How to Reach the Dynamic Limits of Parallel Robots? An Autonomous Control Approach

Pietsch, I.T.; Krefft, Mathias; Becker, Oliver; Bier, C.; Hesselbach, J.

doi:10.1109/tase.2005.851600

Cited by 46 publications

(27 citation statements)

References 32 publications

(52 reference statements)

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“…This does not only cause a severe computational problem but yields high noisy estimation of the velocities and accelerations of the end-effector, even for very small termination conditions of the direct kinematics and especially for the rotational DOFs. The use of the Jacobian and its time derivative to calculate the velocities and accelerations may yield modest or acceptable results for lower-mobility manipulators, like reported in Cheng et al (2003); Pietsch et al (2005); Ren et al (2005) and Vivas and Poignet (2005). The results are however not acceptable for accurate tracking of 6 DOFs mechanisms.…”

Section: Motivation For the Proposed Controllermentioning

confidence: 99%

“…A second crucial issue for the control of parallel robots is the high complexity of their dynamics, that compromises the real-time implementation of u C . Thus, many researchers suggest the simplification of the dynamics model (Caccavale et al, 2003;Lee et al, 2003;Pietsch et al, 2005;Vivas and Poignet, 2005;Wang et al, 2007) to ensure real-time ability. This will increase the uncertainties to be counteracted by using higher feedback action.…”

Section: Motivation For the Proposed Controllermentioning

confidence: 99%

See 1 more Smart Citation

Practical Model-based and Robust Control of Parallel Manipulators Using Passivity and Sliding Mode Theory

Abdellatif¹,

Kotlarski²,

Ortmaier³

et al. 2010

Robotics 2010 Current and Future Challenges

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This chapter provides a practical strategy to realize accurate and robust control for 6 DOFs (degrees of freedom) parallel robots. The presented approach consists in two parts. The first basic part is based on the the compensation of the desired dynamics in combination with controller/observer for the single actuators. The passivity formalism offers an excellent framework to design and to tune the closed-loop dynamics, such that the desired behavior is obtained. The basic algorithm is proved to be locally robust towards uncertainties. The second part of the control strategy consists in a sliding mode controller. To keep the practical and computational efficient implementation, the proposed switching control considers explicitly only the friction model. Here we opt for the so called model-decomposition paradigm and we use additional integral action to improve robustness. The proposed approach is substantiated with experimental results demonstrating the effectiveness and success of the strategy that keeps control setup simple and intuitive.

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Section: Motivation For the Proposed Controllermentioning

confidence: 99%

Section: Motivation For the Proposed Controllermentioning

confidence: 99%

Practical Model-based and Robust Control of Parallel Manipulators Using Passivity and Sliding Mode Theory

Abdellatif¹,

Kotlarski²,

Ortmaier³

et al. 2010

Robotics 2010 Current and Future Challenges

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show abstract

“…They determine smooth and time-optimal trajectories by solving the optimization problem numerically, using cubic splines to parametrize the trajectory inside the admissible motion space, and the flexible tolerance method. Pietsch et al [6], [7] provide an algorithm for time-optimal adaptive trajectory planning for parallel robots, which considers an explicit limitation of the pseudo-jerk.…”

Section: Introductionmentioning

confidence: 99%

Smooth and time-optimal trajectory planning for robot manipulators

Muller

Boucherit

Liu

2012

2012 American Control Conference (ACC)

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In this article a new method for planning smooth and time-optimal trajectories for robot manipulators is proposed. Trajectory planning is considered as dynamic optimization problem in which the end-effector path as well as the limitations of the joint velocities, the actuator torques and the actuator torque rates are the constraints. These constraints transferred to the space of the path variable using the parametrized system dynamics border an admissible solution space in which time optimality and smoothness are defined. DAE models are derived to construct time-optimal trajectories inside the admissible solution space taking the maximum velocity curve and its properties into account.

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“…The kinematic and dynamic control problems for parallel robots are considered in (Kövecses et al, 2003;Cheng et al, 2003;Rosario et al, 2007) and an autonomous control approach to reach the dynamic limits of parallel mechanisms is presented in (Pietsch et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Kinematic control of constrained robotic systems

Freitas

Leite

Lizarralde

2011

Sba Controle & Automação

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RESUMO Controle de Sistemas Robóticos com Restrições CinemáticasEste artigo considera o problema de controle de postura para sistemas robóticos com restrições cinemáti-cas. A ideia principal é considerar as restrições cinemáticas dos mecanismos a partir de suas equações estruturais, ao invés de usar explicitamente a equação de restrição. Um estudo de caso para robôs paralelos e robôs cooperativos é discutido baseado nos conceitos de cinemática direta, cinemática diferencial, singularidades e controle cinemático. Resultados de simulação, obtidos a partir de um mecanismo F our-Bar linkage, uma plataforma de Gough-Stewart planar e dois robôs cooperativos, ilustram a aplicabilidade e versatilidade da metodologia proposta.PALAVRAS-CHAVE: robôs paralelos, robôs redundantes, coordenação multi-rôbos, singularidades cinemáticas . ABSTRACTThis paper addresses the posture control problem for robotic systems subject to kinematic constraints. The key idea is to consider the kinematic constraints of the mechanisms from their structure equations, instead of explicitly using the constraint equations. A case study for parallel robots and cooperating redundant robots is discussed based on the following concepts: forward kinematics, differential kinematics, singularities and kinematic control. Simulations results, obtained with a Four-Bar linkage mechanism, a planar Gough-Stewart platform and two cooperating robots, illustrate the applicability and versatility of the proposed methodology.

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How to Reach the Dynamic Limits of Parallel Robots? An Autonomous Control Approach

Cited by 46 publications

References 32 publications

Practical Model-based and Robust Control of Parallel Manipulators Using Passivity and Sliding Mode Theory

Practical Model-based and Robust Control of Parallel Manipulators Using Passivity and Sliding Mode Theory

Smooth and time-optimal trajectory planning for robot manipulators

Kinematic control of constrained robotic systems

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