Review of assistive strategies in powered lower-limb orthoses and exoskeletons

Starting from the early research in the 1960s, especially in the last two decades, orthoses and exoskeletons have been significantly developed. They are designed in different architectures to assist their users’ movements. The research literature has been more prolific on lower-limb devices: a main...

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Published in	Robotics and autonomous systems Vol. 64; pp. 120 - 136
Main Authors	Yan, Tingfang, Cempini, Marco, Oddo, Calogero Maria, Vitiello, Nicola
Format	Journal Article
Language	English
Published	Elsevier B.V 01.02.2015
Subjects	Assistive strategies Design engineering Devices Exoskeletons Lower-limb Movements Orthoses Powered Robotics Strategy Tasks Orthoses Assistive strategies Exoskeletons Powered Lower-limb
Online Access	Get full text
ISSN	0921-8890 1872-793X
DOI	10.1016/j.robot.2014.09.032

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Abstract	Starting from the early research in the 1960s, especially in the last two decades, orthoses and exoskeletons have been significantly developed. They are designed in different architectures to assist their users’ movements. The research literature has been more prolific on lower-limb devices: a main reason is that they address a basic but fundamental motion task, walking. Leg exoskeletons are simpler to design, compared to upper-limb counterparts, but still have particular cognitive and physical requirements from the emerging human–robot interaction systems. In the state of the art, different control strategies and approaches can be easily found: it is still a challenge to develop an assistive strategy which makes the exoskeleton supply efficient and natural assistance. So, this paper aims to provide a systematic overview of the assistive strategies utilized by active locomotion–augmentation orthoses and exoskeletons. Based on the literature collected from Web of Science and Scopus, we have studied the main robotic devices with a focus on the way they are controlled to deliver assistance; the relevant validations are as well investigated, in particular experimentations with human in the loop. Finally current trends and major challenges in the development of an assistive strategy are concluded and discussed. •We collected lower-limb orthosis/exoskeleton papers from Web of Science and Scopus.•We classified the collected papers according to the adopted assistive strategies.•We reviewed each orthosis/exoskeleton focusing on their control strategy.•We also provided the relevant validations of each assistive strategy.
AbstractList	Starting from the early research in the 1960s, especially in the last two decades, orthoses and exoskeletons have been significantly developed. They are designed in different architectures to assist their users’ movements. The research literature has been more prolific on lower-limb devices: a main reason is that they address a basic but fundamental motion task, walking. Leg exoskeletons are simpler to design, compared to upper-limb counterparts, but still have particular cognitive and physical requirements from the emerging human–robot interaction systems. In the state of the art, different control strategies and approaches can be easily found: it is still a challenge to develop an assistive strategy which makes the exoskeleton supply efficient and natural assistance. So, this paper aims to provide a systematic overview of the assistive strategies utilized by active locomotion–augmentation orthoses and exoskeletons. Based on the literature collected from Web of Science and Scopus, we have studied the main robotic devices with a focus on the way they are controlled to deliver assistance; the relevant validations are as well investigated, in particular experimentations with human in the loop. Finally current trends and major challenges in the development of an assistive strategy are concluded and discussed. •We collected lower-limb orthosis/exoskeleton papers from Web of Science and Scopus.•We classified the collected papers according to the adopted assistive strategies.•We reviewed each orthosis/exoskeleton focusing on their control strategy.•We also provided the relevant validations of each assistive strategy. Starting from the early research in the 1960s, especially in the last two decades, orthoses and exoskeletons have been significantly developed. They are designed in different architectures to assist their users' movements. The research literature has been more prolific on lower-limb devices: a main reason is that they address a basic but fundamental motion task, walking. Leg exoskeletons are simpler to design, compared to upper-limb counterparts, but still have particular cognitive and physical requirements from the emerging human-robot interaction systems. In the state of the art, different control strategies and approaches can be easily found: it is still a challenge to develop an assistive strategy which makes the exoskeleton supply efficient and natural assistance. So, this paper aims to provide a systematic overview of the assistive strategies utilized by active locomotion-augmentation orthoses and exoskeletons. Based on the literature collected from Web of Science and Scopus, we have studied the main robotic devices with a focus on the way they are controlled to deliver assistance; the relevant validations are as well investigated, in particular experimentations with human in the loop. Finally current trends and major challenges in the development of an assistive strategy are concluded and discussed.
Author	Vitiello, Nicola Yan, Tingfang Oddo, Calogero Maria Cempini, Marco
Author_xml	– sequence: 1 givenname: Tingfang surname: Yan fullname: Yan, Tingfang email: yantingfang@gmail.com, t.yan@sssup.it organization: The BioRobotics Institute, Scuola Superiore Sant’Anna, viale Rinaldo Piaggio 34, 56025 Pontedera (PI), Italy – sequence: 2 givenname: Marco orcidid: 0000-0001-8104-319X surname: Cempini fullname: Cempini, Marco email: m.cempini@sssup.it organization: The BioRobotics Institute, Scuola Superiore Sant’Anna, viale Rinaldo Piaggio 34, 56025 Pontedera (PI), Italy – sequence: 3 givenname: Calogero Maria orcidid: 0000-0002-1489-5701 surname: Oddo fullname: Oddo, Calogero Maria email: oddoc@sssup.it organization: The BioRobotics Institute, Scuola Superiore Sant’Anna, viale Rinaldo Piaggio 34, 56025 Pontedera (PI), Italy – sequence: 4 givenname: Nicola surname: Vitiello fullname: Vitiello, Nicola email: n.vitiello@sssup.it organization: The BioRobotics Institute, Scuola Superiore Sant’Anna, viale Rinaldo Piaggio 34, 56025 Pontedera (PI), Italy
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Snippet	Starting from the early research in the 1960s, especially in the last two decades, orthoses and exoskeletons have been significantly developed. They are...
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SubjectTerms	Assistive strategies Design engineering Devices Exoskeletons Lower-limb Movements Orthoses Powered Robotics Strategy Tasks
Title	Review of assistive strategies in powered lower-limb orthoses and exoskeletons
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