An Adaptable Human-Like Gait Pattern Generator Derived From a Lower Limb Exoskeleton
Walking rehabilitation processes include many repetitions of the same physical movements in order to replicate, as close as possible, the normal gait trajectories, and kinematics of all leg joints. In these conventional therapies, the therapist's ability to discover patient's limitations-a...
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| Published in | Frontiers in robotics and AI Vol. 6; p. 36 |
|---|---|
| Main Authors | , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Switzerland
Frontiers Media S.A
14.05.2019
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| Subjects | |
| Online Access | Get full text |
| ISSN | 2296-9144 2296-9144 |
| DOI | 10.3389/frobt.2019.00036 |
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| Abstract | Walking rehabilitation processes include many repetitions of the same physical movements in order to replicate, as close as possible, the normal gait trajectories, and kinematics of all leg joints. In these conventional therapies, the therapist's ability to discover patient's limitations-and gradually reduce them-is key to the success of the therapy. Lower-limb robotic exoskeletons have strong deficiencies in this respect as compared to an experienced therapist. Most of the currently available robotic solutions are not able to properly adapt their trajectories to the biomechanical limitations of the patient. With this in mind, much research and development is still required in order to improve artificial human-like walking patterns sufficiently for valuable clinical use. The work herein reported develops and presents a method to acquire and saliently analyze subject-specific gait data while the subject dons a passive lower-limb exoskeleton. Furthermore, the method can generate adjustable, yet subject-specific, kinematic gait trajectories useful in programming controllers for future robotic rehabilitation protocols. A human-user study with ten healthy subjects provides the experimental setup to validate the proposed method. The experimental protocol consists in capturing kinematic data while subjects walk, with the donned H2 lower-limb exoskeleton, across three experimental conditions: walking with three different pre-determined step lengths marked on a lane. The captured ankle trajectories in the sagittal plane were found by normalizing all trials of each test from one heel strike to the next heel strike independent of the specific gait features of each individual. Prior literature suggests analyzing gait in phases. A preliminary data analysis, however, suggests that there exist six key events of the gait cycle, events that can adequately characterize gait for the purposes required of robotic rehabilitation including gait analysis and reference trajectory generation. Defining the ankle as an end effector and the hip as the origin of the coordinate frame and basing the linear regression calculations only on the six key events, i.e., Heel Strike, Toe Off, Pre-Swing, Initial Swing, Mid-Swing, and Terminal Swing, it is possible to generate a new calculated ankle trajectory with an arbitrary step length. The Leave-One-Out Cross Validation algorithm was used to estimate the fitting error of the calculated trajectory vs. the characteristic captured trajectory per subject, showing a fidelity average value of 95.2, 96.1, and 97.2%, respectively, for each step-length trial including all subjects. This research presents method to capture ankle trajectories from subjects and generate human-like ankle trajectories that could be scaled and computed on-line, could be adjusted to different gait scenarios, and could be used not only to generate reference trajectories for gait controllers, but also as an accurate and salient benchmark to test the human likeness of gait trajectories employed by existing robotic exoskeletal devices. |
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| AbstractList | Walking rehabilitation processes include many repetitions of the same physical movements in order to replicate, as close as possible, the normal gait trajectories, and kinematics of all leg joints. In these conventional therapies, the therapist′s ability to discover patient′s limitations—and gradually reduce them—is key to the success of the therapy. Lower-limb robotic exoskeletons have strong deficiencies in this respect as compared to an experienced therapist. Most of the currently available robotic solutions are not able to properly adapt their trajectories to the biomechanical limitations of the patient. With this in mind, much research and development is still required in order to improve artificial human-like walking patterns sufficiently for valuable clinical use. The work herein reported develops and presents a method to acquire and saliently analyze subject-specific gait data while the subject dons a passive lower-limb exoskeleton. Furthermore, the method can generate adjustable, yet subject-specific, kinematic gait trajectories useful in programming controllers for future robotic rehabilitation protocols. A human-user study with ten healthy subjects provides the experimental setup to validate the proposed method. The experimental protocol consists in capturing kinematic data while subjects walk, with the donned H2 lower-limb exoskeleton, across three experimental conditions: walking with three different pre-determined step lengths marked on a lane. The captured ankle trajectories in the sagittal plane were found by normalizing all trials of each test from one heel strike to the next heel strike independent of the specific gait features of each individual. Prior literature suggests analyzing gait in phases. A preliminary data analysis, however, suggests that there exist six key events of the gait cycle, events that can adequately characterize gait for the purposes required of robotic rehabilitation including gait analysis and reference trajectory generation. Defining the ankle as an end effector and the hip as the origin of the coordinate frame and basing the linear regression calculations only on the six key events, i.e., Heel Strike, Toe Off, Pre-Swing, Initial Swing, Mid-Swing, and Terminal Swing, it is possible to generate a new calculated ankle trajectory with an arbitrary step length. The Leave-One-Out Cross Validation algorithm was used to estimate the fitting error of the calculated trajectory vs. the characteristic captured trajectory per subject, showing a fidelity average value of 95.2, 96.1, and 97.2%, respectively, for each step-length trial including all subjects. This research presents method to capture ankle trajectories from subjects and generate human-like ankle trajectories that could be scaled and computed on-line, could be adjusted to different gait scenarios, and could be used not only to generate reference trajectories for gait controllers, but also as an accurate and salient benchmark to test the human likeness of gait trajectories employed by existing robotic exoskeletal devices. Walking rehabilitation processes include many repetitions of the same physical movements in order to replicate, as close as possible, the normal gait trajectories, and kinematics of all leg joints. In these conventional therapies, the therapist's ability to discover patient's limitations-and gradually reduce them-is key to the success of the therapy. Lower-limb robotic exoskeletons have strong deficiencies in this respect as compared to an experienced therapist. Most of the currently available robotic solutions are not able to properly adapt their trajectories to the biomechanical limitations of the patient. With this in mind, much research and development is still required in order to improve artificial human-like walking patterns sufficiently for valuable clinical use. The work herein reported develops and presents a method to acquire and saliently analyze subject-specific gait data while the subject dons a passive lower-limb exoskeleton. Furthermore, the method can generate adjustable, yet subject-specific, kinematic gait trajectories useful in programming controllers for future robotic rehabilitation protocols. A human-user study with ten healthy subjects provides the experimental setup to validate the proposed method. The experimental protocol consists in capturing kinematic data while subjects walk, with the donned H2 lower-limb exoskeleton, across three experimental conditions: walking with three different pre-determined step lengths marked on a lane. The captured ankle trajectories in the sagittal plane were found by normalizing all trials of each test from one heel strike to the next heel strike independent of the specific gait features of each individual. Prior literature suggests analyzing gait in phases. A preliminary data analysis, however, suggests that there exist six key events of the gait cycle, events that can adequately characterize gait for the purposes required of robotic rehabilitation including gait analysis and reference trajectory generation. Defining the ankle as an end effector and the hip as the origin of the coordinate frame and basing the linear regression calculations only on the six key events, i.e., Heel Strike, Toe Off, Pre-Swing, Initial Swing, Mid-Swing, and Terminal Swing, it is possible to generate a new calculated ankle trajectory with an arbitrary step length. The Leave-One-Out Cross Validation algorithm was used to estimate the fitting error of the calculated trajectory vs. the characteristic captured trajectory per subject, showing a fidelity average value of 95.2, 96.1, and 97.2%, respectively, for each step-length trial including all subjects. This research presents method to capture ankle trajectories from subjects and generate human-like ankle trajectories that could be scaled and computed on-line, could be adjusted to different gait scenarios, and could be used not only to generate reference trajectories for gait controllers, but also as an accurate and salient benchmark to test the human likeness of gait trajectories employed by existing robotic exoskeletal devices.Walking rehabilitation processes include many repetitions of the same physical movements in order to replicate, as close as possible, the normal gait trajectories, and kinematics of all leg joints. In these conventional therapies, the therapist's ability to discover patient's limitations-and gradually reduce them-is key to the success of the therapy. Lower-limb robotic exoskeletons have strong deficiencies in this respect as compared to an experienced therapist. Most of the currently available robotic solutions are not able to properly adapt their trajectories to the biomechanical limitations of the patient. With this in mind, much research and development is still required in order to improve artificial human-like walking patterns sufficiently for valuable clinical use. The work herein reported develops and presents a method to acquire and saliently analyze subject-specific gait data while the subject dons a passive lower-limb exoskeleton. Furthermore, the method can generate adjustable, yet subject-specific, kinematic gait trajectories useful in programming controllers for future robotic rehabilitation protocols. A human-user study with ten healthy subjects provides the experimental setup to validate the proposed method. The experimental protocol consists in capturing kinematic data while subjects walk, with the donned H2 lower-limb exoskeleton, across three experimental conditions: walking with three different pre-determined step lengths marked on a lane. The captured ankle trajectories in the sagittal plane were found by normalizing all trials of each test from one heel strike to the next heel strike independent of the specific gait features of each individual. Prior literature suggests analyzing gait in phases. A preliminary data analysis, however, suggests that there exist six key events of the gait cycle, events that can adequately characterize gait for the purposes required of robotic rehabilitation including gait analysis and reference trajectory generation. Defining the ankle as an end effector and the hip as the origin of the coordinate frame and basing the linear regression calculations only on the six key events, i.e., Heel Strike, Toe Off, Pre-Swing, Initial Swing, Mid-Swing, and Terminal Swing, it is possible to generate a new calculated ankle trajectory with an arbitrary step length. The Leave-One-Out Cross Validation algorithm was used to estimate the fitting error of the calculated trajectory vs. the characteristic captured trajectory per subject, showing a fidelity average value of 95.2, 96.1, and 97.2%, respectively, for each step-length trial including all subjects. This research presents method to capture ankle trajectories from subjects and generate human-like ankle trajectories that could be scaled and computed on-line, could be adjusted to different gait scenarios, and could be used not only to generate reference trajectories for gait controllers, but also as an accurate and salient benchmark to test the human likeness of gait trajectories employed by existing robotic exoskeletal devices. |
| Author | Torricelli, Diego Gordillo, Jose Luis Soto, Rogelio Huegel, Joel Carlos Pons, Jose Luis Mendoza-Crespo, Rafael |
| AuthorAffiliation | 3 Center for Extreme Bionics, Massachusetts Institute of Technology , Cambridge, MA , United States 2 Neural Rehabilitation Group, Cajal Institute , Madrid , Spain 1 Tecnologico de Monterrey, Escuela de Ingenieria y Ciencias , Monterrey , Mexico |
| AuthorAffiliation_xml | – name: 2 Neural Rehabilitation Group, Cajal Institute , Madrid , Spain – name: 3 Center for Extreme Bionics, Massachusetts Institute of Technology , Cambridge, MA , United States – name: 1 Tecnologico de Monterrey, Escuela de Ingenieria y Ciencias , Monterrey , Mexico |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/33501052$$D View this record in MEDLINE/PubMed |
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| Copyright | Copyright © 2019 Mendoza-Crespo, Torricelli, Huegel, Gordillo, Pons and Soto. Copyright © 2019 Mendoza-Crespo, Torricelli, Huegel, Gordillo, Pons and Soto. 2019 Mendoza-Crespo, Torricelli, Huegel, Gordillo, Pons and Soto |
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| Keywords | heel strike gait key events toe off eigenvalue decomposition step length ankle trajectory |
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| License | Copyright © 2019 Mendoza-Crespo, Torricelli, Huegel, Gordillo, Pons and Soto. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms. |
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| References_xml | – volume: 3 start-page: 411 year: 2017 ident: B6 article-title: A multi-functional ankle exoskeleton for mobility enhancement of gait-impaired individuals and seniors publication-title: IEEE Robot. Autom. Lett. doi: 10.1109/LRA.2017.2734239 – start-page: 1 volume-title: IEEE International Conference on Rehabilitation Robotics year: 2011 ident: B20 article-title: Velocity-dependent reference trajectory generation for the LOPES gait training robot – volume: 17 start-page: E825 year: 2017 ident: B21 article-title: Inertial sensor-based robust gait analysis in non-hospital settings for neurological disorders publication-title: Sensors doi: 10.3390/s17040825 – volume: 12 start-page: 54 year: 2015 ident: B3 article-title: The H2 robotic exoskeleton for gait rehabilitation after stroke: early findings from a clinical study publication-title: J. NeuroEng. Rehabil. doi: 10.1186/s12984-015-0048-y – volume: 2013 start-page: 918642 year: 2013 ident: B10 article-title: The golden ratio of gait harmony: Repetitive proportions of repetitive gait phases publication-title: BioMed Res. Int. doi: 10.1155/2013/918642 – volume-title: 2010 3rd IEEE RAS and EMBS International Conference on Biomedical Robotics and Biomechatronics (BioRob) year: 2010 ident: B5 article-title: The MACCEPA actuation system as torque actuator in the gait rehabilitation robot ALTACRO doi: 10.1109/BIOROB.2010.5627030 – ident: B14 – volume: 6 start-page: 943 year: 2015 ident: B17 article-title: The mental representation of the human gait in young and older adults publication-title: Front. Psychol. doi: 10.3389/fpsyg.2015.00943 – volume-title: Statistics for Engineers and Scientists, 3 Edn. year: 2010 ident: B15 – start-page: 574 volume-title: IEEE Transactions on Robotics year: 2004 ident: B11 article-title: Automatic gait-pattern adaptation algorithms for rehabilitation with a 4-DOF robotic orthosis – volume-title: Numerical Analysis year: 2010 ident: B4 – year: 2018 ident: B12 article-title: Real-time gait planner for human walking using a lower limb exoskeleton and its implementation on Exoped robot publication-title: arXiv Comput. Sci – volume: 104 start-page: 31 year: 2016 ident: B16 article-title: Conceptual design and dimensional synthesis of cam-linkage mechanisms for gait rehabilitation publication-title: Mech. Mach. Theory doi: 10.1016/j.mechmachtheory.2016.05.018 – start-page: 121 volume-title: New Trends in Mechanism and Machine Science year: 2013 ident: B8 article-title: Synthesis of a mechanism for human gait rehabilitation: an introductory approach – volume: 12 start-page: 1 year: 2015 ident: B19 article-title: Control strategies for active lower extremity prosthetics and orthotics: a review publication-title: J. NeuroEng. Rehabil. doi: 10.1186/1743-0003-12-1 – start-page: 117 volume-title: International Symposium on Science of Mechanisms Mechanisms and Machine year: 2014 ident: B7 article-title: Design and simulation of a leg exoskeleton linkage for a human rehabilitation system – volume: 10 start-page: 44501 year: 2016 ident: B18 article-title: An adjustable single degree-of-freedom system to guide natural walking movement for rehabilitation publication-title: J. Med. Dev. doi: 10.1115/1.4033329 – volume: 17 start-page: 653 year: 2008 ident: B1 article-title: Robot assisted gait training with active leg exoskeleton (ALEX) publication-title: IEEE Transactions on Neural Systems and Rehabilitation Engineering doi: 10.1109/BIOROB.2008.4762885 – volume: 4 start-page: 94 year: 2016 ident: B13 article-title: Thinking, walking, talking: integratory motor and cognitive brain function publication-title: Front. Public Health doi: 10.3389/fpubh.2016.00094 – volume: 2017 start-page: 228 year: 2017 ident: B9 article-title: A generalized framework to achieve coordinated admittance control for multi-joint lower limb robotic exoskeleton publication-title: IEEE Int Conf Rehabil Robot. doi: 10.1109/ICORR.2017.8009251 – start-page: 292 volume-title: 2016 International Conference on Intelligent Control, Power and Instrumentation, ICICPI year: 2017 ident: B2 article-title: Motion for lower limb Exoskeleton based on predefined gait data |
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| Title | An Adaptable Human-Like Gait Pattern Generator Derived From a Lower Limb Exoskeleton |
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