The long-span arch bridges have been a favorable choice for the design of pedestrian bridges during the past decades in Taiwan. This is because the type of bridges not only can satisfy the transportation needs but also may become the landmark in the local area. In these pedestrian bridges, a single arch is the only choice due to the narrow bridge deck. Since the single arch lacks lateral support and its height increases with the bridge span length, the drag responses in the arch become significant and cannot be negligible. To predict the aerodynamic responses of the arch, the traditional analysis used for cable-stayed and suspension bridges, considering wind forces acting on bridge decks only, cannot be used. In this thesis, an analytical approach based on flutter and buffeting theory associated with the information measured from section model tests is presented. Two examples are used to demonstrate the validity and applicability of this approach and to investigate the effects of the forces acting on the arch on the flutter wind speed and buffeting responses of bridge decks. The results show that the critical flutter wind speeds in these two examples are dominated by the flutter derivatives of bridge decks. The increases of the critical flutter wind speeds considering flutter derivatives of arches are less than 1%. For the buffeting responses, the effects of the forces acting on arches are significant on both drag and torsional responses of arches and bridge decks. In Example 1 incorporating forces acting on the arch into the analysis, the drag and torsional responses of the bridge deck increase 1.9% and 44.1%, respectively. The increases of the drag and torsional responses of the arch are 764% and 792%, respectively. Since the structural coupling between the bridge deck and the arch is minor in this example, the main contribution to the responses of the arch is the forces acting on the arch itself. Therefore, the results with huge increases are expected. In Example 2 incorporating forces acting on the arch into the analysis, the drag and torsional responses of the bridge deck increase 11.99% and 133%, respectively. The increases of the drag and torsional responses of the arch are 57.87% and 64.6%, respectively. In this example, the structural coupling between the bridge deck and the arch is more obvious than in example 1. The effects of the forces acting on the arch on the responses of the arch and the bridge deck are significant. From the results stated above, the forces acting on the arch should be considered in the analysis.