In recent years, serious flooding in areas near the river due to river embankment overflowing is increasing. To promote disaster prevention and protection for the whole river basin, a fast and accurate inundation simulation model is required. The existed National Taiwan University cellular automata flood inundation model (NTU-CAFIM model) can fastly and accurately provide a prediction of flooding in urban areas, thus it is appropriate to be coupled with the 1D unsteady river flow model to provide real-time forecasting of flooding in the river basin. In this study, the 1D unsteady river flow model (RFM) is coupled with the NTU-CAFIM model (OFM), so that water can be dynamically exchanged through embankments of each river reach. Rules to describe exchanged water are developed for coupling the RFM and OFM, including the correspondence of different spatial resolutions between riverbank cells in the OFM and river reaches in the RFM, and the calculation of exchanged volume between riverbank cells in the OFM and river reaches in the RFM. In particular, the exchanged volume between the RFM and OFM through embankments along each river is calculated by either free or submerged weir flow formulas. To verify the water exchanging rules in this study, two case studies are selected, and the coupled model is compared with the HEC-RAS model by indicators such as Nash-Sutcliffe efficiency (NSE), accuracy (ACC), and sensitivity (TPR). Based on the simulation results of a small-scale ideal case and the case of the Severn River Basin in the United Kingdom with an area of 24km2 and actual complex terrains. The simulation results of the coupled model in the hydrographs of water level in river sections, the hydrographs of flow rate in river sections, the hydrographs of water levels in two-dimensional overland flow, the hydrographs of water overflowing, and the maximum flooding area are very similar with the HEC-RAS model. Furthermore, in the ideal case and the real case of the Severn River Basin, the coupled model is 47% and 41% faster than the HEC-RAS model. The above results indicate that the coupled model is as accurate as the HEC-RAS model with a significant reduction in its computational time. Hence, it is concluded that the coupled model has considerable potential to be applied to real-time simulation of flooding in the river basin.