We model a geometrically nonlinear rotating two-degree-of-freedom cantilever cutout beam in a vertical plane and exploit the influence of nonlinear behavior on frequency responses and stability of the beam. A theoretical model is developed and verified with the experimental results. First, Newton's second law along with nonlinear boundary conditions is used to establish the governing equation for a single rotating beam in the vertical plane. The Galerkin’s discretization scheme is used to separate the spatial and temporal variables. The normalization conditions are determined and used to derive the equation of motion. The nonlinearity is taken up to the cubic term. It can be observed that the equation of motion is a Mathieu’s equation with the geometric nonlinear terms. Next, the perturbation method is used to obtain an approximate analytical solution near the resonance frequency. This solution can be used to study the influence of each parameter on the amplitude of the overall system. Second, continued with the above-mentioned single-degree-of-freedom rotating beam, we further established and the model of the vibration of the two-degree-of-freedom rotating cutout beam in a vertical plane. The centrifugal force is examined to see its influence on thenatural frequency of the beam installed in different orientations. The hardening or softening phenomenon due to geometric nonlinearity from rotating environment are then discussed. Third, a piezoelectric layer is attached on the two-degree-of-freedom cutout beam. The base-excitation and the sweeping tests of the rotating environment are carried out respectively to observe the voltage responses., The waveforms at specific driving frequencies are also investigated. Finally, we compare the model with the experiment results and discuss the possible causes of the errors.