Reachy, a 3D-Printed Human-Like Robotic Arm as a Testbed for Human-Robot Control Strategies

Mick, Sébastien; Lapeyre, Matthieu; Rouanet, Pierre; Halgand, Christophe; Benois-Pineau, Jenny; Paclet, Florent; Cattaert, Daniel; Oudeyer, Pierre-Yves; Rugy, Aymar de

doi:10.3389/fnbot.2019.00065

Cited by 53 publications

(38 citation statements)

References 43 publications

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“…In order to facilitate development and testing of prototype prostheses that will support different control schemes, it will be useful to take advantage of multiple robotic platforms that are increasingly accessible to researchers [ 38 – 40 ]. Among these, we recently proposed one that has the potential to attack most perspectives mentioned here [ 40 ]. The 3D-printed skeleton and control interface of this platform make it easy to reconfigure both from hardware and software perspectives.…”

Section: Discussionmentioning

confidence: 99%

Shoulder kinematics plus contextual target information enable control of multiple distal joints of a simulated prosthetic arm and hand

Mick

Segas

Dure

et al. 2021

J NeuroEngineering Rehabil

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Background Prosthetic restoration of reach and grasp function after a trans-humeral amputation requires control of multiple distal degrees of freedom in elbow, wrist and fingers. However, such a high level of amputation reduces the amount of available myoelectric and kinematic information from the residual limb. Methods To overcome these limits, we added contextual information about the target’s location and orientation such as can now be extracted from gaze tracking by computer vision tools. For the task of picking and placing a bottle in various positions and orientations in a 3D virtual scene, we trained artificial neural networks to predict postures of an intact subject’s elbow, forearm and wrist (4 degrees of freedom) either solely from shoulder kinematics or with additional knowledge of the movement goal. Subjects then performed the same tasks in the virtual scene with distal joints predicted from the context-aware network. Results Average movement times of 1.22s were only slightly longer than the naturally controlled movements (0.82 s). When using a kinematic-only network, movement times were much longer (2.31s) and compensatory movements from trunk and shoulder were much larger. Integrating contextual information also gave rise to motor synergies closer to natural joint coordination. Conclusions Although notable challenges remain before applying the proposed control scheme to a real-world prosthesis, our study shows that adding contextual information to command signals greatly improves prediction of distal joint angles for prosthetic control.

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Section: Discussionmentioning

confidence: 99%

Shoulder kinematics plus contextual target information enable control of multiple distal joints of a simulated prosthetic arm and hand

Mick

Segas

Dure

et al. 2021

J NeuroEngineering Rehabil

Self Cite

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“…The use of 3D and 4D printing technologies in robotics primarily involves applying methods that print using plastic-based materials and smart materials [21], such as composites with carbon and glass fibers, as well as rubber-based materials. Many examples of the use of 3D/4D printing technology in robotics have been discussed in numerous research work [22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Viscoelastic Properties of Cell Structures Manufactured Using a Photo-Curable Additive Technology—PJM

Kozior

Kundera

2021

Polymers

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This research paper reviews the test results involving viscoelastic properties of cellular structure models made with the PolyJet Matrix—PJM additive technology. The designed test specimens were of complex cellular structure and made of three various photo-curable polymer resin types. Materials were selected taking into account the so-called “soft” and “tough” material groups. Compressive stress relaxation tests were conducted in accordance with the recommendations of standard ISO 3384, and the impact of the geometric structure shape and material selection on viscoelastic properties, as well as the most favorable geometric variants of the tested cellular structure models were determined. Mathematica and Origin software was used to conduct a statistical analysis of the test results and determine five-parameter functions approximating relaxation curves. The most favorable rheological was adopted and its mean parameters determined, which enables to match both printed model materials and their geometry in the future, to make a component with a specific rheological response. Furthermore, the test results indicated that there was a possibility of modelling cellular structures within the PJM technology, using support material as well.

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“…Recently, however, several scienti c papers have appeared on the additive manufacturing of robotic arm components. Mick et al [9] proposed a prototype of a robotic arm made using 3D printing, which is also economically more advantageous compared to the price of an industrial robot thanks to conventional drives. Junia Santillo Costa et al [10] implemented and validated a 3D printed Open Source robotic arm with 6 degrees of freedom made of ABS material, due to higher mechanical strength.…”

Section: Introductionmentioning

confidence: 99%

Research of the Influence of Production Technologies on the Positioning Accuracy of a Robotic Arm for Low Handling Weights

Michalík

Molnár

Fedorko

et al. 2021

Preprint

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The subject of the paper is the research of production technologies influence on positioning accuracy of a robotic arm. The aim was to find out whether different production technologies (additive and conventional) and the related design differences of the robotic arm affect its operational functionality. In the research, positioning accuracy of a robotic arm formed by 3 partial arms was specifically investigated, while the first partial arm Arm I was manufactured by two different technologies. On the robotic arm, the research was carried out in such a way that the first partial arm, Arm I, was being continuously changed and was available for research purposes in two variants. Each of the Arm I variants was manufactured using a different technology (additive and conventional) while, at the same time, the individual variants also differed in construction. The design differences of both variants were related to the production technology used. The measurement of positioning accuracy was performed with the use of two methods. Specifically, a contact and a non-contact method was used. The contact method was implemented on a 3D-measuring machine RAPID and the second contactless method was performed using an inductive sensor. The maximum working load of the robotic arm was 2 kg, so the positioning accuracy was examined at three degrees of operating load equal to 0; 50 and 100% of the maximum workload.

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Reachy, a 3D-Printed Human-Like Robotic Arm as a Testbed for Human-Robot Control Strategies

Cited by 53 publications

References 43 publications

Shoulder kinematics plus contextual target information enable control of multiple distal joints of a simulated prosthetic arm and hand

Shoulder kinematics plus contextual target information enable control of multiple distal joints of a simulated prosthetic arm and hand

Viscoelastic Properties of Cell Structures Manufactured Using a Photo-Curable Additive Technology—PJM

Research of the Influence of Production Technologies on the Positioning Accuracy of a Robotic Arm for Low Handling Weights

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