Engaging with Robotic Swarms

St-Onge, David; Côté-Allard, Ulysse; Glette, Kyrre; Gosselin, B; Beltrame, Giovanni

doi:10.1145/3323213

Cited by 14 publications

(2 citation statements)

References 52 publications

(41 reference statements)

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“…Information from an IMU system is widely employed in the domain of rehabilitation [27]. Additionally, for dynamic sEMG-based gesture recognition, orientation information from IMU devices can be leveraged to obtain higher performances than with EMG alone [20,28,29]. Furthermore, IMUs have been employed to increase the number of gestures that can be detected by combining the orientation of the forearm with static hand gestures [30,31].…”

Section: The 3dc Armband (Prototype)mentioning

confidence: 99%

A Low-Cost, Wireless, 3-D-Printed Custom Armband for sEMG Hand Gesture Recognition

Côté-Allard

Gagnon-Turcotte

Laviolette

et al. 2019

Sensors

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Wearable technology can be employed to elevate the abilities of humans to perform demanding and complex tasks more efficiently. Armbands capable of surface electromyography (sEMG) are attractive and noninvasive devices from which human intent can be derived by leveraging machine learning. However, the sEMG acquisition systems currently available tend to be prohibitively costly for personal use or sacrifice wearability or signal quality to be more affordable. This work introduces the 3DC Armband designed by the Biomedical Microsystems Laboratory in Laval University; a wireless, 10-channel, 1000 sps, dry-electrode, low-cost (∼150 USD) myoelectric armband that also includes a 9-axis inertial measurement unit. The proposed system is compared with the Myo Armband by Thalmic Labs, one of the most popular sEMG acquisition systems. The comparison is made by employing a new offline dataset featuring 22 able-bodied participants performing eleven hand/wrist gestures while wearing the two armbands simultaneously. The 3DC Armband systematically and significantly ( p < 0.05 ) outperforms the Myo Armband, with three different classifiers employing three different input modalities when using ten seconds or more of training data per gesture. This new dataset, alongside the source code, Altium project and 3-D models are made readily available for download within a Github repository.

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Section: The 3dc Armband (Prototype)mentioning

confidence: 99%

A Low-Cost, Wireless, 3-D-Printed Custom Armband for sEMG Hand Gesture Recognition

Côté-Allard

Gagnon-Turcotte

Laviolette

et al. 2019

Sensors

Self Cite

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“…The most interactive systems come from the HCI field, implementing various modalities for both input (e.g., touch [57,91], mid-air gesture [10,101], direct shape deformation [73,106], wearable glove-like controller [114]) and output (e.g., LEDs [10,57,72], GUI displays [28], vibrotactile feedback [114], haptic patterns [52]). However, even though systems coming from the robotics field rather focus on locomotion, and that reconfiguration is not designed to interact with users, prior robotics work embed sensors to interact with their environment (e.g., temperature sensor [29], ambient light sensor [93]).…”

Section: Interactivity (Interaction)mentioning

confidence: 99%

Molecular HCI

Pruszko

Coutrix

Laurillau

et al. 2021

Proc. ACM Hum.-Comput. Interact.

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Shape-changing User Interfaces attract growing interest in Human-Computer Interaction. Modular robotics offer a great opportunity for their implementation. However, the current theoretical and technical advances of modular robotics are fragmented and little centered on the user. To unify existing work and center future research on the user, we perform a systematic literature review enabling us to build a unifying space for the design of modular shape-changing user interfaces.Our aim is to bridge the gap between HCI and robotics. We relate properties of different domains and identify inconsistencies to structure the design space. Towards this aim, we conduct a thorough cross-disciplinary survey to propose: 1) a set of design properties at the scale of the interface (macro-scale) and at the scale of the modules (micro-scale) and 2) the impact of these properties on each other. This paper can be used to describe and compare existing modular shape-changing UIs and generate new design ideas by building upon knowledge from robotics and HCI.

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