Synergy-based Gaussian Process Estimation of Ankle Angle and Torque: Conceptualization for High level Controlling of Active Foot Prostheses/Orthoses.

Human gait is the result of a complex and fascinating cooperation between different joints and segments in the lower extremity. This study aims at investigating the existence of this cooperation or the so-called synergy between the shank motion and the ankle motion. One potential use of this synergy is to develop the high level controllers for active foot prostheses/orthoses. The central point in this paper is to develop a high level controller that is able to continuously map shank kinematics (inputs) to ankle angles and torques (outputs). At the same time, it does not require speed determination, gait percent identification, switching rules and look-up tables. Furthermore, having those targets in mind, an important part of this study is to determine which input type is required to achieve such targets. This should be fulfilled through using minimum number of inputs. To do this, the Gaussian Process (GP) regression has been used to estimate the ankle angles and torques for 11 subjects at three walking speeds (0.5, 1, 1.5 m/s) based on the shank angular velocity and angle. The results show that it is possible to estimate ankle motion based on the shank motion. It was found that the estimation achieved less quality with only shank angular velocity or angle, whereas, the aggregated angular velocity and angle resulted in much higher output estimation quality. The pros and cons of the proposed method are investigated at different scenarios.

[1]  André Seyfarth,et al.  Effects of unidirectional parallel springs on required peak power and energy in powered prosthetic ankles: Comparison between different active actuation concepts , 2012, 2012 IEEE International Conference on Robotics and Biomimetics (ROBIO).

[2]  Michael Goldfarb,et al.  Powered sit-to-stand and assistive stand-to-sit framework for a powered transfemoral prosthesis , 2009, 2009 IEEE International Conference on Rehabilitation Robotics.

[3]  Daniel P Ferris,et al.  An improved powered ankle-foot orthosis using proportional myoelectric control. , 2006, Gait & posture.

[4]  T.G. Sugar,et al.  A Robust Control Concept for Robotic Ankle Gait Assistance , 2007, 2007 IEEE 10th International Conference on Rehabilitation Robotics.

[5]  J Y Goulermas,et al.  Predicting lower limb joint kinematics using wearable motion sensors. , 2008, Gait & posture.

[6]  Hartmut Geyer,et al.  Control of a Powered Ankle–Foot Prosthesis Based on a Neuromuscular Model , 2010, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[7]  João Yoshiyuki Ishihara,et al.  Estimation of foot orientation with respect to ground for an above knee robotic prosthesis , 2009, 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[8]  Daniel P Ferris,et al.  Locomotor adaptation to a powered ankle-foot orthosis depends on control method , 2007, Journal of NeuroEngineering and Rehabilitation.

[9]  Carl E. Rasmussen,et al.  Gaussian processes for machine learning , 2005, Adaptive computation and machine learning.

[10]  Michael W. Whittle,et al.  Gait Analysis: An Introduction , 1986 .

[11]  Max Donath,et al.  Feasibility of an Active Control Scheme for Above Knee Prostheses , 1977 .

[12]  Donald Lee Grimes An active multi-mode above knee prosthesis controller , 1979 .

[13]  Thomas Sugar,et al.  Robotic transtibial prosthesis with biomechanical energy regeneration , 2009, Ind. Robot.

[14]  Constantinos Gavriel,et al.  Gaussian Process Regression for accurate prediction of prosthetic limb movements from the natural kinematics of intact limbs , 2015, 2015 7th International IEEE/EMBS Conference on Neural Engineering (NER).

[15]  Bram Vanderborght,et al.  The AMP-Foot 2.0: Mimicking intact ankle behavior with a powered transtibial prosthesis , 2012, 2012 4th IEEE RAS & EMBS International Conference on Biomedical Robotics and Biomechatronics (BioRob).

[16]  Ivan Glesk,et al.  Skin Temperature Prediction in Lower Limb Prostheses , 2016, IEEE Journal of Biomedical and Health Informatics.

[17]  Kate Button,et al.  Inertial Measurement Units for Clinical Movement Analysis: Reliability and Concurrent Validity , 2018, Sensors.

[18]  Philip A. Voglewede,et al.  Within-socket myoelectric prediction of continuous ankle kinematics for control of a powered transtibial prosthesis , 2014, Journal of neural engineering.

[19]  Hugh M. Herr,et al.  Powered ankle-foot prosthesis to assist level-ground and stair-descent gaits , 2008, Neural Networks.

[20]  H. Hermens,et al.  Energy storage and release of prosthetic feet Part 1: Biomechanical analysis related to user benefits , 1997, Prosthetics and orthotics international.

[21]  L. Barnes,et al.  An EMG-to-Force Processing Approach for Estimating in Vivo Hip Muscle Forces in Normal Human Walking , 2017, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[22]  Hugh M. Herr,et al.  Powered Ankle--Foot Prosthesis Improves Walking Metabolic Economy , 2009, IEEE Transactions on Robotics.

[23]  N. A. Borghese,et al.  Kinematic determinants of human locomotion. , 1996, The Journal of physiology.

[24]  André Seyfarth,et al.  A comparison of parallel- and series elastic elements in an actuator for mimicking human ankle joint in walking and running , 2012, 2012 IEEE International Conference on Robotics and Automation.

[25]  H.A. Varol,et al.  Real-time gait mode intent recognition of a powered knee and ankle prosthesis for standing and walking , 2008, 2008 2nd IEEE RAS & EMBS International Conference on Biomedical Robotics and Biomechatronics.

[26]  Michael Goldfarb,et al.  Multiclass Real-Time Intent Recognition of a Powered Lower Limb Prosthesis , 2010, IEEE Transactions on Biomedical Engineering.

[27]  Nicholas P. Fey,et al.  Intent Recognition in a Powered Lower Limb Prosthesis Using Time History Information , 2013, Annals of Biomedical Engineering.

[28]  Michael Goldfarb,et al.  Design and Control of a Powered Transfemoral Prosthesis , 2008, Int. J. Robotics Res..

[29]  Hyun-Chul Kim,et al.  Statistical method for prediction of gait kinematics with Gaussian process regression. , 2014, Journal of biomechanics.

[30]  Daniel P. Ferris,et al.  Comparing neural control and mechanically intrinsic control of powered ankle exoskeletons , 2017, 2017 International Conference on Rehabilitation Robotics (ICORR).

[31]  Mahdy Eslamy,et al.  Emulation of Ankle Function for Different Gaits through Active Foot Prosthesis: Actuation Concepts, Control and Experiments , 2014 .

[32]  H.A. Varol,et al.  Design and control of an active electrical knee and ankle prosthesis , 2008, 2008 2nd IEEE RAS & EMBS International Conference on Biomedical Robotics and Biomechatronics.

[33]  Xuan Zhang,et al.  Human lower extremity joint moment prediction: A wavelet neural network approach , 2014, Expert Syst. Appl..

[34]  P. Bonato,et al.  An EMG-position controlled system for an active ankle-foot prosthesis: an initial experimental study , 2005, 9th International Conference on Rehabilitation Robotics, 2005. ICORR 2005..

[35]  H. van der Kooij,et al.  Reference Trajectory Generation for Rehabilitation Robots: Complementary Limb Motion Estimation , 2009, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[36]  Thomas G. Sugar,et al.  A novel control algorithm for wearable robotics using phase plane invariants , 2009, 2009 IEEE International Conference on Robotics and Automation.

[37]  Michael Goldfarb,et al.  Self-contained powered knee and ankle prosthesis: Initial evaluation on a transfemoral amputee , 2009, 2009 IEEE International Conference on Rehabilitation Robotics.

[38]  J Y Goulermas,et al.  Regression techniques for the prediction of lower limb kinematics. , 2005, Journal of biomechanical engineering.

[39]  H.A. Varol,et al.  Real-time Intent Recognition for a Powered Knee and Ankle Transfemoral Prosthesis , 2007, 2007 IEEE 10th International Conference on Rehabilitation Robotics.

[40]  Katsuhiko Ogata,et al.  Modern Control Engineering , 1970 .

[41]  Nicholas P. Fey,et al.  Classifying the intent of novel users during human locomotion using powered lower limb prostheses , 2013, 2013 6th International IEEE/EMBS Conference on Neural Engineering (NER).

[42]  Fan Zhang,et al.  Continuous Locomotion-Mode Identification for Prosthetic Legs Based on Neuromuscular–Mechanical Fusion , 2011, IEEE Transactions on Biomedical Engineering.

[43]  Atilla Kilicarslan,et al.  High accuracy decoding of user intentions using EEG to control a lower-body exoskeleton , 2013, 2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[44]  He Huang,et al.  A Strategy for Identifying Locomotion Modes Using Surface Electromyography , 2009, IEEE Transactions on Biomedical Engineering.

[45]  J.K. Hitt,et al.  Control of a Regenerative Braking Powered Ankle Foot Orthosis , 2007, 2007 IEEE 10th International Conference on Rehabilitation Robotics.