Design of power curve for soft gripper based on DQN algorithm
This dissertation presents an in-depth study on developing and training a soft robotic gripper to optimize its gripping performance while minimizing power consumption. With their ability to handle delicate objects, soft robotic grippers hold great promise in industrial automation and human-rob...
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| Format: | Thesis-Master by Coursework |
| Language: | English |
| Published: |
Nanyang Technological University
2025
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/182453 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This dissertation presents an in-depth study on developing and training a soft
robotic gripper to optimize its gripping performance while minimizing
power consumption. With their ability to handle delicate objects, soft robotic
grippers hold great promise in industrial automation and human-robot
interaction applications. However, attaining the most appropriate balance
between gripping performance and energy usage remains essential.
The research explores mixing superior sign processing techniques—
Exponential transferring average (EMA) and Kalman Filtering—into the
education framework to cope with this issue. Those filters are applied to
decorate the accuracy of sensor readings and stabilize the managed indicators,
thereby improving the precision of gripping maneuvers. The examine
systematically evaluates the results of these filtering techniques on the
performance of the smooth gripper under three distinct education strategies:
(1) a step-smart technique, which incrementally adjusts the control
parameters. (2) an abrupt drop strategy, which introduces unexpected
adjustments on top-of-things indicators; and (3) a loose exploration approach,
allowing the machine to discover numerous configurations autonomously.
Experimental outcomes show that the combination of EMA and Kalman
filtering improves the accuracy and reliability of gripping predictions and
i
allows a substantial reduction in energy consumption compared to standard
methods. The findings suggest that the proposed filtering-based total
framework can effectively mitigate the noise and instability commonly
encountered in tender robotic structures, leading to more efficient and sturdy
operation.
This painting contributes insights into developing power-green robot
structures and underscores the significance of adaptive education
methodologies in soft robotics. The consequences provide a basis for future
studies on optimizing the performance of soft actuators in various complex
environments, paving the way for greater sustainability and robot structure. |
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