Journal article 529 views 19 downloads
An evolutionary intelligent control system for a flexible joints robot
Alejandro Pena,
Juan C. Tejada 
,
Juan David Gonzalez-Ruiz ,
Lina María Sepúlveda-Cano ,
Francisco Chiclana,
Fabio Caraffini ,
Mario Gongora
,
Juan David Gonzalez-Ruiz ,
Lina María Sepúlveda-Cano ,
Francisco Chiclana,
Fabio Caraffini ,
Mario Gongora
Applied Soft Computing, Volume: 135, Start page: 110043
Swansea University Author:
Fabio Caraffini
-
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©2023 All rights reserved. All article content, except where otherwise noted, is licensed under a Creative Commons Attribution Non-Commercial No Derivatives License (CC-BY-NC-ND)
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DOI (Published version): 10.1016/j.asoc.2023.110043
Abstract
In this paper, we present a model for a serial robotic system with flexible joints (RFJ) using Euler–Lagrange equations, which integrates the oscillatory dynamics generated by the flexible joints at specific operating points, using a pseudo-Ornstein-Uhlembeck process with reversion to the mean. We a...
| Published in: | Applied Soft Computing |
|---|---|
| ISSN: | 1568-4946 |
| Published: |
Elsevier BV
2023
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| Online Access: |
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa62420 |
| first_indexed |
2023-01-24T08:49:32Z |
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| last_indexed |
2024-11-14T12:20:55Z |
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2024-07-29T12:54:31.5802258 v2 62420 2023-01-24 An evolutionary intelligent control system for a flexible joints robot d0b8d4e63d512d4d67a02a23dd20dfdb 0000-0001-9199-7368 Fabio Caraffini Fabio Caraffini true false 2023-01-24 MACS In this paper, we present a model for a serial robotic system with flexible joints (RFJ) using Euler–Lagrange equations, which integrates the oscillatory dynamics generated by the flexible joints at specific operating points, using a pseudo-Ornstein-Uhlembeck process with reversion to the mean. We also propose a Stochastic Flexible - Adaptive Neural Integrated System (SF-ANFIS) to identify and control the RFJ with two degrees of freedom. For the configuration of the model, we use two adaptive strategies. One strategy is based on the Generalised Delta Rule (GDR). In contrast, a second strategy is based on the EDA-MAGO algorithm (Estimation Distribution Algorithms - Multi-dynamics Algorithm for Global Optimisation), improving online learning. We considered three stages for analysing and validating the proposed SF-ANFIS model: a first identification stage, a second stage defined by the adaptive control process, and a final stage or cancellation of oscillations. Results show that, for the identification stage, the SF-ANFIS model showed better statistical indices than the MADALINE model in control for the second joint, which presents the greatest oscillations; among those that stand out, the IOA (0.9955), VG (1.0012) and UAPC2 (-0.0003). For the control stage, The SF-ANFIS model showed, in a general way, the best behaviour in the system’s control for both joints, thanks to the capacity to identify and cancel oscillations based on the advanced sampling that defines the EDA algorithm. For the cancellation of the oscillations stage, the SF-ANFIS achieved the best behaviour, followed by the MADALINE model, where it is highlighted the UAPC2 (0.9525) value. Journal Article Applied Soft Computing 135 110043 Elsevier BV 1568-4946 Adaptive Neural Fuzzy Integrated Systems (ANFIS); Stochastic model; System control; Robotics; Ornstein–Uhlenbeck (OU) 1 3 2023 2023-03-01 10.1016/j.asoc.2023.110043 COLLEGE NANME Mathematics and Computer Science School COLLEGE CODE MACS Swansea University 2024-07-29T12:54:31.5802258 2023-01-24T08:44:38.7657224 Faculty of Science and Engineering School of Mathematics and Computer Science - Computer Science Alejandro Pena 1 Juan C. Tejada 0000-0003-1195-3379 2 Juan David Gonzalez-Ruiz 0000-0003-4425-7687 3 Lina María Sepúlveda-Cano 0000-0003-1749-816x 4 Francisco Chiclana 5 Fabio Caraffini 0000-0001-9199-7368 6 Mario Gongora 7 62420__26406__b085a75996694f54a7a76e0b040d7fdb.pdf 62420.pdf 2023-01-26T13:46:09.7054683 Output 5970346 application/pdf Accepted Manuscript true 2024-01-23T00:00:00.0000000 ©2023 All rights reserved. All article content, except where otherwise noted, is licensed under a Creative Commons Attribution Non-Commercial No Derivatives License (CC-BY-NC-ND) true eng https://creativecommons.org/licenses/by-nc-nd/4.0/ |
| title |
An evolutionary intelligent control system for a flexible joints robot |
| spellingShingle |
An evolutionary intelligent control system for a flexible joints robot Fabio Caraffini |
| title_short |
An evolutionary intelligent control system for a flexible joints robot |
| title_full |
An evolutionary intelligent control system for a flexible joints robot |
| title_fullStr |
An evolutionary intelligent control system for a flexible joints robot |
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An evolutionary intelligent control system for a flexible joints robot |
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An evolutionary intelligent control system for a flexible joints robot |
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d0b8d4e63d512d4d67a02a23dd20dfdb_***_Fabio Caraffini |
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Fabio Caraffini |
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Alejandro Pena Juan C. Tejada Juan David Gonzalez-Ruiz Lina María Sepúlveda-Cano Francisco Chiclana Fabio Caraffini Mario Gongora |
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Applied Soft Computing |
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In this paper, we present a model for a serial robotic system with flexible joints (RFJ) using Euler–Lagrange equations, which integrates the oscillatory dynamics generated by the flexible joints at specific operating points, using a pseudo-Ornstein-Uhlembeck process with reversion to the mean. We also propose a Stochastic Flexible - Adaptive Neural Integrated System (SF-ANFIS) to identify and control the RFJ with two degrees of freedom. For the configuration of the model, we use two adaptive strategies. One strategy is based on the Generalised Delta Rule (GDR). In contrast, a second strategy is based on the EDA-MAGO algorithm (Estimation Distribution Algorithms - Multi-dynamics Algorithm for Global Optimisation), improving online learning. We considered three stages for analysing and validating the proposed SF-ANFIS model: a first identification stage, a second stage defined by the adaptive control process, and a final stage or cancellation of oscillations. Results show that, for the identification stage, the SF-ANFIS model showed better statistical indices than the MADALINE model in control for the second joint, which presents the greatest oscillations; among those that stand out, the IOA (0.9955), VG (1.0012) and UAPC2 (-0.0003). For the control stage, The SF-ANFIS model showed, in a general way, the best behaviour in the system’s control for both joints, thanks to the capacity to identify and cancel oscillations based on the advanced sampling that defines the EDA algorithm. For the cancellation of the oscillations stage, the SF-ANFIS achieved the best behaviour, followed by the MADALINE model, where it is highlighted the UAPC2 (0.9525) value. |
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2023-03-01T20:19:04Z |
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