Design for Sensorless Force Control of Flexible Robot by Using Resonance Ratio Control Based on Coefficient Diagram Method

Abstract: Original scientific paperGenerally, the flexible robot system can be modeled as the two-mass system which consists of a motor and load connected by a spring. Thus, its elasticity causes resonance in the system. By using the conventional PID controller, this method cannot perform well in this situation. Much research has proceeded with the aim of reducing vibration. A new effective control method, the resonance ratio control, has been introduced as a new way to guarantee the robustness and suppress the oscillat… Show more

“…Therefore, the consideration of the torsion torque as the connecting element for the motor and load sides is needed when the reduction gear is driven. However, in the proposed method of this paper, the feedforward friction compensation (11) and the MEDOB (12) are applied which do not use the torsion stiffness. In addition, we propose the assist control based on the backlash that is not related to the torsional torque.…”

“…τ f s and τ f c are the maximum static friction and the Coulomb friction respectively,θ s and Δθ are the Stribeck angular velocity and the micro angular velocity respectively; and D v is the viscous friction coefficient. (12) In describing the MEDOB, the motor torque becomes τ M = τ M + τ f model by separating the feedforward friction compensation and others. When the effect of friction is compensated by the feedforward friction compensation, Eq.…”

“…To this end, it reduces the friction in the reduction gear by feedforward friction compensation (11) . It also feedbacks the load-side external torque, which is estimated by a multi-encoder-based disturbance observer (MEDOB) (12) . A backdrive assist control that moves the motor based on the a) Correspondence to: Kenta Nagano.…”

Backdrivability Improvement Method Based on Angular Transmission Error in a High Reduction Gear

“…Therefore, the consideration of the torsion torque as the connecting element for the motor and load sides is needed when the reduction gear is driven. However, in the proposed method of this paper, the feedforward friction compensation (11) and the MEDOB (12) are applied which do not use the torsion stiffness. In addition, we propose the assist control based on the backlash that is not related to the torsional torque.…”

“…τ f s and τ f c are the maximum static friction and the Coulomb friction respectively,θ s and Δθ are the Stribeck angular velocity and the micro angular velocity respectively; and D v is the viscous friction coefficient. (12) In describing the MEDOB, the motor torque becomes τ M = τ M + τ f model by separating the feedforward friction compensation and others. When the effect of friction is compensated by the feedforward friction compensation, Eq.…”

“…To this end, it reduces the friction in the reduction gear by feedforward friction compensation (11) . It also feedbacks the load-side external torque, which is estimated by a multi-encoder-based disturbance observer (MEDOB) (12) . A backdrive assist control that moves the motor based on the a) Correspondence to: Kenta Nagano.…”

Backdrivability Improvement Method Based on Angular Transmission Error in a High Reduction Gear

“…We used a multi-encoder-based disturbance observer (MEDOB) [11] as the external torque estimation method in the double inertia system. Using MEDOB, the torqueτ d is estimated by the following equation:…”

Torque-Sensorless Control for a Powered Exoskeleton Using Highly Back-Drivable Actuators

“…Different CDM controllers have been proposed for linear system [4][5][6]. But, CDM controllers' essential shortage is her limitation to linear system and the needing of exponential stability for a given nonlinear systems.…”

A Coefficient Diagram Method Controller with Backstepping Methodology for Robotic Manipulators