Tuned Mass Damper (TMD) is one of well-known passive control systems that can effectively reduce structural responses under seismic excitations. However, due to the high fundamental frequency in low-rise buildings, the allowable displacement is insufficient to accommodate excessive responses during severe earthquakes. In addition, the functionality of a single tuned mass damper is limited to tune an individual frequency, leading to overestimated performance while variation of stiffness occurs. Therefore, an innovative passive control system, entitled “Dual-length Nonlinear Pendulum”, is proposed in this study. This pendulum can provide variable resonances during swinging and result in an applicable frequency range. By means of a specific stopper, the length of a pendulum can be suddenly changed to a short one and yield a high-frequency resonance. Then, the energy from earthquakes is more effectively transferred to high frequencies, and the structural responses can be quickly damped out. Therefore, a pendulum with a stopper has higher capability of mitigating structural responses during severe to extreme earthquake events. In this study, the dual-length nonlinear pendulum is developed and experimentally verified for a seismically-excited model building. First, the numerical model of this nonlinear pendulum is established to understand the dynamic behavior and control performance. A series of parametric studies are carried out to explore the effectiveness and functionality of this nonlinear pendulum for a low-rise building (e.g., with a relatively high fundamental frequency). These studies include the instantaneous natural frequency and mode shapes with respect to positions, frequency-domain amplitudes under harmonic excitation, frequency content due to impulsive loads, energy distributions during earthquakes, and seismic performance. Then, a design example is provided in accordance with the parametric studies, and the dual lengths of the nonlinear pendulum are to tune the first and second natural frequencies of a building. Seismic performance of the building with the optimally designed nonlinear pendulum is also numerically evaluated. Moreover, a two-story, shear-type model building is fabricated to experimentally investigate and verify seismic performance of the proposed dual-length nonlinear pendulum. During the test, records from 1999 Chi-Chi earthquake are considered as the ground excitation. Performance of the nonlinear pendulum is also compared to the uncontrolled bare frame building and the building with a tuned mass damper. This nonlinear pendulum exhibits a high ability to reduce structural responses during relatively large earthquakes. As seen in the experimental results, the proposed dual-length nonlinear pendulum has higher performance than the conventional tuned mass damper, in particular when structural degradation occurs or seismic intensity becomes large.