Rainfall-triggered shallow landslide is one of the major natural disasters over the world which may immediately cause large numbers of casualties and huge economic losses. To mitigate the landslide disasters, the numerical model simulations based on the infinite slope theory have been widely applied to predict the slope stability during a rainfall event. However, due to the inherent heterogeneity and lack of complete information about model input variables, uncertainties exist in specifying the values of these variables in the numerical model rendering potential failure to obtain the authentic model output (safety factor, FS) for the slope under consideration. In this study, three approximated uncertainty analysis methods, including the first-order second-moment (FOSM), Rosenblueth’s point estimation (R-PE), and Li’s point estimation (LI-PE) were utilized with the developed rainfall triggered shallow landslide model (Tsai and Yang, 2006) to obtain the statistical properties of FS and the landslide probability (Pf) at the Salunzai slope during typhoon Aere. Besides, the relative errors of computed Pf with respect to Monte Carlo simulation (MCS) result were compared. Six stochastic model input variables, including the saturated hydraulic conductivity (Ksat), friction angle (), cohesion (c), initial groundwater depth (dZ), soil thickness (dLZ), and slope (α) were considered. Moreover, six cases involving different uncertainty levels of slope angle and soil thickness were considered. The results showed that each of the three approximated methods has its own advantages and drawbacks for the uncertainty analysis of rainfall triggered shallow landslide model. The performances of the approximated uncertainty analysis methods were evaluated through three criteria including: (1) accuracy; (2) efficiency; and (3) prior information requirements. For the accuracy of the approximated methods, the differences in obtained landslide probability between the point estimation (Rosenblueth’s and Li’s) and MCS are minimal in all of the six cases. However, the FOSM method tends to significantly overestimate the landslide probability especially in the case with higher model inputs uncertainties. In contrast to accuracy, the FOSM method has highest computational efficiency because the required number of numerical model evaluation in one simulation grid is 9, while the Rosenblueth’s and Li’s point estimation methods require 16 and 15 model evaluations, respectively. In view of the prior information requirement, the FOSM method only requires the first two moments of the stochastic model input variables while the Rosenblueth’s and Li’s point estimation methods require the first three and four moments of model inputs, respectively. In summary, the applicability of the three approximated uncertainty analysis methods for rainfall-triggered shallow landslide model depend on the space scale of the application. For the estimation of the distributions of the landslide probabilities within a watershed, the third and fourth moments of stochastic model inputs might not be reliably obtained, besides, the amounts of simulation grids might be huge, thus the FOSM method is more applicable than the Rosenblueth’s and Li’s point estimation methods. In contrast, for the estimation of landslide probability at a specified slope, the third and fourth moments of stochastic model inputs might be reliably through a more comprehensive field investigation, thus the Rosenblueth’s and Li’s point estimation methods are more applicable due to the higher accuracy.