This study established a model to predict the probability of unmanned aerial vehicle (UAV) crash and conduct ground risk assessment. The greater availability and simpler operation of UAVs compared with manned aerial vehicles have contributed to their growing prevalence and extensive applications among the public. However, the ability of UAVs to fly at low altitudes and the rapidly growing number of UAVs both contribute greatly to the increase in ground risk. Most studies have discussed the effect of few factors on ground risk. To address this research gap, this study conducted a comprehensive and systematic review of relevant literature and accounted for crash probability, UAV impact, and population density in ground risk assessment. Reasons of UAV crashes may concern human operation, wind resistance of UAVs, wind conditions, energy loss during flight, satellite navigation problems, and lost communication due to electromagnetic interference. Accordingly, relevant literature findings, data, equations, and machine learning techniques were employed to establish five crash probability submodels, which were individually based on human operation, wind resistance, energy loss, satellite navigation, or electromagnetic interference. Prediction results obtained from the random forest regression algorithm and deep neural network algorithm were compared to identify the optimal machine learning model. Ground risk attributed to UAV operation per km2 was calculated based on population density and mortality and injuries due to UAV impact. The results verified that the deep neural network model yielded more accurate prediction results through constant update, thereby more closely reflecting real-world situations compared with the random forest model. In sum, the construction of a UAV flight management system enables the collection of immense real-world data, which can be used to create a data-driven ground risk assessment system and thereby provide referential data for regulatory decision-making, flight route planning, and ground risk mapping.