Abstract
This paper presents a simple control method on the basis of the trajectory planning for vertical Acrobot to accomplish the control goal of moving the system from the downward initial position (DIP) and steadying the system at the upward target position (UTP). First, for the active link, we frame a trajectory that contains some adjustable parameters. Along the framed trajectory, we can make the active link stabilize at its end angle from its start angle. Furthermore, we change the trajectory parameters to make the passive link also arrive at the zone near the end angle. Next, we devise a PD-based tracking controller to track this planned trajectory. In this way, the vertical Acrobot is swung up to a small zone near the UTP. Then, from the approximate linear model at the UTP, we devise a stabilization controller to stabilize the vertical Acrobot at the UTP. Finally, we implement the simulation to show the validity of the proposed method.
Highlights
The rigid manipulator is a mechanical system composed of a connecting link and joint, which is widely used in the real industrial process [1]
Based on the approximate linear model (ALM) at the upward target position (UTP), we designed a pole-assignment-based stabilization controller [32] to make the vertical Acrobot stabilize at the UTP
This paper presented a simple control strategy on the basis of the trajectory planning method for the vertical Acrobot to accomplish the swing-up and stable control goal
Summary
The rigid manipulator is a mechanical system composed of a connecting link and joint, which is widely used in the real industrial process [1]. The dynamic model of this system does not meet the Brockett’s criteria [13,14], making it difficult to design a smooth state feedback controller to accomplish its control goal [15] These pose great challenges to the control of the VUM. The stabilization controller on the basis of the ALM at the UTP [18] is designed in the balance zone to accomplish the stable control goal of the VUM [19,20], and the main methods include the LQR approach, the linear matrix inequality approach, etc. The main innovations of this paper are as follows: (1) In contrast to existing methods, the vertical Acrobot is swung up from the DIP to a small zone near the UTP by adjusting the parameters in the planned trajectory and tracking this trajectory. The main innovations of this paper are as follows: (1) In contrast to existing methods, the vertical Acrobot is swung up from the DIP to a small zone near the UTP by adjusting the parameters in the planned trajectory and tracking this trajectory. (2) Compared with the energy-based swing-up controller, a simpler PD-based tracking controller without the singular value is devised. (3) Unlike most methods that are only suitable for a particular system, the method proposed in this paper is applicable to the VUM with multiple links and passive joints
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