References
- Bell, A. P. (2014). Guitars have disabilities: Exploring guitar adaptations for an adolescent with Down syndrome. British Journal of Music Education, 31, 343–357.
- Bretan, M., & Weinberg, G. (2016). A survey of robotic musicianship. Communications of the ACM, 59, 100-109.
- Burland, K., & Magee, W. (2014). Developing identities using music technology in therapeutic settings. Psychology of Music, 42, 177–189.
- Chadefaux, D., Le Carrou, J. L., Vitrani, M. A., Billout, S., & Quartier, L. (2012). Harp plucking robotic finger. IEEE International Conference on Intelligent Robots and Systems (pp. 4886–4891), Algarve, Portugal.
- Hainisch, R., & Platz, M. (2007). Phonetic control: A new approach for continuous, non-invasive device control using the vocal tract. 2007 IEEE 10th International Conference on Rehabilitation Robotics, ICORR’07, Noordwijk, The Netherlands. pp. 688–692.
- Harrison, P. M. C., Collins, T., & Müllensiefen, D. (2017). Applying modern psychometric techniques to melodic discrimination testing: Item response theory, computerised adaptive testing, and automatic item generation. Scientific Reports,7,3618.
- Hove, M. J., Marie, C., Bruce, I. C., & Trainor, L. J. (2014). Superior time perception for lower musical pitch explains why bass-ranged instruments lay down musical rhythms. Proceedings of the National Academy of Sciences, 111, 10383–10388.
- Hunt, A., Kirk, R., & Neighbour, M. (2004). Multiple media interfaces for music therapy. IEEE Multimedia, 11, 50–58.
- Jordà, S. (2002). Afasia: the Ultimate Homeric One-man-multimedia-band. Proceedings of the International Conference on New Interfaces for Musical Expression, Dublin, Ireland. pp. 102–107.
- Kapur, A. (2005). A history of robotic musical instruments. Proceedings of the International Computer Music Conference, Barcelona, Spain. pp. 21–28.
- Katan, S., Grierson, M., & Fiebrink, R. (2015). Using interactive machine learning to support interface development through workshops with disabled people. Seoul, Republic of Korea: CHI.
- Larsen, J. V., Overholt, D. & Moeslund, T. B. (2014). The actuated guitar: Implementation and user test on children with hemiplegia. NIME ’14 Proceedings of the 2014 Conference on New Interfaces for Musical Expression, London, UK. pp. 60–65.
- Larsen, J. V., Overholt, D. & Moeslund, T. B. (2016). The prospects of musical instruments for people with physical disabilities. NIME ’16 Proceedings of the 2016 Conference on New Interfaces for Musical Expression, Brisbane, Australia. pp. 327–331.
- Lin, H. W. J., Aflatoony, L., & Wakkary, R. (2014). Design for one: A game controller for a quadriplegic gamer. Conference on Human Factors in Computing Systems - Proceedings, Ontario, Canada. pp. 1243–1248.
- Linn, R. (2013). LinnStrument and other new expressive musical controllers. The Journal of the Acoustical Society of America, 134, 4053–4053.
- Majaranta, P. (Ed.). (2011). Gaze Interaction and Applications of Eye Tracking: Advances in Assistive Technologies: Advances in Assistive Technologies. Hershey, PA: IGI Global.
- Matossian, V., & Gehlhaar, R. (2015). Human Instruments: Accessible Musical Instruments for People with Varied Physical Ability. Studies in Health Technology and Informatics, 219, 202–207.
- McCloskey, B., Bridges, B., & Lyons, F. (2015). Accessibility and dimensionality: Enhanced real time creative independence for digital musicians with quadriplegic cerebral palsy. Proceedings NIME, 24–27, Baton Rouge, LA.
- McPherson, A. P., Jack, R. H., & Moro, G. (2016). Action-sound latency: Are our tools fast enough? Proceedings of the International Conference on New Interfaces for Musical Expression, Brisbane, Australia.
- McPherson, A. P., & Zappi, V. (2015). An environment for submillisecond-latency audio and sensor processing on BeagleBone Black. Audio Engineering Society 138th Convention, Audio Engineering Society. (pp. 4–9)
- McVay, J., Carnegie, D., & Murphy, J. (2015). An overview of MechBass: a four string robotic bass guitar. In 6th International Conference 2015 on Automation, Robotics and Applications (ICARA) (pp. 179–184). Queenstown, New Zealand: IEEE.
- Meckin, D., & Bryan-kinns, N. (2013). moosikMasheens : Music, motion and narrative with young people who have complex needs. New York, NY: IDC, pp. 66–73.
- Nayak, S., Wheeler, B. L., Shiflett, S. C., & Agostinelli, S. (2000). Effect of music therapy on mood and social interaction among individuals with acute traumatic brain injury and stroke. Rehabilitation Psychology, 45, 274–283.
- Norman, D. (2013). The design of everyday things: Revised and expanded edition. Azusa, CA: Basic Books.
- Särkämö, T., Tervaniemi, M., Laitinen, S., Forsblom, A., Soinila, S., Mikkonen, M., ... Hietanen, M. (2008). Music listening enhances cognitive recovery and mood after middle cerebral artery stroke. Brain, 131, 866–876.
- Shibuya, K., Ideguchi, H., Ikushima, K., Cho, J., Kato, S., Kanoh, M., ... Takanishi, A. (2012). Volume control by adjusting wrist moment of violin-playing robot. International Journal of Synthetic Emotions, 3, 31–47.
- Snedeker, J. P. (2005). Adaptive engineering for musical instruments. Medical Problems of Performing Artists, 20, 89–99.
- Swingler, T. (1998). The invisible keyboard in the air : An overview of the educational, therapeutic and creative applications of the EMS Soundbeam. Proceedings of the 2nd European Conference on Disability, Virtual Reality and Associated Technologies, Sk\"{o}vde, Sweden. pp. 253-259
- Vindriis, R. G., & Carnegie, D. A. (2011). A comparison of pick-based strategies for robotic bass playing., 1, 21–22.
- Wessel, D., & Wright, M. (2002). Problems and prospects for intimate musical control of computers. Computer Music journal, 26, 11–14.
- Westerlund, H. (2006). Garage rock bands: a future model for developing musical expertise? International Journal of Music Education, 24, 119–125.