We are looking for two classes of subsets $A$ of $(\mathbb{Q},+)$ such that:
Class 1):
(i) $1\in A$
(ii) $A-A\neq \mathbb{Q}$ but $(A-A)+\cdots +(A-A)=\mathbb{Q}$ (i.e., some finite sumation of $A-A$ is equal to $\mathbb{Q}$)
(iii) $A$ is neither co-finite nor bounded (i.e., $\mathbb{Q}\setminus A$ is an infinite set and $A$ is unbounded)
Class 2):
(i) $1\in A$
(ii) $(A-A)+\cdots +(A-A)\neq \mathbb{Q}$ (i.e., every finite sumation of $A-A$ is not equal to $\mathbb{Q}$)
(iii) $\langle A\rangle=\mathbb{Q}$
(iv) $A$ is neither co-finite nor bounded
Note that $A-A:=\{ a-\alpha:a,\alpha\in A\}$ and $B_1+\cdots +B_k:=\{ b_1+\cdots + b_k:b_1,\cdots,b_k\in B\}$. It is interesting to know that for every subset $A$, either a finite summation $(A-A)+\cdots +(A-A)$ or the infinite summation $(A-A)+(A-A)\cdots$ is a subgroup of $\mathbb{Q}$. Also, all $A$ from both classes are generating sets of $(\mathbb{Q},+)$.
One can find more information in this and this.
Can one give some explicit forms (or examples) of subsets $A$ of Class 1 and Class 2?
Thank you so much for your attention and participation.