Sage Journals: Discover world-class research

Abstract

Sensory data are critical for soft robot perception. However, integrating sensors to soft robots remains challenging due to their inherent softness. An alternative approach is indirect sensing through an estimation scheme, which uses robot dynamics and available measurements to estimate variables that would have been measured by sensors. Nevertheless, developing an adequately effective estimation scheme for soft robots is not straightforward. First, it requires a mathematical model; modeling of soft robots is analytically demanding due to their complex dynamics. Second, it should perform multimodal sensing for both internal and external variables, with minimal sensors, and finally, it must be robust against sensor faults. In this article, we propose a recurrent neural network-based adaptive unscented Kalman filter (RNN-AUKF) architecture to estimate the proprioceptive state and exteroceptive unknown input of a pneumatic-based soft finger. To address the challenge in modeling soft robots, we adopt a data-driven approach using RNNs. Then, we interconnect the AUKF with an unknown input estimator to perform multimodal sensing using a single embedded flex sensor. We also prove mathematically that the estimation error is bounded with respect to sensor degradation (noise and drift). Experimental results show that the RNN-AUKF achieves a better overall performance in terms of accuracy and robustness against the benchmark method. The proposed scheme is also extended to a multifinger soft gripper and is robust against out-of-distribution sensor dynamics. The outcomes of this research have immense potentials in realizing a robust multimodal indirect sensing in soft robots.

Get full access to this article

View all access options for this article.

References

Kim

, Laschi

, Trimmer

. Soft robotics: A bioinspired evolution in robotics. Trends Biotechnol, 2013; 31:287–294.

Webster

, Jones

. Design and kinematic modeling of constant curvature continuum robots: A review. Int J Robot Res, 2010; 29:1661–1683.

Laschi

, Mazzolai

, Cianchetti

. Soft robotics: Technologies and systems pushing the boundaries of robot abilities. Sci Robot, 2016; 1:eaah3690.

Wang

, Totaro

, Beccai

. Toward perceptive soft robots: Progress and challenges. Adv Sci, 2018; 5:1800541.

Hawkes

, Blumenschein

, Greer

, et al. A soft robot that navigates its environment through growth. Sci Robot, 2017; 2:eaan3028.

Runciman

, Darzi

, Mylonas

. Soft robotics in minimally invasive surgery. Soft Robot, 2019; 6:423–443.

Wang

, Nurzaman

, Iida

. Soft-material robotics. Found Trends Robot, 2017; 5:191–259.

Iida

, Nurzaman

. Adaptation of sensor morphology: an integrative view of perception from biologically inspired robotics perspective. Interf Focus, 2016; 6:20160016.

Culha

, Nurzaman

, Clemens

, et al. SVAS3: strain vector aided sensorization of soft structures. Sensors, 2014; 14:12748–12770.

10.

Ward-Cherrier

, Pestell

, Cramphorn

, et al. The TacTip Family: Soft optical tactile sensors with 3D-printed biomimetic morphologies. Soft Robot, 2018; 5:216–227.

11.

Larson

, Peele

, Li

, et al. Highly stretchable electroluminescent skin for optical signaling and tactile sensing. Science, 2016; 351:1071–1074.

12.

Muth

, Vogt

, Truby

, et al. 3D printing: Embedded 3D printing of Strain sensors within highly stretchable elastomers (Adv. Mater. 36/2014). Adv Mater, 2014; 26:6202–6202.

13.

Truby

, Wehner

, Grosskopf

, et al. Soft somatosensitive actuators via embedded 3D printing. Adv Mater, 2018; 30:1706383.

14.

Park

, Chen

, Wood

. Design and fabrication of soft artificial skin using embedded microchannels and liquid conductors. IEEE Sensors J, 2012; 12:2711–2718.

15.

Kramer

, Majidi

, Sahai

, et al. Soft curvature sensors for joint angle proprioception. In: 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), San Francisco, CA, September 25–30. IEEE,, 2011:1919–1926.

16.

Maiolino

, Galantini

, Mastrogiovanni

, et al. Soft dielectrics for capacitive sensing in robot skins: Performance of different elastomer types. Sensors Actuat A Phys, 2015; 226:37–47.

17.

Han

, Kim

, et al. Use of deep learning for characterization of microfluidic soft sensors. IEEE Robot Autom Lett, 2018; 3:873–880.

18.

Thuruthel

, Shih

, Laschi

, et al. Soft robot perception using embedded soft sensors and recurrent neural networks. Sci Robot, 2019; 4:eaav1488.

19.

Rus

, Tolley

. Design, fabrication and control of soft robots. Nature, 2015; 521:467.

20.

Laschi

, Cianchetti

. Soft robotics: New perspectives for robot bodyware and control. Front Bioeng Biotechnol, 2014; 2:3.

21.

Godage

, Medrano-Cerda

, Branson

, et al. Modal kinematics for multisection continuum arms. Bioinspirat Biomimet, 2015; 10:035002.

22.

Marchese

, Rus

. Design, kinematics, and control of a soft spatial fluidic elastomer manipulator. Int J Robot Res, 2016; 35:840–869.

23.

Thuruthel

, Falotico

, Renda

, et al. Learning dynamic models for open loop predictive control of soft robotic manipulators. Bioinspirat Biomimet, 2017; 12:066003.

24.

Godage

, Medrano-Cerda

, Branson

, et al. Dynamics for variable length multisection continuum arms. Int J Robot Res, 2016; 35:695–722.

25.

Marchese

, Tedrake

, Rus

. Dynamics and trajectory optimization for a soft spatial fluidic elastomer manipulator. Int J Robot Res, 2016; 35:1000–1019.

26.

Shiva

, Sadati

, Noh

, et al. Elasticity versus hyperelasticity considerations in quasistatic modeling of a soft finger-like robotic appendage for real-time position and force estimation. Soft Robot, 2019; 6:228–249.

27.

Wang

, Hirai

. Soft gripper dynamics using a line-segment model with an optimization-based parameter identification method. IEEE Robot Autom Lett, 2017; 2:624–631.

28.

Chen

, Wang

, Galloway

, et al. Modal-based kinematics and contact detection of soft robots. Soft Robot. [Epub ahead of print]; DOI: 10.1089/soro.2019.0095.

29.

Elgeneidy

, Lohse

, Jackson

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

30.

Nakajima

, Hauser

, Li

, et al. Exploiting the dynamics of soft materials for machine learning. Soft Robot, 2018; 5:339–347.

31.

Van Meerbeek

, De Sa

, Shepherd

. Soft optoelectronic sensory foams with proprioception. Sci Robot, 2018; 3.

32.

Bruder

, Fu

, Gillespie

, et al. Data-driven control of soft robots using koopman operator theory. IEEE Trans Robot, 2021; 37:948–961.

33.

Hauser

, Ijspeert

, Füchslin

, et al. Towards a theoretical foundation for morphological computation with compliant bodies. Biol Cybernet, 2011; 105:355–370.

34.

Tanaka

, Yamane

, Hroux

, et al. Recent advances in physical reservoir computing: A review. Neural Netw, 2019; 115:100–123.

35.

Thieffry

, Kruszewski

, Duriez

, et al. Control design for soft robots based on reduced-order model. IEEE Robot Autom Lett, 2019; 4:25–32.

36.

Lunni

, Giordano

, Sinibaldi

, et al. Shape estimation based on Kalman filtering: Towards fully soft proprioception. In: 2018 IEEE International Conference on Soft Robotics (RoboSoft), Livorno, Italy, April 24–28. IEEE,, 2018:541–546.

37.

Loo

, Kong

, Tan

, et al. Non-linear system identification and state estimation in a pneumatic based soft continuum robot. In: 2019 IEEE Conference on Control Technology and Applications (CCTA), Hong Kong, China, August 19–21. IEEE,, 2019:39–46.

38.

Loo

, Tan

, Nurzaman

. H-infinity based Extended Kalman Filter for State Estimation in Highly Non-linear Soft Robotic System. In: 2019 American Control Conference (ACC), Philadelphia, PA, July 10–12. IEEE,, 2019:5154–5160.

39.

Huang

, Yang

, Zhou

. Adaptive quadratic sum-squares error with unknown inputs for damage identification of structures. Struct Contr Health Monitor, 2010; 17:404–426.

40.

Liu

, Su

, Zhu

, et al. Data fusion based EKF-UI for real-time simultaneous identification of structural systems and unknown external inputs. Measurement, 2016; 88:456–467.

41.

Hochreiter

, Schmidhuber

. Long short-term memory. Neural Comput, 1997; 9:17351780.

42.

Cho

, Van Merriënboer

, Gulcehre

, et al. Learning phrase representations using RNN encoder-decoder for statistical machine translation. arXiv preprint arXiv:1406.1078 2014.

43.

Julier

, Uhlmann

. Unscented filtering and nonlinear estimation. Proceed IEEE, 2004; 92:401–422.

44.

Ilievski

, Mazzeo

, Shepherd

, et al. Soft robotics for chemists. Angewandte Chem Int Edit, 2011; 50:1890–1895.

45.

Katzschmann

, Marchese

, Rus

. Autonomous object manipulation using a soft planar grasping manipulator. Soft Robot, 2015; 2:155–164.

46.

Jain

, Seera

, Lim

, et al. A review of online learning in supervised neural networks. Neural Comput Applicat, 2013; 25:491–509.

47.

Vlachas

, Pathak

, Hunt

, et al. Backpropagation algorithms and Reservoir Computing in Recurrent Neural Networks for the forecasting of complex spatiotemporal dynamics. Neural Netw, 2020; 126:191–217.

48.

Metia

, Ha

, Duc

, et al. Estimation of power plant emissions with unscented kalman filter. IEEE J Selected Top Appl Earth Observ Remote Sens, 2018; 11:2763–2772.

49.

Kingma

, Welling

. Auto-encoding variational bayes. In: 2nd International Conference on Learning Representations, ICLR 2014, Banff, AB, Canada, April 14–16, 2014.

50.

Goodfellow

, Pouget-Abadie

, Mirza

, et al. Generative adversarial nets. In: Ghahramani Z, Welling M, Cortes C, Lawrence N, Weinberger KQ. (Eds). Proceedings of the Advances in Neural Information Processing Systems. Quebec, Canada: Curran Associates, Inc.,, 2014; 27:2672–2680.

51.

Kingma

, Mohamed

, Jimenez Rezende

, et al. Semi-supervised learning with deep generative models. In: Ghahramani Z, Welling M, Cortes C, Lawrence N, Weinberger KQ. (Eds). Proceedings of the Advances in Neural Information Processing Systems. Curran Associates, Inc.,, 2014; 27:3581–3589.

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.

0.88 MB

1.50 MB

0.01 MB

52.05 MB

0.03 MB

0.00 MB

Robust Multimodal Indirect Sensing for Soft Robots Via Neural Network-Aided Filter-Based Estimation

Abstract

Get full access to this article

References

Supplementary Material