The objective of this study is to explore the feasibility of using covariance-based subspace system identification method under output-only conditions as well as the recursive stochastic subspace system identification method under a deterministic-stochastic model for bridges. In this thesis, a concrete arch bridge is considered as the object. Both traffic load and earthquake are considered as the input excitations. Traffic load is simulated as point loads moving consecutively at a specified time lag in a constant speed on the bridge. As the traffic load cannot be measured in reality, only the SSI-COV method was adopted for analysis. The bi-directional El Centro earthquake records were used as the seismic inputs. Since the ground accelerations are measurable in practical applications, the R4SID method was adopted in this study in addition to the SSI-COV method. Simulation results indicate that the frequencies, mode shapes and damping ratios of the bridge for a certain predominant modes can be identified using SSI-COV under traffic load, regardless of the health conditions of the bridge. Under seismic load, the frequencies, mode shapes and damping ratios of the bridge for a certain predominant modes can also be identified using both the R4SID and SSI-COV, with SSI-COV being less accurate in predicting the mode shapes and damping. Under the considered pattern of traffic load, the identified results of the structural modes primarily in vertical (Z) direction by SSI-COV are equivalent to those under earthquake load by R4SID. The mode shapes related to the transverse (Y) directions thus identified, however, are less accurate. Moreover, the frequencies and mode shapes of predominant modes of the bridge are found barely changed when locally damaged. Therefore, they are not sufficient as indicators for damage detection of bridge structures.