This study aims at developing the probabilistic rainfall threshold estimation model for shallow landslide (PRTE_SL) by taking into account the uncertainties in the hydrological factors and geographic factors. The hydrological factors serve as rainfall characteristics, including the rainfall duration, depth and storm patterns. The effective cohesion of soil, the unit weight of soil, the angle of internal friction, hydraulic conductivity and hydraulic diffusivity are regarded as the geographic factors. In this study, the framework of developing the PRTE_SL model could be grouped into seven steps: (1) collect the rainfall data of rainstorm events in the study are and extract the associated rainfall characteristics; (2) classify the rainstorm events into various types using the cluster analysis based on the storm pattern; (3) generate the rainfall characteristics, which are composed of the hyetograph, and the parameters of the landslide simulation model (i.e. TRIGRS model) by using the Multivariate Monte Carlo Simulation method; (4) calculate the safety factors by means of TRIGRS model with simulated rainstorms and the TRIGRS parameters; (5) identify the time step of the calculated safety factors less than the critical values (i.e. 1.0, 1.1, 1.12, 1.15, 1.2) (called the failure time) and then accumulate the rainfall amount (named the rainfall threshold) for different early warning time (1hr, 3hr, 6hr, 12hr, 24hr, 48hr, 72hr). The early warning time stands for the period between the current time and the failure time; (6) establish a relationship between the rainfall thresholds and the aforementioned the rainfall factors (i.e rainfall depth and maximum rainfall intensity) and TRIGRS parameters using the multivariate regression analysis. In referring to the coefficients of uncertainty factors, the rainfall thresholds are sensitive to the rainfall the maximum rainfall intensity, effective cohesion of soil, the unit weight of soil, and the angle of internal friction, which are defined as major uncertainty factors; and (7) calculate the exceedance probability of rainfall threshold rainfall by Advanced First-Order Second-Moment (AFOSM) method with the rainfall estimation equation derived at the step 7 under various early-warning times and critical safety factors; and (8) derive the relationship between the exceedance probability and corresponding the rainfall thresholds, the early-warning times and critical safety factors, named the equation of calculating the exceedance probability of rainfall thresholds. In summary, the proposed PRTE_SL model involves two equations. One is the threshold estimation equation with early-warning times, maximum rainfall intensity and TRIGRS parameters of interest for various critical safety factors; and the other is the exceedance probability calculation equation with the rainfall thresholds, critical safety factors, and early-warning times considered. As a result, the PRTE_SL is expected to provide the rainfall thresholds in association with its reliability under a specific early-warning time and the critical safety factors given. The Jhuokou river watershed is chosen as the study area, and corresponding hourly rainfall data of 1,111 rainstorm events recorded from 1967-2013 at Dona gauge are used in the model development and applicability evaluation. In advance, 1,111 rainfall events are classified into four types: advanced, center, uniform and delayed types. Then, this study sets up the TRIGRS parameters for the study area Jhuokou River watershed based on the investigation of landslide data from Typhoons Mindulle, Haitang and Morakot. After that, 4000 simulated rainstorm events and TRIGRS parameters are used for developing the PRTE_SL by means of the uncertainty method (AFOSM) and logistic regression analysis. In this study, the assumption of the rainfall thresholds based on the issued thresholds by the Soil and Water Conservation Bureau are applied to demonstrate the applicability of the proposed PRTE_SL model in the reliability assessment of the rainfall thresholds of interest. The results indicate the original announced rainfall thresholds occur within 24 hours as the safety factors are less than critical values. In average, the corresponding underestimated risk approximates 10%, and this implies that the reliability of issued safety factors reach 90%. However, the issued rainfall thresholds with high reliability might hardly achieve the goal of early warning. This is because the shallow landslide has possibly taken place before the actual rainfall amount exceeds the threshold. The proposed PRTE_SL model can provide the estimation of the rainfall threshold with the specific occurrence probability (named as the probabilistic rainfall threshold) for various critical safety factors and early-warning times. Therefore, the proposed PRTE_SL can not only quantify the reliability of the rainfall thresholds, but also provide the probabilistic rainfall thresholds referred to modify the announced thresholds.