Review of control strategies for lower-limb exoskeletons to assist gait

Baud, Romain; Manzoori, Ali Reza; Ijspeert, Auke Jan; Bouri, Mohamed

doi:10.1186/s12984-021-00906-3

Cited by 164 publications

(110 citation statements)

References 341 publications

(622 reference statements)

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“…The existing reviews on bipedal walking exoskeletons have been performed for medical applications. A majority of the researchers in the last decade focused on modular rehabilitation of the ankle or knee joints [35][36][37][38] while some selected articles reviewed the leg composition, but with an additional supportive device [39][40][41][42][43][44]. There have been reviews, designs, and clinical gait evaluations in the last few decades, but no specific meta-analysis has been made combining several analyses, evaluations, design, and control methods to validate a model as a proof of concept for developing efficient, affordable, and safety-wise bipedal walking exoskeleton robots that require no additional crutches support.…”

Section: Challenges In Biped Walking Exoskeleton Robotsmentioning

confidence: 99%

A Survey on Design and Control of Lower Extremity Exoskeletons for Bipedal Walking

2022

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Exoskeleton robots are electrically, pneumatically, or hydraulically actuated devices that externally support the bones and cartilage of the human body while trying to mimic the human movement capabilities and augment muscle power. The lower extremity exoskeleton device may support specific human joints such as hip, knee, and ankle, or provide support to carry and balance the weight of the full upper body. Their assistive functionality for physically-abled and disabled humans is demanded in medical, industrial, military, safety applications, and other related fields. The vision of humans walking with an exoskeleton without external support is the prospect of the robotics and artificial intelligence working groups. This paper presents a survey on the design and control of lower extremity exoskeletons for bipedal walking. First, a historical view on the development of walking exoskeletons is presented and various lower body exoskeleton designs are categorized in different application areas. Then, these designs are studied from design, modeling, and control viewpoints. Finally, a discussion on future research directions is provided.

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Section: Challenges In Biped Walking Exoskeleton Robotsmentioning

confidence: 99%

A Survey on Design and Control of Lower Extremity Exoskeletons for Bipedal Walking

2022

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“…Across the reviewed literature, the inconsistency found in the experimental validation of the reviewed control strategies is remarkable. As reported in other reviews ( Pinto-Fernandez et al, 2020 ; Baud et al, 2021 ), the lack of common validation protocols and metrics makes it extremely difficult to compare results from different devices and reliably assess the benefits of each control strategy. Regarding the reviewed works, we found two main issues that were divergent: 1) the subject population that tested the devices and 2) the evaluated outcomes.…”

Section: State Of the Artmentioning

confidence: 99%

“…In terms of control strategies, Tucker et al provided an overview of the different control strategies for lower-limb robotic prostheses and orthoses and introduced a three-level paradigm controller development ( Tucker et al, 2015 ). This same paradigm was recently updated and completed by Baud et al, who systematically analyzed the control strategies of lower-limb exoskeletons by dividing them into functional units ( Baud et al, 2021 ). Considering these three-level paradigms, Ma et al performed a deeper review of the high-level controllers responsible for the voluntary control of robotic devices ( Ma et al, 2019 ), while Miscon et al focused on middle-level controllers, in particular, joint trajectory generation for robotic exoskeletons ( Miskon and Yusof, 2014 ).…”

Section: Introductionmentioning

confidence: 99%

“…In contrast with complete lower-limb exoskeletons, which act over the hips and knees (even ankles) of both limbs, partial exoskeletons act partially over the locomotor system of the wearer by exclusively assisting one joint (single-joint exoskeletons) or one leg of the user (unilateral exoskeletons). Although they present several advantages [they are simpler and lighter than bilateral devices ( Baud et al, 2021 ) and can target the specific function of the assisted joint during gait ( Yan et al, 2015a )], they need to ensure proper interjoint coordination, especially with non-actuated joints. Unlike complete exoskeletons, which can impose the appropriate coordination between joints and legs, partial exoskeletons cannot actuate globally in the entire locomotor system; therefore, this interjoint coordination needs to be resolved by the controller of the device.…”

Section: Introductionmentioning

confidence: 99%

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Coordination Between Partial Robotic Exoskeletons and Human Gait: A Comprehensive Review on Control Strategies

Lora-Millán

Moreno

Rocón

2022

Front. Bioeng. Biotechnol.

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Lower-limb robotic exoskeletons have become powerful tools to assist or rehabilitate the gait of subjects with impaired walking, even when they are designed to act only partially over the locomotor system, as in the case of unilateral or single-joint exoskeletons. These partial exoskeletons require a proper method to synchronize their assistive actions and ensure correct inter-joint coordination with the user’s gait. This review analyzes the state of the art of control strategies to coordinate the assistance provided by these partial devices with the actual gait of the wearers. We have analyzed and classified the different approaches independently of the hardware implementation, describing their basis and principles. We have also reviewed the experimental validations of these devices for impaired and unimpaired walking subjects to provide the reader with a clear view of their technology readiness level. Eventually, the current state of the art and necessary future steps in the field are summarized and discussed.

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“…The interest on lower-limb exoskeletons for gait re-69 habilitation has increased exponentially in the last 70 years, which is reflected in the considerable number 71 of reviews published within the last decade [38,. 72 However, the majority of these reviews focus on hard-73 ware, while only a few of them analyzed the control 74 strategies implemented on lower limb exoskeletons and 75 their effects on walking function in people with brain 76 injuries [38,41,42,[54][55][56][57][58][59][60]]. Yet, the control strategy -77 as ergonomics and robot actuation-might play a key 78 role on the effectiveness of the robotic treatment [61].…”

mentioning

confidence: 99%

Control strategies used in lower limb exoskeletons for gait rehabilitation after brain injury: a systematic review and analysis of clinical effectiveness

Miguel-Fernández

Lobo-Prat²,

Prinsen

et al. 2022

Preprint

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BackgroundIn the past decade, there has been substantial progress in the development of robotic controllers that specify how lower-limb exoskeletons should interact with brain-injured patients. However, it is still an open question which exoskeleton control strategies can more effectively stimulate motor function recovery. Within this review, we aim to complement previous literature surveys on the topic of exoskeleton control for gait rehabilitation by: (1) Providing an updated structured framework of current control strategies, (2) Analyzing the methodology of clinical validations used in the robotic interventions, and (3) Reporting the potential relation between the employed control strategies and clinical outcomes. MethodsFour databases were searched using database-specific search terms from 2000 to September 2020. We identified 1648 articles, of which 159 were included and evaluated in full-text. We included studies that clinically evaluated the effectiveness of the exoskeleton on impaired participants, and which clearly explained or referenced the implemented control strategy. Results(1) We found that adaptive assistive control (100 \% of exoskeletons) that followed rule-based algorithms (72 \%) based on ground reaction force thresholds (63 \%) in conjunction with trajectory-tracking control (97 \%) were the most implemented control strategies. (2) Regarding the clinical validations used in the robotic interventions, we found high variability on the experimental protocols and outcome metrics selected. (3) With moderate grade of evidence, associated to the high heterogeneity in the experimental protocol and low number of studies, we found that adaptive control strategies, which followed threshold-based or adaptive oscillator algorithms together with trajectory-tracking control, resulted in the highest improvements on clinical outcomes for people with stroke. ConclusionsDespite the efforts to develop novel more effective controllers for gait neurorehabilitation, the current level of evidence on the effectiveness of the different control strategies on clinical outcomes is still low. There is a clear lack of standardization in the experimental protocols leading to high levels of heterogeneity. Standardized comparisons among control strategies analyzing the relation between control parameters and biomechanical metrics will fill this gap to better guide future technical developments. The most promising controllers seem to be those that adapt to key biomechanical descriptors based on the patients' specific pathology.

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Review of control strategies for lower-limb exoskeletons to assist gait

Cited by 164 publications

References 341 publications

A Survey on Design and Control of Lower Extremity Exoskeletons for Bipedal Walking

A Survey on Design and Control of Lower Extremity Exoskeletons for Bipedal Walking

Coordination Between Partial Robotic Exoskeletons and Human Gait: A Comprehensive Review on Control Strategies

Control strategies used in lower limb exoskeletons for gait rehabilitation after brain injury: a systematic review and analysis of clinical effectiveness

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