Monitor haptyczny zbudowany w oparciu o system dysz powietrznych z zaworami termobimetalicznymi

• Autorzy: Ligęza Paweł

Warianty tytułu

EN

Haptic monitor built on the basis of a system of air nozzles with thermobimetallic valves

• Języki publikacji: PL

Abstrakty

PL

Systemy haptyczne to urządzenia pobudzające zmysł dotyku. Oddziaływają one na receptory somatosensoryczne skóry organizmów żywych. Monitory haptyczne stanowią układy wyjściowe urządzeń technicznych, umożliwiające przekazanie informacji i komunikację z odbiorcą, w szczególności z człowiekiem. W monitorach haptycznych istotna jest możliwość przekazania odpowiednio dużej ilości informacja w sposób precyzyjny i jednoznaczny. Bodźce powinny być dobrze wyczuwalne, z możliwością lokalizacji położenia bodźca i jego amplitudy. Monitory haptyczne w zależności od przeznaczenia i wymaganych właściwości oraz parametrów wykorzystują różnorodne źródła bodźca dotykowego. W artykule przedstawiono koncepcję nowatorskiego monitora haptycznego przekazującego informację za pomocą sterowanych strumieni powietrza.

EN

Haptic systems are devices that stimulate the sense of touch. They affect the somatosensory receptors of the skin of living organisms. Haptic monitors are the output systems of technical devices, enabling the transfer of information and communication with the recipient, in particular with a human being. In haptic monitors, it is important to be able to convey a sufficiently large amount of information in a precise and unambiguous way. The stimuli should be clearly perceptible, with the ability to localize the location of the stimulus and its amplitude. Haptic monitors, depending on the purpose and the required properties and parameters, use various sources of tactile stimulus. The article presents the concept of an innovative haptic monitor transmitting information by means of controlled air streams.

Słowa kluczowe

PL

haptyka; zmysł dotyku; transfer informacji maszyna – człowiek; monitor haptyczny; dysza powietrzna; zawory termo bimetaliczne

EN

haptic; sense of touch; machine-human information transfer; haptic monitor; air jets; thermal bimetallic valves

• Wydawca: Instytut Mechaniki Górotworu PAN
• Czasopismo: Prace Instytutu Mechaniki Górotworu PAN
• Rocznik: 2022
• Tom: T. 24, nr 1-4
• Strony: 21--26
• Opis fizyczny: Bibliogr. 35 poz., rys.

Twórcy

autor

Ligęza Paweł

• Instytut Mechaniki Górotworu PAN, ul. Reymonta 27; 30-059 Kraków

• https://orcid.org/0000-0002-2865-4001

Bibliografia

• [1] Jenkins, B.A., & Lumpkin, E.A. (2017). Developing a sense of touch. Development, 144 (22), 4078-4090.
• [2] Lederman, S.J., & Klatzky, R.L. (2009). Haptic perception: A tutorial. Attention, Perception, & Psychophysics, 71 (7), 1439-1459.
• [3] Steinbach, E., Hirche, S., Ernst, M., Brandi, F., Chaudhari, R., Kammerl, J., & Vittorias, I. (2012). Haptic communications. Proceedings of the IEEE, 100 (4), 937-956.
• [4] Adams, R.J., & Hannaford, B. (1999). Stable haptic interaction with virtual environments. IEEE Transactions on robotics and Automation, 15 (3), 465-474.
• [5] Sreelakshmi, M., & Subash, T.D. (2017). Haptic technology: A comprehensive review on its applications and future prospects. Materials Today: Proceedings, 4 (2), 4182-4187.
• [6] Pleger, B., & Villringer, A. (2013). The human somatosensory system: from perception to decision making. Progress in neurobiology, 103, 76-97.
• [7] Hendry, S., & Hsiao, S. (2013). The somatosensory system. In Fundamental Neuroscience: Fourth Edition (pp. 531-551). Elsevier Inc.
• [8] Wang, H., & Kosuge, K. (2012). Control of a robot dancer for enhancing haptic human-robot interaction in waltz. IEEE transactions on haptics, 5 (3), 264-273.
• [9] Sreelakshmi, M., & Subash, T.D. (2017). Haptic technology: A comprehensive review on its applications and future prospects. Materials Today: Proceedings, 4 (2), 4182-4187.
• [10] Steinbach, E., Hirche, S., Ernst, M., Brandi, F., Chaudhari, R., Kammerl, J., & Vittorias, I. (2012). Haptic communications. Proceedings of the IEEE, 100 (4), 937-956.
• [11] Akahane, K., Yu, C., Liu, X., & Sato, M. The research of light-weighted finger haptic device using voice coil.
• [12] Seim, C., Chandler, J., DesPortes, K., Dhingra, S., Park, M., & Starner, T. (2014, September). Passive haptic learning of Braille typing. In Proceedings of the 2014 ACM International Symposium on Wearable Computers (pp. 111-118).
• [13] Paneva, V., Seinfeld, S., Kraiczi, M., & Müller, J. (2020, July). HaptiRead: Reading Braille as mid-air haptic information. In Proceedings of the 2020 ACM Designing Interactive Systems Conference (pp. 13-20).
• [14] Bettelani, G.C., Averta, G., Catalano, M.G., Leporini, B., & Bianchi, M. (2020). Design and validation of the readable device: a single-cell electromagnetic refreshable braille display. IEEE transactions on haptics, 13 (1), 239-245.
• [15] Brewster, S. (2017). The impact of haptic ‘touching’technology on cultural applications. In Digital applications for cultural and heritage institutions (pp. 301-312). Routledge.
• [16] Dima, M., Hurcombe, L., & Wright, M. (2014, June). Touching the past: haptic augmented reality for museum artefacts. In International Conference on Virtual, Augmented and Mixed Reality (pp. 3-14). Springer, Cham.
• [17] Kos, A. Matryca dotykowa dla osób niewidomych, (2010) Patent PL 20 6784 B1, UPRP.
• [18] Visell, Y., Giordano, B. L., Millet, G., & Cooperstock, J.R. (2011). Vibration influences haptic perception of surface compliance during walking. PLoS one, 6 (3), e17697.
• [19] Hwang, J., & Hwang, W. (2011). Vibration perception and excitatory direction for haptic devices. Journal of Intelligent Manufacturing, 22 (1), 17-27.
• [20] Jayant, C., Acuario, C., Johnson, W., Hollier, J., & Ladner, R. (2010, October). V-braille: haptic braille perceptron using a touch-screen and vibration on mobile phones. In Proceedings of the 12th international ACM SIGACCESS conference on Computers and accessibility (pp. 295-296).
• [21] Dangxiao, W., Yuan, G.U.O., Shiyi, L.I.U., Zhang, Y., Weiliang, X., & Jing, X. (2019). Haptic display for virtual reality: progress and challenges. Virtual Reality & Intelligent Hardware, 1 (2), 136-162.
• [22] Wu, C.M., Hsu, C.W., Lee, T.K., & Smith, S. (2017). A virtual reality keyboard with realistic haptic feedback in a fully immersive virtual environment. Virtual Reality, 21 (1), 19-29.
• [23] Schmidt-Skipiol, F.J., & Hecker, P. (2015). Tactile Feedback and Situation Awareness-Improving Adherence to an Envelope in Sidestick-Controlled Fly-by-Wire Aircrafts. In 15th AIAA Aviation Technology, Integration, and Operations Conference (p. 2905).
• [24] Van Baelen, D., van Paassen, M.M., Ellerbroek, J., Abbink, D.A., & Mulder, M. (2021). Flying by feeling: Communicating flight envelope protection through haptic feedback. International Journal of Human-Computer Interaction, 37 (7), 655-665.
• [25] Ciáurriz, P., Díaz, I., & Gil, J.J. (2013, October). Bimanual drive-by-wire system with haptic feedback. In 2013 IEEE International Symposium on Haptic Audio Visual Environments and Games (HAVE) (pp. 18-23). IEEE.
• [26] Escobar-Castillejos, D., Noguez, J., Neri, L., Magana, A., & Benes, B. (2016). A review of simulators with haptic devices for medical training. Journal of medical systems, 40 (4), 1-22.
• [27] Ullrich, S., & Kuhlen, T. (2012). Haptic palpation for medical simulation in virtual environments. IEEE Transactions on Visualization and Computer graphics, 18 (4), 617-625.
• [28] Amirabdollahian, F., Livatino, S., Vahedi, B., Gudipati, R., Sheen, P., Gawrie-Mohan, S., & Vasdev, N. (2018). Prevalence of haptic feedback in robot-mediated surgery: a systematic review of literature. Journal of Robotic Surgery, 12 (1), 11-25.
• [29] Endo, T., Kawasaki, H., Mouri, T., Ishigure, Y., Shimomura, H., Matsumura, M., & Koketsu, K. (2010). Five-fingered haptic interface robot: HIRO III. IEEE Transactions on Haptics, 4 (1), 14-27.
• [30] Katila, J., Gan, Y., & Goodwin, M.H. (2020). Interaction rituals and ‘social distancing’: New haptic trajectories and touching from a distance in the time of COVID-19. Discourse Studies, 22 (4), 418-440.
• [31] Ligęza P. Monitor haptyczny. (2022) Zgłoszenie Patentowe P – 442165, UPRP
• [32] Ligęza, P. (2001). Układy termoanemometryczne-struktura, modelowanie, przyrządy i systemy pomiarowe (Doctoral dissertation, Akademii Górniczo-Hutniczej im. S. Staszica w Krakowie).
• [33] Ligęza, P., Poleszczyk, E., & Skotniczny, P. (2008). Measurements of velocity profile in headings with the use of integrated hot-wire anemometric system. Archives of Mining Sciences, 53 (1), 87-96.
• [34] Ligęza, P., Poleszczyk, E., & Skotniczny, P. (2009). Method and the system of spatial measurement of velocity field of air flow in a mining heading. Archives of Mining Sciences, 54 (3), 419-440.
• [35] Ligęza, P. (2020). Static and dynamic parameters of hot-wire sensors in a wide range of filament diameters as a criterion for optimal sensor selection in measurement process. Measurement, 151, 107177.