Sage Journals: Discover world-class research

Abstract

Successful soft robot modeling approaches appearing in the recent literature have been based on a variety of distinct theories, including traditional robotic theory, continuum mechanics, and machine learning. Though specific modeling techniques have been developed for and validated against already realized systems, their strengths and weaknesses have not been explicitly compared against each other. In this article, we show how three distinct model structures, a lumped-parameter model, a continuum mechanical model, and a neural network, compare in capturing the gross trends and specific features of the force generation of soft robotic actuators. In particular, we study models for fiber-reinforced elastomeric enclosures (FREEs), which are a popular choice of soft actuator and that are used in several soft articulated systems, including soft manipulators, exoskeletons, grippers, and locomoting soft robots. We generated benchmark data by testing eight FREE samples that spanned broad design and kinematic spaces and compared the models on their ability to predict the loading–deformation relationships of these samples. This comparison shows the predictive capabilities of each model on individual actuators and each model’s generalizability across the design space. While the neural net achieved the highest peak performance, the first principles-based models generalized best across all actuator design parameters tested. The results highlight the essential roles of mathematical structure and experimental parameter determination in building high-performing, generalizable soft actuator models with varying effort invested in system identification.

Keywords

Soft robotics robotics modeling first principles neural network comparison

Get full access to this article

View all access options for this article.

References

Bishop-Moser

Kota

(2015) Design and modeling of generalized fiber-reinforced pneumatic soft actuators. IEEE Transactions on Robotics 31(3): 536–545.

Branyan

Menguc

(2018) Soft snake robots: Investigating the effects of gait parameters on locomotion in complex terrains. In: 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).

Bruder

Remy

Vasudevan

(2018a) Nonlinear system identification of soft robot dynamics using koopman operator theory. arXiv preprint arXiv:1810.06637.

Bruder

Sedal

Bishop-Moser

Kota

Vasudevan

(2017) Model based control of fiber reinforced elastofluidic enclosures. In: 2017 IEEE International Conference on Robotics and Automation (ICRA). IEEE, pp. 5539–5544.

Bruder

Sedal

Vasudevan

Remy

(2018b) Force generation by parallel combinations of fiber-reinforced fluid-driven actuators. arXiv preprint arXiv:1805.00124.

Coevoet

Morales-Bieze

Largilliere

, et al. (2017) Software toolkit for modeling, simulation, and control of soft robots. Advanced Robotics 31(22): 1208–1224.

Connolly

Walsh

Bertoldi

(2017) Automatic design of fiber-reinforced soft actuators for trajectory matching. Proceedings of the National Academy of Sciences 114(1): 51–56.

Deimel

Brock

(2016) A novel type of compliant and underactuated robotic hand for dexterous grasping. The International Journal of Robotics Research 35(1–3): 161–185.

Della Santina

Katzschmann

Bicchi

Rus

(2018a) Dynamic control of soft robots interacting with the environment. In: 2018 IEEE International Conference on Soft Robotics (RoboSoft).

10.

Della Santina

Lakatos

Bicchi

Albu-Schäffer

(2018b) Using nonlinear normal modes for execution of efficient cyclic motions in soft robots. arXiv preprint arXiv:1806.08389.

11.

Elgeneidy

Lohse

Jackson

(2018) Bending angle prediction and control of soft pneumatic actuators with embedded flex sensors—a data-driven approach. Mechatronics 50: 234–247.

12.

Gent

(2012) Engineering With Rubber: How to Design Rubber Components. Carl Hanser Verlag GmbH Co KG.

13.

Gillespie

Best

Townsend

Wingate

Killpack

(2018) Learning nonlinear dynamic models of soft robots for model predictive control with neural networks. In: 2018 IEEE International Conference on Soft Robotics (RoboSoft). IEEE, pp. 39–45.

14.

Giorelli

Renda

Calisti

Arienti

Ferri

Laschi

(2015) Neural network and Jacobian method for solving the inverse statics of a cable-driven soft arm with nonconstant curvature. IEEE Transactions on Robotics 31(4): 823–834.

15.

Giorelli

Renda

Ferri

Laschi

(2013) A feed-forward neural network learning the inverse kinetics of a soft cable-driven manipulator moving in three-dimensional space. In: 2013 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). IEEE, pp. 5033–5039.

16.

Giorgio-Serchi

Arienti

Corucci

Giorelli

Laschi

(2017) Hybrid parameter identification of a multi-modal underwater soft robot. Bioinspiration and Biomimetics 12(2): 025007.

17.

Goury

Duriez

(2018) Fast, generic, and reliable control and simulation of soft robots using model order reduction. IEEE Transactions on Robotics 34(6): 1565–1576.

18.

Han

Chesnutt

Garcia

Liu

Wen

(2013) Artery buckling: New phenotypes, models, and applications. Annals of Biomedical Engineering 41(7): 1399–1410.

19.

Holzapfel

Gasser

Ogden

(2000) A new constitutive framework for arterial wall mechanics and a comparative study of material models. Journal of Elasticity and the Physical Science of Solids 61(1–3): 1–48.

20.

Ilievski

Mazzeo

Shepherd

Chen

Whitesides

(2011) Soft robotics for chemists. Angewandte Chemie 123(8): 1930–1935.

21.

Koller

Gates

Ferris

Remy

(2016) ‘body-in-the-loop’optimization of assistive robotic devices: A validation study. In: Robotics: Science and Systems.

22.

Laschi

Cianchetti

Mazzolai

Margheri

Follador

Dario

(2012) Soft robot arm inspired by the octopus. Advanced Robotics 26(7): 709–727.

23.

Liu

Wen

Mottahedi

Han

(2014) Artery buckling analysis using a four-fiber wall model. Journal of Biomechanics 47(11): 2790–2796.

24.

McMahan

Chitrakaran

Csencsits

, et al. (2006) Field trials and testing of the Octarm continuum manipulator. In: Proceedings 2006 IEEE International Conference on Robotics and Automation (ICRA 2006). IEEE, pp. 2336–2341.

25.

Moseley

Florez

Sonar

Agarwal

Curtin

Paik

(2016) Modeling, design, and development of soft pneumatic actuators with finite element method. Advanced Engineering Materials 18(6): 978–988.

26.

Ogden

(1997) Non-linear Elastic Deformations. Courier Corporation.

27.

Park

Chen

Pérez-Arancibia

, et al. (2014) Design and control of a bio-inspired soft wearable robotic device for ankle–foot rehabilitation. Bioinspiration and Biomimetics 9(1): 016007.

28.

Perrone

Cooper

(1992) When networks disagree: Ensemble methods for hybrid neural networks. Technical Report, Institute for Brain and Neural Systems, Brown University, Providence, RI.

29.

Polygerinos

Wang

Galloway

Wood

Walsh

(2015a) Soft robotic glove for combined assistance and at-home rehabilitation. Robotics and Autonomous Systems 73: 135–143.

30.

Polygerinos

Wang

Overvelde

, et al. (2015b) Modeling of soft fiber-reinforced bending actuators. IEEE Transactions on Robotics 31(3): 778–789.

31.

Pritts

Rahn

(2004) Design of an artificial muscle continuum robot. In: Proceedings 2004 IEEE International Conference on Robotics and Automation (ICRA’04), Vol. 5. IEEE, pp. 4742–4746.

32.

Robertson

Sadeghi

Florez

Paik

(2017) Soft pneumatic actuator fascicles for high force and reliability. Soft Robotics 4(1): 23–32.

33.

Rus

Tolley

(2015) Design, fabrication and control of soft robots. Nature 521(7553): 467–475.

34.

Sadati

Naghibi

Shiva

Walker

Althoefer

Nanayakkara

(2017) Mechanics of continuum manipulators, a comparative study of five methods with experiments. In: Annual Conference Towards Autonomous Robotic Systems. Berlin: Springer, pp. 686–702.

35.

Satheeshbabu

(2018) Open loop position control of soft continuum arm using deep reinforcement learning. In: 2019 International Conference on Robotics and Automation (ICRA).

36.

Satheeshbabu

Krishnan

(2017) Designing systems of fiber reinforced pneumatic actuators using a pseudo-rigid body model. In: 2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). IEEE, pp. 1201–1206.

37.

Scarborough

Rahn

Smith

(2012) Fluidic composite tunable vibration isolators. Journal of Vibration and Acoustics 134(1): 011010.

38.

Sedal

Bruder

Bishop-Moser

Vasudevan

Kota

(2018) A continuum model for fiber-reinforced soft robot actuators. Journal of Mechanisms and Robotics 10(2): 024501.

39.

Shepherd

Ilievski

Choi

, et al. (2011) Multigait soft robot. Proceedings of the National Academy of Sciences 108(51): 20400–20403.

40.

Singh

Xiao

Hsiao-Wecksler

Krishnan

(2018) Design and analysis of coiled fiber reinforced soft pneumatic actuator. Bioinspiration and Biomimetics 13(3): 036010.

41.

Spencer

(1971) Part III. Theory of invariants. Continuum Physics 1: 239–353.

42.

Sünderhauf

Brock

Scheirer

, et al. (2018) The limits and potentials of deep learning for robotics. The International Journal of Robotics Research 37(4–5): 405–420.

43.

Thuruthel

Falotico

Renda

Laschi

(2019) Model-based reinforcement learning for closed-loop dynamic control of soft robotic manipulators. IEEE Transactions on Robotics 35(1): 124–134.

44.

Tondu

Lopez

(2000) Modeling and control of mckibben artificial muscle robot actuators. IEEE control systems 20(2): 15–38.

45.

Uppalapati

Singh

Krishnan

(2018) Parameter estimation and modeling of a pneumatic continuum manipulator with asymmetric building blocks. In: 2018 IEEE International Conference on Soft Robotics (RoboSoft). IEEE, pp. 528–533.

46.

Veale

Xie

Anderson

(2018) Accurate multivariable arbitrary piecewise model regression of McKibben and Peano muscle static and damping force behavior. Smart Materials and Structures 27(10): 105048.

47.

Wang

Polygerinos

Overvelde

Galloway

Bertoldi

Walsh

(2017) Interaction forces of soft fiber reinforced bending actuators. IEEE/ASME Transactions on Mechatronics 22(2): 717–727.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.37 MB

0.00 MB

Comparison and experimental validation of predictive models for soft,fiber-reinforced actuators

Abstract

Keywords

Get full access to this article

References

Supplementary Material