Exoskeleton robot control based on cane and body joint synergies

Hassan, Modar; Kadone, Hideki; Suzuki, Kenji; Sankai, Yoshiyuki

doi:10.1109/iros.2012.6386248

Cited by 43 publications

(32 citation statements)

References 19 publications

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“…The Japanese company Cyberdyne is worldwide known for the development of the HAL (acronym for hybrid assistive limb) exoskeleton [12], which is used for either task support, rehabilitation, or welfare applications. The HAL robot has been extensively studied, for example, the synchronization control that is based on the position change of the center of ground reaction force (CoGRF) by Tsukahara et al [12], which later added a speed estimator to this control model [13], or the work presented by Hassan et al [14] that included the application of HAL control that is based on combining both lower and upper limb pose signals. Furthermore, the Indego exoskeleton is another good example of commercial devices [15] that are based on the Vanderbilt exoskeleton [5] and is a powered lower limb orthosis for ground gait training.…”

Section: Mathematical Problems In Engineeringmentioning

confidence: 99%

Inverse Modeling of Human Knee Joint Based on Geometry and Vision Systems for Exoskeleton Applications

Piña-Martínez¹,

Rodriguez-Leal

2015

Mathematical Problems in Engineering

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Current trends in Robotics aim to close the gap that separates technology and humans, bringing novel robotic devices in order to improve human performance. Although robotic exoskeletons represent a breakthrough in mobility enhancement, there are design challenges related to the forces exerted to the users’ joints that result in severe injuries. This occurs due to the fact that most of the current developments consider the joints as noninvariant rotational axes. This paper proposes the use of commercial vision systems in order to perform biomimetic joint design for robotic exoskeletons. This work proposes a kinematic model based on irregular shaped cams as the joint mechanism that emulates the bone-to-bone joints in the human body. The paper follows a geometric approach for determining the location of the instantaneous center of rotation in order to design the cam contours. Furthermore, the use of a commercial vision system is proposed as the main measurement tool due to its noninvasive feature and for allowing subjects under measurement to move freely. The application of this method resulted in relevant information about the displacements of the instantaneous center of rotation at the human knee joint.

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Section: Mathematical Problems In Engineeringmentioning

confidence: 99%

Inverse Modeling of Human Knee Joint Based on Geometry and Vision Systems for Exoskeleton Applications

Piña-Martínez¹,

Rodriguez-Leal

2015

Mathematical Problems in Engineering

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“…Again during the double stance phase, the cane remains at rest until the beginning of the weak leg swing. Note that this strategy is in accordance with [7] where the authors take advantage of the synergy between the cane and the legs motion to control a HAL Exoskeleton.…”

Section: A Strategymentioning

confidence: 83%

Development and control of a one-wheel telescopic active cane

Ady

Bachta

Bidaud

2014

5th IEEE RAS/EMBS International Conference on Biomedical Robotics and Biomechatronics

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Population ageing calls for innovative solutions to increase daily living autonomy. Since people autonomy relies on their mobility capabilities, several robotized walking aids i.e. walkers and canes, mainly including navigation functions, have been developed. The existing robotized canes generally consist in statically stable mobile platforms equipped with a rod and a handle. This design alters the basic characteristics of original canes i.e. their weight-lightness and compactness. In this paper, a one-wheel telescopic active cane closer to the original cane concept is presented. Its control law and synchronization with the walking cycle is also given along with experimental results.

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“…Figure 5 illustrates the signal flow of the control system at this state. Motion of the affected leg's hip and knee joints are estimated from the motion of the cane and the motion of the unaffected leg's hip and knee joints (all motions are angle and angular velocities in the sagittal plane), as in Equation (8)

x_{2} = {normalΓ}_{2} {normalΓ}_{1}^{#} x_{1}

where x 2 are the variables to be estimated: affected leg's hip and knee angles and angular velocities, x 1 are the known variables: cane and unaffected leg's hip and knee angles and angular velocities, and

{normalΓ}_{2} {normalΓ}_{1}^{#}

is the rearranged matrix of the eigenvectors extracted from walking with cane trials of seven healthy subjects [30], and rearranged for estimation of x 2 from x 1 [31]. The estimated trajectories are streamed to the robot, and tracked with the actuators on the robot's hip and knee joints with PD controllers.…”

Section: System Overviewmentioning

confidence: 99%

Wearable Gait Measurement System with an Instrumented Cane for Exoskeleton Control

Hassan

Kadone

Suzuki

et al. 2014

Sensors

Self Cite

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In this research we introduce a wearable sensory system for motion intention estimation and control of exoskeleton robot. The system comprises wearable inertial motion sensors and shoe-embedded force sensors. The system utilizes an instrumented cane as a part of the interface between the user and the robot. The cane reflects the motion of upper limbs, and is used in terms of human inter-limb synergies. The developed control system provides assisted motion in coherence with the motion of other unassisted limbs. The system utilizes the instrumented cane together with body worn sensors, and provides assistance for start, stop and continuous walking. We verified the function of the proposed method and the developed wearable system through gait trials on treadmill and on ground. The achievement contributes to finding an intuitive and feasible interface between human and robot through wearable gait sensors for practical use of assistive technology. It also contributes to the technology for cognitively assisted locomotion, which helps the locomotion of physically challenged people.

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Exoskeleton robot control based on cane and body joint synergies

Cited by 43 publications

References 19 publications

Inverse Modeling of Human Knee Joint Based on Geometry and Vision Systems for Exoskeleton Applications

Inverse Modeling of Human Knee Joint Based on Geometry and Vision Systems for Exoskeleton Applications

Development and control of a one-wheel telescopic active cane

Wearable Gait Measurement System with an Instrumented Cane for Exoskeleton Control

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