Faced with rapid changes and a competitive environment, in order for enterprises to maintain their competitiveness, they must ensure a stable supply of products to satisfy fluctuations in market demand. If a good replenishment strategy is built with the Vendor Management Inventory (VMI), it will not only lead to efficient inventory management, but will also reduce the overall system cost and increase operation efficiency. In practice, the inventory level is controlled manually by experienced planning personnel. Consequently, the planning results may not reflect overall optimality. Therefore, in this study, based on the system optimization perspective, we develop the deterministic-demand upper-and-lower inventory level control model, the stochastic-demand upper-and-lower inventory level control model, with the objective of minimizing the total cost, considering the upper-and-lower inventory level control problem and stochastic daily demands. The models are expected to be useful tools for the planner to decide on the optimal upper-and-lower inventory level planning. We employed the mathematical programming and network flow techniques to develop all the models with suitable objective functions and constraints based on the problem characteristics to comply with real operating requirements. These two models are expected to be formulated as integer network flow problems with side constraints, which are characterized as NP-hard. We developed a solution algorithm for each model by adopting a problem decomposition strategy, coupled with the use of the CPLEX software. Finally, case studies and sensitivity analyses are performed the operating data for one supplier and retailers from the chain retailers. Conclusions and suggestions then are given.