Powered Hip Exoskeletons Can Reduce the User's Hip and Ankle Muscle Activations During Walking

被引:173
作者
Lenzi, Tommaso [1 ]
Carrozza, Maria Chiara [1 ]
Agrawal, Sunil K. [2 ]
机构
[1] Scuola Super Sant Anna, BioRobot Inst, I-56025 Pisa, Italy
[2] Columbia Univ, Dept Mech Engn, New York, NY 10027 USA
来源
IEEE TRANSACTIONS ON NEURAL SYSTEMS AND REHABILITATION ENGINEERING | 2013年 / 21卷 / 06期
关键词
Assistive and rehabilitation robotics; biomechanics; gait; human-robot interaction; powered exoskeletons; GAIT CHARACTERISTICS; ROBOT; DESIGN; FORCE; AGE; COORDINATION; BIOMECHANICS; PROGRESSION; STRATEGIES; ORTHOSES;
D O I
10.1109/TNSRE.2013.2248749
中图分类号
R318 [生物医学工程];
学科分类号
0831 ;
摘要
In this paper, we study the human locomotor adaptation to the action of a powered exoskeleton providing assistive torque at the user's hip during walking. To this end, we propose a controller that provides the user's hip with a fraction of the nominal torque profile, adapted to the specific gait features of the user from Winter's reference data [34]. The assistive controller has been implemented on the ALEX II exoskeleton and tested on ten healthy subjects. Experimental results show that when assisted by the exoskeleton, users can reduce the muscle effort compared to free walking. Despite providing assistance only to the hip joint, both hip and ankle muscles significantly reduced their activation, indicating a clear tradeoff between hip and ankle strategy to propel walking.
引用
收藏
页码:938 / 948
页数:11
相关论文
共 68 条
[1]   Design of gravity balancing leg orthosis using non-zero free length springs [J].
Agrawal, A ;
Agrawal, SK .
MECHANISM AND MACHINE THEORY, 2005, 40 (06) :693-709
[2]   Inertia Compensation Control of a One-Degree-of-Freedom Exoskeleton for Lower-Limb Assistance: Initial Experiments [J].
Aguirre-Ollinger, Gabriel ;
Colgate, J. Edward ;
Peshkin, Michael A. ;
Goswami, Ambarish .
IEEE TRANSACTIONS ON NEURAL SYSTEMS AND REHABILITATION ENGINEERING, 2012, 20 (01) :68-77
[3]   Extraction of Voluntary Movement for an EMG Controlled Exoskeltal Robot of Tremor Patients [J].
Ando, Takeshi ;
Watanabe, Masaki ;
Fujie, Masakatsu G. .
2009 4TH INTERNATIONAL IEEE/EMBS CONFERENCE ON NEURAL ENGINEERING, 2009, :120-+
[4]  
Artemiadis P. K., 2011, P IEEE INT C REH ROB, P1
[5]   Robot Assisted Gait Training With Active Leg Exoskeleton (ALEX) [J].
Banala, Sai K. ;
Kim, Seok Hun ;
Agrawal, Sunil K. ;
Scholz, John P. .
IEEE TRANSACTIONS ON NEURAL SYSTEMS AND REHABILITATION ENGINEERING, 2009, 17 (01) :2-8
[6]   Pressure and the diabetic foot: clinical science and offloading techniques [J].
Boulton, AJM .
AMERICAN JOURNAL OF SURGERY, 2004, 187 (5A) :17S-24S
[7]   Anterior-posterior ground reaction forces as a measure of paretic leg contribution in hemiparetic walking [J].
Bowden, MG ;
Balasubramanian, CK ;
Neptune, RR ;
Kautz, SA .
STROKE, 2006, 37 (03) :872-876
[8]   Gait-Related Strategies for the Prevention of Plantar Ulcer Development in the High Risk Foot [J].
Bowling, Frank L. ;
Reeves, Neil D. ;
Boulton, Andrew J. .
CURRENT DIABETES REVIEWS, 2011, 7 (03) :159-163
[9]   Spring-like Ankle Foot Orthoses reduce the energy cost of walking by taking over ankle work [J].
Bregman, D. J. J. ;
Harlaar, J. ;
Meskers, C. G. M. ;
de Groot, V. .
GAIT & POSTURE, 2012, 35 (01) :148-153
[10]   Age causes a redistribution of joint torques and powers during gait [J].
DeVita, P ;
Hortobagyi, T .
JOURNAL OF APPLIED PHYSIOLOGY, 2000, 88 (05) :1804-1811
1234567