Abstract
A DC motor velocity control in feedback systems usually requires a velocity sensor, which increases the controller cost. Additionally, the velocity sensor used in industrial applications presents several disadvantages such as maintenance requirements and signal conditioning. In this work, we propose a robust velocity control scheme applied to a DC motor based on estimation strategies using a sliding-mode observer. This means that measurements with mechanical sensors are not required in the controller design. The proposed observer estimates the rotational velocity and load torque of the motor. The controller design applies the exact-linearization technique combined with the super-twisting algorithm to achieve robust performance in the closed-loop system. The controller validation was carried out by experimental tests using a workbench, which is composed of a control and data acquisition Digital Signal Proccessor board, a DC-DC electronic converter, an interface board for signals conditioning, and a DC electric generator connected to an adjustable resistive load. The simulation and experimental results show a significant performance of the proposed control scheme. During tests, the accuracy, robustness, and speed response on the controller were evaluated and the experimental results were compared with a classic proportional-integral controller, which uses a conventional encoder.
Highlights
A DC motor is an electromechanical actuator, with the characteristics of being easy to control, having great versatility, and capability for applications with high inertia loads
This paper proposes a robust second-order sliding-mode (SOSM) super-twisting velocity controller applied to a separately excited DC motor
The DC motor velocity controller performance was evaluated by mean of three disturbances on the load torque and three values for speed reference
Summary
A DC motor is an electromechanical actuator, with the characteristics of being easy to control, having great versatility, and capability for applications with high inertia loads. This paper proposes a robust second-order sliding-mode (SOSM) super-twisting velocity controller applied to a separately excited DC motor. This controller is designed based on input–output feedback linearization control techniques combined with sliding-mode observer. Controller consists of a Design feedback system in which the output variable is compared with a velocity set-point This The comparison represents the deviation as the controlled variably in with respect to theThe set main goal of the control systemofisthe tovelocity maintain motor velocity preset values. The new system proposed (12) has a relative degree one, a first-order control law can be applied to establish a robust closed-loop system, such as the super-twisting algorithm of second order sliding modes.
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