Experimental validation of a model of an uncontrolled bicycle

Kooijman, J. D. G.; Schwab, A. L.; Meijaard, J. P.

doi:10.1007/s11044-007-9050-x

Cited by 79 publications

(55 citation statements)

References 8 publications

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“…Both disadvantages may be overcome with more advanced set-ups which cancel out the above-mentioned advantages to some extent due to the higher complexity [5]. Torsion pendulum set-ups are typically used for DUTs with smaller mass moments of inertia [6].…”

Section: Measurement Principles and Realised Set-upsmentioning

confidence: 99%

Comparison of Two Experiments Based on a Physical and a Torsion Pendulum to Determine the Mass Moment of Inertia Including Measurement Uncertainties

Klaus

2017

Measurement Science Review

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To determine the mass-moment-of-inertia properties of devices under test with particularly small mass moments of inertia (some 10 −4 kg m 2 ), two measurement set-ups based on different measurement principles were developed. One set-up is based on a physical pendulum, the second set-up incorporates a torsion pendulum. Both measurement set-ups and their measurement principles are described in detail, including the chosen data acquisition and analysis. Measurement uncertainty estimations according to the Guide to the Expression of Uncertainty in Measurement (GUM) were carried out for both set-ups by applying Monte Carlo simulations. Both set-ups were compared using the same three devices under test. For each measurement result, the measurement uncertainties were estimated. The measurement results are compared in terms of consistency and the resulting measurement uncertainties. For the given devices under test, the torsion pendulum set-up gave results with smaller measurement uncertainties compared to the set-up incorporating a physical pendulum.

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Section: Measurement Principles and Realised Set-upsmentioning

confidence: 99%

Comparison of Two Experiments Based on a Physical and a Torsion Pendulum to Determine the Mass Moment of Inertia Including Measurement Uncertainties

Klaus

2017

Measurement Science Review

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“…The history and state-of-the-art discussions on topic of bicycle dynamics and control were reviewed comprehensively by Schwab and Meijaard [6]. In a study of bicycle stability, Meijaard et al [7] analysed the eigenvalues of a linearized bicycle model that was experimentally validated by Kooijman [8]. Results of these works showed the relationship of the bicycle's stability with its longitudinal speed.…”

Section: Introductionmentioning

confidence: 99%

Design and Implementation of Model Predictive Control for a Gyroscopic Inverted Pendulum

Chu

Chen

2017

Applied Sciences

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This study proposes the design of an active stabilizing system (ASAS) for a single-track vehicle. Using the gyroscopic effects of two flywheels, this system can generate control torque to stabilize the vehicle in cases where there is centrifugal force of turning. To control the flywheel gimbals to generate stabilizing torque, a model predictive controller (MPC) is applied to control the system. For the controller design and performance evaluations, a model of a gyroscopic inverted pendulum is developed. Control strategies are proposed to stabilize the vehicle in the cases of straight running, circular motion, and path following. The results of the proposed stratgies when controlling the gyroscopic inverted pendulum showed good performance even with physical limitations of the control torques. In order to evaluate the real-time performance and the feasibility of the MPC, a real-time simulator is employed, which includes two embedded STM32F407 boards. The dynamic system and the control algorithms are respectively embedded into two STM32F407 boards for real-time simulation. Implementations of the MPC in this study demonstrate that the proposed controllers are feasible for real-time applications.

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“…En este modelo asumen que la bicicleta sólo está constituida por cuatro cuerpos rígidos y obtienen un modelo en espacio de estado con parámetros variantes (LPV), a partir de unas ecuaciones diferenciales de movimiento que provienen del principio de D'Alembert (Whipple, 1899). La validación del anterior modelo se desarrolló en (Kooijman et al, 2008) mediante la adquisición de datos en tiempo real de una bicicleta en movimiento. Este modelo es base del diseño utilizado en la estrategia propuesta del presente trabajo.…”

Section: Introductionunclassified

Estabilización Automática de una Bicicleta sin Conductor mediante el Enfoque de Control por Rechazo Activo de Perturbaciones

Baquero-Suárez

Cortés‐Romero

Arcos-Legarda

et al. 2017

Rev. iberoam. autom. inform. ind.

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ResumenEste trabajo propone una estrategia de Control por Rechazo Activo de Perturbaciones (ADRC), usando observadores extendidos de perturbación, para estabilizar una bicicleta en movimiento, sin conductor y con una velocidad de avance variable. Aunque la bicicleta tiene una dinámica inestable y no lineal alrededor de su posición vertical, que puede modelarse como un sistema Lineal de Parámetros Variantes (LPV) dependientes de la velocidad, el diseño del controlador usa un modelo simplificado de parámetros concentrados invariantes en el tiempo y una velocidad nominal constante. El esquema ADRC agrupa las discrepancias entre el modelo simplificado y la planta, junto con las perturbaciones externas en una señal aditiva unificada, que es estimada a través del observador y realimentada mediante una ley de control lineal para rechazarla. La efectividad de la estrategia es validada mediante una co-simulación entre ADAMS y MATLAB, la cual exhibe un alto desempeño y robustez sobre un modelo dinámico virtual de la bicicleta, sometida a perturbaciones externas severas y variaciones de parámetros.Palabras Clave: Bicicletas robóticas, Rechazo activo de perturbaciones, Control robusto, Observadores de perturbación, Sistemas dinámicos de multicuerpos, Sistemas no lineales, Vehículos autónomos. Automatic Stabilization of a Riderless Bicycle using the Active Disturbance Rejection Control Approach AbstractThis work proposes an ADRC (Active Disturbance Rejection Control) strategy by disturbance extended observers to stabilize a moving riderless bicycle with a variant forward speed. Although the bicycle has an unstable and non-linear dynamics when in its upright position, which can be modeled as a LPV (Linear-Parameter-Varying) system that depends on the forward speed, a simplified time-invariant and lumped-parameter model, with an nominal constant forward speed is used in the controller design. ADRC scheme groups discrepancies between the simplified model and the plant, with external disturbances into an equivalent additive unified disturbance signal at input, which is estimated via the observer and rejected through a linear control law. The effectiveness of this strategy is validated by a co-simulation between ADAMS and MATLAB, which exhibits a high performance and robustness in a virtual dynamic model of the bicycle, submitted to severe external disturbances and parameter variations.

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Experimental validation of a model of an uncontrolled bicycle

Cited by 79 publications

References 8 publications

Comparison of Two Experiments Based on a Physical and a Torsion Pendulum to Determine the Mass Moment of Inertia Including Measurement Uncertainties

Comparison of Two Experiments Based on a Physical and a Torsion Pendulum to Determine the Mass Moment of Inertia Including Measurement Uncertainties

Design and Implementation of Model Predictive Control for a Gyroscopic Inverted Pendulum

Estabilización Automática de una Bicicleta sin Conductor mediante el Enfoque de Control por Rechazo Activo de Perturbaciones

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