Browsing by Author "Narong Aphiratsakun"
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ItemAU ball on Plate Balancing Robot( 2015) Ali, Ehsan ; Narong AphiratsakunThe ball on plate system is the extension of traditional ball on beam balancing problem in control theory. In this paper the implementation of a proportional-integral- derivative controller (PID controller) to balance a ball on a plate has been demonstrated. To increase the system response time and accuracy multiple controllers are piped through a simple custom serial protocol to boost the processing power, and overall performance. A single HD camera module is used as a sensor to detect the ball’s position and two RC servo motors are used to tilt the plate to balance the ball. The result shows that by implementing multiple PUs (Processing Units) redundancy and high resolution can be achieved in real-time control systems.
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ItemBall On The Plate Model Based on PID Tuning Methods( 2016) Narong Aphiratsakun ; Otaryan, NaneController design is one of the important steps during the modelling of various systems, starting with constructing an electric kettle to an aircraft system. To achieve a good controller it is needed to define suitable values for the controller coefficients. This paper describes the research practices of the tuning technique by using MATLAB/Simulink compared with manually PID tuning based on the trial and error process, as well as, PID tuning methods from Ziegler- Nichols and Tyreus-Luyben (closed-loop proportional gain control or P-Control tests). The paper can be useful for readers who want to have a basic knowledge of research assignments based on PID tuning.
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ItemSingle Loop and Double Loop Control of AU Self-Balancing Bicycle (AUSB)( 2012-12) Narong Aphiratsakun ; Kittiphan TechakittirojThis paper evaluates the controllers performance on AU Self-balancing Bicycle (AUSB). The gyroscope is used to sense the balanced position of the bicycle while an encoder is used to sense the position of the flywheel. The Single loop uses a gyroscope sensor and an additional encoder sensor is used in the Double loop. The main objective of this paper is to demonstrate the improvement in the performance of the AUSB. In the Single loop control, the bicycle can balance within a certain flywheel angle, and then the bicycle will fall. In the Double loop control, bicycle's leaning angle and the flywheel's position are controlled to be horizontal to the ground plane which give a better performance to the AUSB.
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