor will retain the classification problem under a base change.

Recall that we say that a contravariant functor $F: \mathcal{C}^{\text{op}}$ is representable by an object $X$ if there is a natural isomorphism $$\xi: F \to h_X$$ where $h_X$ is the functor of points associated to $X$. Now, whenever a functor $F: \text{Sch}^{\text{op}} \to \text{Set}$ is representable by a scheme $M$, such that $\xi: F \to h_M$ and $h_M(S) = Hom(S,M)$, then we call $M$ a fine moduli space. There is also a universal family on the scheme $S$ such that its pullback recovers all the families in $\mathcal{C}$. But we do not always get a fine moduli space and a universal family (the family of objects in $M$ for $id: M \to M$). In other cases, we may get a coarse moduli space. Furthermore, representability by a scheme can fail if the objects have nontrivial automorphism groups; then we move to a moduli stack (hopefully in the next post).

A very good example of representability in moduli theory is the Grassmannian. Grassmannian is used to classify the k-dimensional linear subspaces of an n-dimensional vector space. But in algebraic geometry, we are looking for families of objects over a base scheme $S$. We have a functor $$G(k,n): \text{Sch}^{\text{op}} \to \text{Set}$$ such that $G(k,n)$ associates to scheme $S$ the set $G(k,n)(S)$ of isomorphism classes of surjections $q: \mathcal{O}^{\oplus n}_S \to \mathcal{Q}$ where $Q$ is locally free $\mathcal{O}_S$-module of rank $n-k$. So, $\mathcal{Q}$ is locally free of rank $n$, but the quotient must be locally free of rank $n-k$. There is also a notion pullback here. So it is a moduli functor. In fact, it is representable by the Grassmannian scheme (making it a fine moduli space). There is a generalization of the Grassmannian moduli functor by Grothendieck (see here) in the construction of the Hilbert and Quot schemes.