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Abstract

This article presents the system integration, sensing, and control of a novel modular soft-rigid pneumatic exoskeleton for lower limb. The proposed exoskeleton consists of three soft hinges (to drive the hip, knee, and ankle joints) and four rigid links (aligned with the waist, thigh, crus, and foot). Each soft hinge is made of and actuated by a customized bidirectional curl pneumatic artificial muscle (CPAM), whereas the links are three-dimensional printed. Each of the rigid links combined with its lower soft hinge (if any) is made into an independent soft-rigid module, that is, the waist-hip, thigh-knee, crus-ankle, and foot modules. With each of the modules are multiple sensors integrated, including two pressure sensors for detecting the inflating pressures, and two flex sensors and an inertia measurement unit for estimating the bending angles of the soft hinges via data fusion. Through a data-fitted angle–torque–pressure relationship of the CPAM, the actuation torque is estimated. An external electropneumatic control system is also developed. The double closed-loop control system consisting of pressure servos and position/torque controllers is designed to control the bending angles and actuation torques of the exoskeleton hinges. Experiment shows good motion controllability of the proposed exoskeleton in the range of motion of a gait cycle.

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References

Ali

Bionic exoskeleton: history, development and the future. IOSR J Mech Civ Eng, 2014; 9:58–62.

Maciejasz

, Eschweiler

, Gerlach-Hahn

, et al. A survey on robotic devices for upper limb rehabilitation. J Neuroeng Rehabil, 2014; 11:3.

Rupal

, Rafique

, Singla

, et al. Lower-limb exoskeletons: research trends and regulatory guidelines in medical and non-medical applications. Int J Adv Robot Syst, 2017; 14:1–27.

Redlarski

, Blecharz

, Dąbkowski

, et al. Comparative analysis of exoskeletal actuators. Pomiary Automat Robot, 2012; 16:133–138.

Schiele

Ergonomics of exoskeletons: objective performance metrics. In: World Haptics 2009—Third Joint EuroHaptics Conference and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems, Salt Lake City, UT, 2009, pp. 103–108.

Browning

, Modica

, Kram

, et al. The effects of adding mass to the legs on the energetics and biomechanics of walking. Med Sci Sports Exerc, 2007; 39:515–525.

Kim

, Laschi

, Trimmer

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

Asbeck

, De Rossi

SMM

, Holt

, et al. A biologically inspired soft exosuit for walking assistance. Int J Rob Res, 2015; 34:744–762.

Polygerinos

, Galloway

, Savage

, Herman

, Donnell

, Walsh

. Soft robotic glove for hand rehabilitation and task specific training, 2015 IEEE International Conference on Robotics and Automation (ICRA), Seattle, WA, 2015, pp. 2913–2919.

10.

Yap

, Khin

, Koh

, et al. A fully fabric-based bidirectional soft robotic glove for assistance and rehabilitation of hand impaired patients. IEEE Robot Autom Lett, 2017; 2:1383–1390.

11.

Wehner

, Quinlivan

, Aubin

, et al. A lightweight soft exosuit for gait assistance. In: 2013 IEEE International Conference on Robotics and Automation, Karlsruhe, Germany, 2013, pp. 3362–3369.

12.

Costa

, Caldwell

. Control of a Biomimetic”Soft-actuated” 10DoF Lower Body Exoskeleton. In: IEEE/RAS-EMBS International Conference on Biomedical Robotics and Biomechatronics, Pisa, Italy, 2006, pp. 495–501.

13.

Koh

, Cheng

, Yap

, et al. Design of a soft robotic elbow sleeve with passive and intent-controlled actuation. Front Neurosci, 2017; 11:597.

14.

Hassanin

, Steve

, Samia

. A novel, soft, bending actuator for use in power assist and rehabilitation exoskeletons. In: IEEE International Conference on Intelligent Robots and Systems, Vancouver, BC, Canada, 2017, pp. 533–538.

15.

Copaci

, Cano

, Moreno

, et al. New design of a soft robotics wearable elbow exoskeleton based on shape memory alloy wire actuators. Appl Bionics Biomech, 2017; 2017:1–11.

16.

Fei

, Wang

, Pang

. A novel fabric-based versatile and stiffness-tunable soft gripper integrating soft pneumatic fingers and wrist. Soft Robot, 2019; 6:1–20.

17.

Mosadegh

, Polygerinos

, Keplinger

, et al. Pneumatic networks for soft robotics that actuate rapidly. Adv Funct Mater, 2014; 24:2163–2170.

18.

Galloway KC, Polygerinos P, Walsh CJ, et al. Mechanically programmable bend radius for fiber-reinforced soft actuators. In: 2013 16th International Conference on Advanced Robotics (ICAR), Montevideo, Uruguay, 2013, pp. 1–6.

19.

Boyraz

, Runge

, Raatz

. An overview of novel actuators for soft robotics. Actuators, 2018; 7:48.

20.

Yap

, Lim

, Nasrallah

, et al. A soft exoskeleton for hand assistive and rehabilitation application using pneumatic actuators with variable stiffness. In: 2015 IEEE International Conference on Robotics and Automation (ICRA), Seattle, WA, 2015, pp. 4967–4972.

21.

Polygerinos

, Lyne

, Wang

, et al. Towards a soft pneumatic glove for hand rehabilitation. In: IEEE International Conference on Intelligent Robots and Systems, Tokyo, Japan, 2013, pp. 1512–1517.

22.

Young

, Ferris

. State of the art and future directions for lower limb robotic exoskeletons. IEEE Trans Neural Syst Rehabil Eng, 2017; 25:171–182.

23.

Morrow

, Shin

, Phillips-Grafflin

, et al. Improving Soft Pneumatic Actuator fingers through integration of soft sensors, position and force control, and rigid fingernails. In: Proceedings—IEEE International Conference on Robotics and Automation, Stockholm, Sweden, 2016, pp. 5024–5031.

24.

US Bionics Inc. MAX (Modular Agile eXoskeleton). Available at https://www.suitx.com/max-modular-agile-exoskeleton (accessed September 28, 2019).

25.

OpenStax. Anatomy and Physiology. 1st ed. OpenStax, Houston, 2013.

26.

Apkarian

, Naumann

, Cairns

. A three-dimensional kinematic and dynamic model of the lower limb. J Biomech, 1989; 22:143–155.

27.

Marchese

, Katzschmann

, Rus

. A recipe for soft fluidic elastomer robots. Soft Robotics, 2015; 2:7–25.

28.

Wang

, Liu

, Fei

. Design and testing of a soft rehabilitation glove integrating finger and wrist function. J Mech Robot, 2019; 11:011015.

29.

Mahony

, Hamel

, Pflimlin

. Nonlinear complementary filters on the special orthogonal group. IEEE Trans Automat Contr, 2008; 53:1203–1218.

30.

Hazewinkel

Skew-asymmetric matrix. In: Hazewinkel M. (Ed). Encyclopaedia of Mathematics. 10th ed. Springer, Netherlands, 1989.

31.

Mad Dogg Athletics Inc. Back to the basics: Cadence ranges, resistance levels and common corrections every instructor should know. Available at https://spinning.com/back-basics-cadence-ranges-resistance-levels-common-corrections-every-instructor-know (accessed September 28, 2019).

32.

Saggio

Mechanical model of flex sensors used to sense finger movements. Sens Actuators A Phys, 2012; 185:53–58.

33.

Mattson

, Howell

, Magleby

. Development of commercially viable compliant mechanisms using the pseudo-rigid-body model: Case studies of parallel mechanisms. J Intell Mater Syst Struct, 2004; 15:195–202.

34.

Roaas

, Andersson

GBJ

. Normal range of motion of the hip, knee and ankle joints in Male subjects, 30–40 years of age. Acta Orthop Scand, 1982; 53:205–208.

35.

Mungiole

, Crowell

HHP

, Boynton

, Mungiole

Exoskeleton power and torque requirements based on human biomechanics. Available at www.arl.army.mil/arlreports/2002/ARL-TR-2764.pdf (accessed September 28, 2019).

36.

Riener

, Edrich

. Identification of passive elastic joint moments in the lower extremities. J Biomech, 1999; 32:539–544.

37.

Festo Inc. Fluidic muscle DMSP. Available at https://www.festo.com/cat/de_de/products_010606 (accessed September 28, 2019).

38.

Haugen

The good gain method for simple experimental tuning of PI controllers. Model Ident Control, 2012; 33:141–151.

39.

Kadaba

, Ramakrishnan

, Wootten

, et al. Repeatability of kinematic, kinetic, and electromyographic data in normal adult gait. J Orthop Res, 1989; 7:849–860.

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Integration,Sensing,and Control of a Modular Soft-Rigid Pneumatic Lower Limb Exoskeleton

Abstract

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