Development of Foot Modules of an Exoskeleton Equipped with Multiple Sensors for Detecting Walking Phase and Intent

Byoung Jong Son; Yoon Su Baek; Jung Hoon Kim

doi:10.4028/www.scientific.net/AMM.752-753.1016

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 752-753Development of Foot Modules of an Exoskeleton...

Development of Foot Modules of an Exoskeleton Equipped with Multiple Sensors for Detecting Walking Phase and Intent

Abstract:

This paper presents design and application of foot modules in exoskeleton. Detecting the walking phase and intent is most important data for controlling the wearable exoskeleton. The zero moment point (ZMP) trajectory in the robot foot support area is significant criterion for a stability of the walk. The ZMP is calculated by measured force / torque data and Force / Torque sensor (F/T sensor) can measure that. But, the thick foot module is inconvenient to walking. For such a reason, most foot modules are developed using the film type sensors such as force sensing resistor (FSR), ground contact sensor such as tape switch and so on. In this paper, the foot modules equipped optimal design of 3-axis F/T sensor and ground contact sensor are presented and experimental application of detecting the walking phase using both sensors is introduced.

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Periodical:

Applied Mechanics and Materials (Volumes 752-753)

Pages:

1016-1021

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.752-753.1016

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Online since:

April 2015

Authors:

Byoung Jong Son, Yoon Su Baek, Jung Hoon Kim*

Keywords:

Exoskeleton, F/T Sensor, Foot Module, Gait Algorism, Multiple Sensor, Signal Processing, Tape Switch, Walking Phase

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References

[1] Institute on Disability. University of New Hampshire, 2010 Annual disability statistics compendium, Rehabilitation Research and Training Center on Disability Statistics and Demographics, (2010).

Google Scholar

[2] K. Erbatur, A. Okazaki, K. Obiya, T. Takahashi and A. Kawamura, A Study on the Zero Moment Point Measurement for Biped Walking Robots, IEEE Advanced motion control, (2002).

DOI: 10.1109/amc.2002.1026959

Google Scholar

[3] H. Hirohisa, K. Fumio and K. Kenji, Humanoid robotics platforms developed in HRP, Robot. and Auton. Syst. 48 (2004) 165–175.

Google Scholar

[4] M. Hirose and K. Ogawa, Honda humanoid robots development. Phil. Trans. R. Soc. A, 365 (2007) 11–19.

Google Scholar

[5] Z. Weimin, H. Qiang and J. Dongyong, Mechanical design of a light weight and high stiffness humanoid arm of BHR-03. Robotics and Biomimetics, IEEE Int. Conf. on Digit. Object Identifier. (2009) 1681–1686.

DOI: 10.1109/robio.2009.5420411

Google Scholar

[6] L. Jianxi, H. Qiang, Z. Weimin, Y. Zhangguo and L. Kejie, Flexible foot design for a humanoid robot, Automation and Logistics, ICAL 2008, IEEE. Int. Conf. on, 1-3 September, (2008).

DOI: 10.1109/ical.2008.4636375

Google Scholar

[7] R.W. Horst, A Bio-Robotic Leg Orthosis for Rehabilitation and Mobility Enhancement, 31st Annu. Int. Conf. of the IEEE. MBS. 2-6 September (2009).

Google Scholar

[8] S.K. Banala, S.H. Kim, S.K. Agrawal and J.P. Scholz, Robot Assisted Gait Training With Active Leg Exoskeleton (ALEX), IEEE Transactions on neural systems and rehabilitation engineering, February, 17(1) (2009).

DOI: 10.1109/tnsre.2008.2008280

Google Scholar

[9] A.B. Zoss, H. Kazerooni and A. Chu, Biomechanical Design of the Berkeley Lower Extremity Exoskeleton (BLEEX), IEEE/ASME Transactions on mechatronics, April, 11(2) (2006).

DOI: 10.1109/tmech.2006.871087

Google Scholar

[10] J.W. Han, Design of Exoskeletal Assistance Robot for Walking and Rehabilitaion, Korean Soc. for Precision Eng. (2011).

Google Scholar

[11] S.J.M. Bamberg, A.Y. Benbasat, D.M. Scarborough, D.E. Krebs and J.A. Paradiso, Gait analysis using a shoe-integrated wireless sensor system. IEE Trans. Inform. Technol. Biomed., 12 (2008) 413-423.

DOI: 10.1109/titb.2007.899493

Google Scholar

[12] I.P.I. Pappas, M.R. Popovic, T. Keller, V. Diets and M. Morari, A reliable gait phase detection system. IEEE Trans. Neural Syst. Rehab. Eng., 9 (2001) 113-125.

DOI: 10.1109/7333.928571

Google Scholar

[13] J.H. Kim, The Design of Foot Module and 3-Axis F/T Sensor for Measuring ZMP of the Exoskeleton. Korean Soc. for Precision Eng. (2013).

Google Scholar