{"citation":{"ieee":"M. Griese, S. D. Mousavi, and T. Schulte, <i>Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle</i>. IEEE, 2021, pp. 205–210.","short":"M. Griese, S.D. Mousavi, T. Schulte, Modeling the Vertical Dynamics of a Self-Stabilizing Monorail Vehicle, IEEE, 2021.","ufg":"<b>Griese, Martin et. al. (2021)</b>: Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle.","bjps":"<b>Griese M, Mousavi SD and Schulte T</b> (2021) <i>Modeling the Vertical Dynamics of a Self-Stabilizing Monorail Vehicle</i>. IEEE.","mla":"Griese, Martin, et al. “Modeling the Vertical Dynamics of a Self-Stabilizing Monorail Vehicle.” <i>2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)</i>, IEEE, 2021, pp. 205–10, doi:<a href=\"https://doi.org/10.1109/ICCMA54375.2021.9646219\">10.1109/ICCMA54375.2021.9646219</a>.","van":"Griese M, Mousavi SD, Schulte T. Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle. 2021 9th International Conference on Control, Mechatronics and Automation (ICCMA). IEEE; 2021.","havard":"M. Griese, S.D. Mousavi, T. Schulte, Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle, IEEE, 2021.","din1505-2-1":"<span style=\"font-variant:small-caps;\">Griese, Martin</span> ; <span style=\"font-variant:small-caps;\">Mousavi, Seyed Davood</span> ; <span style=\"font-variant:small-caps;\">Schulte, Thomas</span>: <i>Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle</i> : IEEE, 2021","chicago-de":"Griese, Martin, Seyed Davood Mousavi und Thomas Schulte. 2021. <i>Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle</i>. <i>2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)</i>. IEEE. doi:<a href=\"https://doi.org/10.1109/ICCMA54375.2021.9646219,\">10.1109/ICCMA54375.2021.9646219,</a> .","apa":"Griese, M., Mousavi, S. D., &#38; Schulte, T. (2021). <i>Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle</i>. <i>2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)</i> (pp. 205–210). Belval, Luxembourg : IEEE. <a href=\"https://doi.org/10.1109/ICCMA54375.2021.9646219\">https://doi.org/10.1109/ICCMA54375.2021.9646219</a>","ama":"Griese M, Mousavi SD, Schulte T. <i>Modeling the Vertical Dynamics of a Self-Stabilizing Monorail Vehicle</i>. IEEE; 2021:205-210. doi:<a href=\"https://doi.org/10.1109/ICCMA54375.2021.9646219\">10.1109/ICCMA54375.2021.9646219</a>","chicago":"Griese, Martin, Seyed Davood Mousavi, and Thomas Schulte. <i>Modeling the Vertical Dynamics of a Self-Stabilizing Monorail Vehicle</i>. <i>2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)</i>. IEEE, 2021. <a href=\"https://doi.org/10.1109/ICCMA54375.2021.9646219\">https://doi.org/10.1109/ICCMA54375.2021.9646219</a>."},"publication_identifier":{"eisbn":["978-1-6654-1073-1"]},"keyword":["Vehicle dynamics","Control moment gyroscope","Control system analysis","Roll stabilization","Monorail vehicles"],"publisher":"IEEE","language":[{"iso":"eng"}],"author":[{"first_name":"Martin","id":"52308","full_name":"Griese, Martin","last_name":"Griese"},{"id":"79148","full_name":"Mousavi, Seyed Davood","last_name":"Mousavi","first_name":"Seyed Davood"},{"id":"46242","last_name":"Schulte","full_name":"Schulte, Thomas","first_name":"Thomas"}],"publication_status":"published","user_id":"56955","title":"Modeling the Vertical Dynamics of a Self-stabilizing Monorail Vehicle","publication":"2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)","department":[{"_id":"DEP6020"},{"_id":"DEP5022"}],"page":"205-210","date_updated":"2023-03-15T13:50:15Z","year":2021,"date_created":"2022-06-22T14:22:07Z","conference":{"name":"2021 9th International Conference on Control, Mechatronics and Automation (ICCMA)","end_date":"2021-11-14","location":"Belval, Luxembourg ","start_date":"2021-11-11"},"doi":"10.1109/ICCMA54375.2021.9646219","status":"public","type":"conference_editor_article","_id":"8385","abstract":[{"text":"Currently, numerous single-track railway lines are disused due to economic reasons. However, they could be reactivated for a bidirectional on-demand service traffic by small vehicles that use only one rail. MonoCabs are such small cabin-like vehicles, stabilized by a system of control moment gyroscopes and a moveable mass. They could make an important contribution to improve the mobility offer especially in rural areas. This paper focuses on the analytical modeling and vertical stabilization system of the MonoCab. A nonlinear dynamic model is obtained using the Lagrangian method and subsequently linearized about its equilibrium point. Which is used for the design of the cascade control system. The dynamic analysis of the system is accomplished by comparing between analytically derived model in simulink environment and same structured model in simscape multibody. This system is discussed based on a physical three body model which describes the rolling motion of the vehicle, the lateral motion of the mass and the precession motion of the gyroscope. The model is utilized for a cascaded control concept adjusting the vehicle’s roll angle and gyroscope’s precession angle. The proposed stabilization concept is capable of compensating both high dynamic disturbances and stationary disturbances (e. g. unbalanced loads and steady wind flows). The concept is analyzed by simulations and experimental investigations. Beside transient command responses also the frequency response of the system is experimentally evaluated and used for a validation of the model and theoretical findings. For the experimental validation, a small scaled test rig is used which consists of mechanical frames and flywheels, inverter-fed drives, rotary encoders, an inertial measurement unit (IMU) and a rapid control prototyping system.","lang":"eng"}]}