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Cybathlon

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Logo of CYBATHLON
CYBATHLON - For a world without barriers.

Cybathlon, a project of ETH Zurich, acts as a platform that challenges teams from all over the world to develop assistive technologies suitable for everyday use with and for people with disabilities. The driving force behind CYBATHLON is international competitions and events, in which teams consisting of technology developers from universities, companies or NGOs and a person with disabilities (pilot) tackle unsolved everyday tasks with their latest assistive technologies. Besides the actual competition, the Cybathlon offers a benchmarking platform to drive forward research on assistance systems for dealing with daily-life challenges, and to promote dialogue with the public for the inclusion of people with disabilities in society. The involvement of the pilot is considered essential both to the competition and in the development process, to ensure that the perspective and needs of end users are considered and addressed.[1]

The first Cybathlon organised by the Swiss Federal Institute of Technology in Zurich (ETH Zurich) took place in the Swiss Arena in Kloten north of Zurich in Switzerland on 8 October 2016 and was the first international competition of this kind.[2][3] 66 pilots from 25 nations competed in front of 4600 spectators.[4]

The 2020 Cybathlon "Global edition" took place on 13–14 November 2020. After having first been postponed due to the COVID-19 pandemic[5] it was reorganized to take place remotely, with teams setting up the infrastructure for the competition at their home bases and with the races, overseen by Cybathlon officials, taking place via video.[6][7]

CYBATHLON 2024 is scheduled to take place from 25 to 27 October 2024. The third edition of the CYBATHLON will take place in a global format in the Arena Schluefweg in Kloten near Zurich and in local hubs all around the world. 160 international teams from the worlds of academia and industry will compete in a unique competition.[8]

A survey of pilots and technical leads from 2020 suggests considerable success in including pilots in a user-centered design process. Daily life usage of the new assistive technology was less frequent. Both daily life usage and prolonged user involvement were found to be related to race performance at the competition. [9]

Background

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The World Health Organization (WHO) estimates that around 15% of people (1.1. billion people worldwide) experience some form of disability. Robert Riener, head of the professorship for Sensory-Motor Systems at ETH Zurich, initiated the Cybathlon in 2013 as a platform for the development of everyday-suitable assistance systems.[1]

The event organised under the umbrella of ETH Zurich is supported financially as well as ideologically by partners and through patronage.[10]

Whereas other international competitions for disabled athletes, such as the Paralympics, only permit competitors to use unpowered assistive technology, the Cybathlon encourages the use of performance-enhancing technology such as powered exoskeletons.[3]

Teams can compete in eight different disciplines. A team always consists of a pilot (a person with a disability that meets the inclusion criteria of the respective discipline) and a technology developer (university or company) who work closely together. Teams may include clinicians and other professionals with expertise in areas such as therapy, orthotics and prosthetics.[1] Currently, the split is about 70% with a university and 30% with a company background (e.g. manufacturers of commercially available prostheses).

Disciplines

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The CYBATHLON competition includes competitions in a number of different disciplines, each of which has eligibility criteria specific to the pilot and device. The tasks for each of the CYBATHLON disciplines are chosen to reflect everyday activities that are challenging for people with disabilities. While solving the respective tasks in competition, it is shown how well the developed technology is suited to support the pilot in everyday life. Design of the tasks varies from one competition to the next, with the rule book for the competition being published years in advance to allow time for development. The 2016 and 2020 events included six disciplines.[1] Two further disciplines, Assistance Robot Race and Vision Assistance Race, were added for 2024.[8]

Teams compete on courses designed to test how well suited a given technology is to helping its user with everyday tasks, for example climbing stairs or opening doors. In each discipline several pilots compete simultaneously. The tasks and rules are defined in detail for each of the six disciplines. Most important is that the pilots complete the tasks correct, safe and secure. Time comes in as a secondary factor.[11]

  • Brain-Computer Interface (BCI) Race: In the BCI race, pilots with quadriplegia use brain-computer interfaces to control avatars in a computer game. The aim of this technology is to associate specific mental tasks with distinct behaviors of an external device. An example would be the direction of wheelchairs by people with limited ability to move. Teams in the 2016 and 2020 competitions used surface-based BCIs. Implanted BCI systems will be allowed to participate for the first time in 2024.[1][12]
  • Functional Electrical Stimulation (FES) Bike Race: The FES race is for pilots with paraplegia due to an injury of the central nervous system. A device delivers electrical pulses to muscles to induce contractions. The control system must selectively activate different muscles in a coordinated manner. Functional electrical stimulation enables pilots to perform a pedalling movement on a recumbent bicycle.[1][13]
  • Arm Prosthesis Race: In this race, pilots using an arm prosthesis on one or both sides can compete. Tasks generally involve grasping and manipulation activities, and may also require bimanual coordination or use of a variety of arm postures. The prosthesis has to include the wrist and can be navigated with any kind of control. It can be either body- or externally powered.[1]
  • Leg Prosthesis Race: In this race, pilots using a leg prosthesis on one or both sides, including a knee joint, have to perform various movements. Tasks such as standing up and sitting down and walking on uneven terrain involve aspects of locomotion such as balance, stability, agility, mobility, and precision in stepping. Some tests may involve dual-tasking. Teams can use any kind of prosthetic device, with differing control strategies and actuation and sensing principles.[1]
  • Exoskeleton Race: In this race, pilots with complete thoracic or lumbar spinal cord injury can compete using an exoskeleton. This powered wearable device supports the body and enables types of anthropomorphic motion used in everyday tasks. Tasks include sitting and standing, walking, and climbing stairs.[1]
  • Wheelchair Race: In this race, pilots with severe walking disability can compete using a powered wheelchair. The wheelchairs feature novel technologies for advanced mobility performance to overcome obstacles. Tasks include negotiating steep ramps, staircases, uneven terrain, and confined spaces.[1]
  • Assistance Robot Race: The Race consists of tasks that contain elements of human-robot interaction. Both pilots and robots recognize and manipulate various objects, avoid obstacles and react to some dynamic elements on the track.[8]
  • Vision Assistance Race: The Race includes elements of spatial orientation and personal mobility, such as boarding and leaving a public bus and react to some dynamic elements. Tasks are tackled under a time constraint. Pilots are to recognize the context of a task and avoid obstacles.[8]

Cybathlon 2016

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Medals were awarded to both the pilots themselves and to the companies or institutions that create their bionics.

Competitions were organized in such a way that the participants could demonstrate not only their own skills, but also the distinctive qualities of assistive technologies. For example, in the category of "hand prostheses", competitors attempted several food-related fine motor tasks and in the category "Neuro" the participants managed avatars in a specially designed computer game.[14]

The winners:[14]

  • Brain-Computer Interface Race: Numa Poujouly - Team Brain Tweakers (Switzerland)
  • Functional Electrical Stimulation Bike Race: Mark Muhn - Team Cleveland (US)
  • Arm Prosthesis Race: Robert (Bob) Radocy - Team Dipo Power (Netherlands)
  • Exoskeleton Race: Andre Van Ruschen - Team ReWalk (Germany)
  • Leg Prosthesis Race: Helgi Sveinsson - Team Rheo Knee (Iceland)
  • Wheelchair Race: Florian Hauser - Team HSR Enhanced (Switzerland)[14]

Cybathlon 2020

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Cybathlon 2020 took place on 13 – 14 November 2020 – globally and in a new format, at the teams’ home bases. They set up their infrastructure for the competition and filmed their races. Instead of starting directly next to each other, the pilots started individually and under the supervision of Cybathlon officials. From ETH Zurich, the competitions were broadcast through a new platform in a unique live programme.[5][6]

The winners:

  • Brain-Computer Interface Race: Francesco Bettella – Team WHi (Italy)[15]
  • Functional Electrical Stimulation Bike Race: Sander Koomen – Team PULSE Racing (Netherlands)[16][17]
  • Arm Prosthesis Race: Andrej Đukić – Team Maker Hand (Croatia)[18]
  • Exoskeleton Race: Kim Byeong-Uk – Team Angel Robotics 1 (South Korea)[19]
  • Leg Prosthesis Race: Andre Frei – Team Circleg (Switzerland)[20]
  • Wheelchair Race: Florian Hauser – Team Robility enhanced (Switzerland)[20]

References

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  1. ^ a b c d e f g h i j Jaeger, Lukas; et al. (3 May 2023). "How the CYBATHLON Competition Has Advanced Assistive Technologies". Annual Review of Control, Robotics, and Autonomous Systems. 6: 447–476. doi:10.1146/annurev-control-071822-095355. hdl:20.500.11850/613524. Retrieved 4 May 2023.
  2. ^ "Cybathlon". Cybathlon.ethz.ch. Retrieved 20 October 2014.
  3. ^ a b Jeffries, Adrianne (26 March 2014). "Switzerland to host the first Cybathlon, an Olympics for bionic athletes". The Verge. Retrieved 28 March 2014.
  4. ^ Gassert, Roger; Lambercy, Olivier (16 March 2018). "Insights from the first CYBATHLON". On Medicine. Retrieved 4 May 2023.
  5. ^ a b "Cybathlon 2020 postponed due to coronavirus". Disability Insider. 11 March 2020. Retrieved 4 May 2023.
  6. ^ a b "Cybathlon 2020 Global Edition". Imperial College London. 2020.
  7. ^ Harris, Aaliyah (18 November 2020). "Cybathlon tournament showcases life-changing tech for people with disabilities". CNN. Retrieved 4 May 2023.
  8. ^ a b c d Bleich, Vanessa (2 November 2021). "Cybathlon 2024 to include the visually impaired and robot aides". myScience. Retrieved 4 May 2023.
  9. ^ Meyer, Jan T.; Weber, Selina; Jäger, Lukas; Sigrist, Roland; Gassert, Roger; Lambercy, Olivier (2 April 2022). "A survey on the influence of CYBATHLON on the development and acceptance of advanced assistive technologies". Journal of NeuroEngineering and Rehabilitation. 19 (1): 38. doi:10.1186/s12984-022-01015-5. hdl:20.500.11850/542343. ISSN 1743-0003.
  10. ^ Blickenstaff, Brian Blickenstaff (October 19, 2016). "The Cybathlon: Where Paraplegics Walk Again". Vice. Retrieved 4 May 2023.
  11. ^ "Technology that moves you". Swisstech. December 9, 2020. Retrieved 4 May 2023.
  12. ^ Perdikis, Serafeim; Tonin, Luca; Saeedi, Sareh; Schneider, Christoph; Millán, José del R. (10 May 2018). "The Cybathlon BCI race: Successful longitudinal mutual learning with two tetraplegic users". PLOS Biology. 16 (5): e2003787. doi:10.1371/journal.pbio.2003787. ISSN 1545-7885. PMC 5944920. PMID 29746465.
  13. ^ Hamdan, Puteri Nur Farhana; Hamzaid, Nur Azah; Abd Razak, Nasrul Anuar; Hasnan, Nazirah (1 November 2022). "Contributions of the Cybathlon championship to the literature on functional electrical stimulation cycling among individuals with spinal cord injury: A bibliometric review". Journal of Sport and Health Science. 11 (6): 671–680. doi:10.1016/j.jshs.2020.10.002. ISSN 2095-2546. PMC 9729926. PMID 33068748.
  14. ^ a b c Lewington, Lara (10 October 2016). "Cybathlon: Battle of the bionic athletes". BBC News. Retrieved 4 May 2023.
  15. ^ Pescovitz, David (3 December 2020). "People with quadriplegia use brain-computer interfaces to compete in a cyborg olympics". Boing Boing. Retrieved 4 May 2023.
  16. ^ Docter, Heleen; Podvinšek, Katja; Koomen, Sander; Kaman, Birgit E; Visser, Ilona; Klunder, Niek; van den Berg, Anneloes; Bellens, Laurien; Wijnbelt, Chrétine; Groot, Sterre (3 March 2023). "Practical approaches of PULSE Racing in training their athlete for the Cybathlon Global Edition Functional Electrical Stimulation bike race: a case report". Journal of NeuroEngineering and Rehabilitation. 20 (1): 30. doi:10.1186/s12984-023-01143-6. ISSN 1743-0003. PMC 9983524. PMID 36869321.
  17. ^ "The Cybathlon Global Edition 2020". PULSE Racing. 31 January 2021. Retrieved 4 May 2023.
  18. ^ Pauković, Donatella (29 November 2020). "Andrej Djukic Wants Winning Prosthetic Hand Project to be Available to Everyone". Total Croatia News. Retrieved 4 May 2023.
  19. ^ "A Next Step in Wearable Robotics | RoboticsTomorrow". Robotics Tomorrow. June 30, 2021. Retrieved 4 May 2023.
  20. ^ a b "Smart ArM team develops prosthetics to compete in Cybathlon 2020". The Robot Report. 5 December 2020. Retrieved 4 May 2023.
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