In this research, we established a non-resonant acoustic levitation system. We also discussed the effects of thicknesses, areas, densities, and shapes of planar objects on the difficulty of levitation. The experimental results show that sound pressure required to levitate the objects increases as their thicknesses or densities increase. As for the objects’ areas, the difficulty of levitation decreases with the increasing areas of the objects when the areas are lower than a critical value. Otherwise, the larger the areas of the objects are, the harder they are to be levitated. We defined a shape factor by results of sound field measurement. This factor can describe the extent of acoustic radiation forces that the objects received in the same sound field. Then we got the area formula and the shape formula by curve fitting. However, the prediction of the shape formula is contrary to the experimental data for the objects of low areas. We thought it is because the sound field inside the levitator was not axisymmetric and the centroids of the levitated objects were not located on the central axis of the levitator. Finally, by the area formula and the shape formula, we predicted the sound pressure required to levitate a sphere or an ellipsoid of arbitrary density.