Due to fragile geology, steep topography, and frequent storm events, reservoirs are threaten by sedimentation and dam failure in Taiwan. Moreover, flooding and water supply problems are also related to the same reasons. Therefore, this study develops a model to optimize the reservoir operation to control the flooding damage, increase the water supply, and improve the sediment sluicing efficiency. This model includes four parts: (1) genetic algorithms (GAs), (2) river simulation model, (3) artificial neural network (ANN) model, and (4) reservoir turbidity dynamic model. This developed model is applied to Zengwen Reservoir and is tested using multiple historical storm events. A multi-objective function is adopted. These objectives include flood control, water supply, and sediment sluicing. The weighting coefficients for each objective is also studied and discussed. The results show better operation efficiency in terms of flooding control and sediment sluicing. For example, the maximum river depth is reduced by 1.8m for Typhoon Krosa and flooding is completely avoided for Typhoon Sinlaku. The sluicing sediment increases 33%, which is about 1,130,000 tons, for Typhoon Krosa and increases 25%, which is about 400,000 tons, for Typhoon Sinlaku, respectively. These results show the efficiency and capability of the proposed model.