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A Tilt Compensated Haptic Cane for Obstacle Detection

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Ambient Assisted Living (ForItAAL 2016)

Part of the book series: Lecture Notes in Electrical Engineering ((LNEE,volume 426))

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Abstract

Several Electronic Travel Aids (ETA) have been developed to improve the autonomy of impaired people, with specific regard to visually impaired. Such systems often perform a good job in detecting obstacles, identifying services and, generally, obtaining useful information from the surroundings, thus enabling a safe and effective exploitation of the environment. The main drawback of systems developed in the Ambient Assisted Living framework is related to the form and the degree of information provided to the end-user. The arbitrary codifications, often adopted, lead to a diffidence of the user against the proposed solutions. This paper deals with a study on a haptic device aimed to provide the user with information on the presence of obstacles inside the environment. The haptic interface is intended to reproduce the same stimuli provided by a traditional white cane, without any contact with the environment. A real prototype of the system, implemented through a short cane with an embedded smart sensing strategy and an active handle, is presented. The tests performed, with users in good health and blindfolded, confirm the suitability of the proposed solution.

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References

  1. Committee on Vision (1986) Electronic travel aids: new directions for research. National Academy Press, Washington, D.C.

    Google Scholar 

  2. Hersh M, Johnson MA (eds) (2008) Assistive technology for visually impaired and blind people. Springer, London, GB

    Google Scholar 

  3. Bujacz M, Baranski P, Moranski M, Strumillo P, Materka A (2008) Remote mobility and navigation aid for the visually disabled. In: Sharkey PM, Lopes-dos-Santos P, Weiss PL, Brooks AL (eds) Proceedings of 7th international conference on disability, virtual reality and association technologies with art abilitation, Maia, Portugal, 8–11 Sept 2008, pp 263–270

    Google Scholar 

  4. Velázquez R (2010) Wearable assistive devices for the blind. In: Lay-Ekuakille A, Mukhopadhyay SC (eds) Wearable and autonomous biomedical devices and systems for smart environment: issues and characterization. LNEE 75. Springer, Chap. 17, pp 331–349

    Google Scholar 

  5. Farcy R, Bellik Y (2002) Comparison of various interface modalities for a locomotion assistance device. In: Miesenberger K, Klaus J, Zagler W (eds) Computers helping people with special needs. Springer, Berlin, pp 421–428

    Google Scholar 

  6. Andò B, Ascia A (2007) Navigation aids for the visually impaired: from artificial codification to natural sensing. IEEE Mag Instrument Meas 10(3):44–51

    Article  Google Scholar 

  7. Andò B, Baglio S, La Malfa S, Marletta V (2011) Innovative smart sensing solutions for the visually impaired. In: Pereira J (ed) Handbook of research on personal autonomy technologies and disability informatics. Med. Inform. Science, Hershey, PA, pp 60–74

    Google Scholar 

  8. Kay L (1964) An ultrasonic sensing probe as a mobility aid for the blind. Ultrasonics 2:53–59

    Google Scholar 

  9. Kay L (1966) Ultrasonic spectacles for the blind. In: Dufton R (ed) Sensory devices for the blind. St. Dunstans, London

    Google Scholar 

  10. Russell L (1965) Travel path sounder. In: Proceedings: Rotterdam Mobility Research Conference. American Foundation for the Blind, New York

    Google Scholar 

  11. Pressey N (1977) Mowat sensor. Focus 3:35–39

    Google Scholar 

  12. Nye PW (1973) A preliminary evaluation of the bionic instruments-veterans administration, C-4 Laser Cane. National Research Council, Washington, D.C., National Academy of Sciences

    Google Scholar 

  13. Andò B, Graziani S (2009) Multisensor strategies to assist blind people: a clear-path indicator. IEEE Trans Instrument Meas 58(8):2488–2494

    Article  Google Scholar 

  14. Loughborough W (1979) Talking lights. J Vis Impairment Blindness

    Google Scholar 

  15. Gemperle F, Ota N, Siewiorek D (2001) Design of a wearable tactile display. In: Proceedings of 5th international symposium on wearable computers, Zurich, CH, pp 5–12

    Google Scholar 

  16. Wang Y, Kuchenbecker KJ (2012) HALO: haptic alerts for low-hanging obstacles in white cane navigation. In: IEEE haptics symposium, Vancouver, BC, 4–7 Mar 2012, pp 527–532

    Google Scholar 

  17. Meijer P (1992) An experimental system for auditory image representations. IEEE Trans Biomed Eng 39(2):112–121

    Article  Google Scholar 

  18. Velazquez R, Fontaine E, Pissaloux E (2006) Coding the environment in tactile maps for real-time guidance of the visually impaired. In: Proceedings of IEEE international symposium on micro-nanomechatronics and human science, Nagoya, Japan, 5–8 Nov 2006, pp 1–6

    Google Scholar 

  19. Prudhvi BR, Bagani R (2013) Silicon eyes: GPS-GSM based navigation assistant for visually impaired using capacitive touch braille keypad and smart SMS facility. In: 2013 world congress on computer and information technology (WCCIT), Sousse, 22–24 June 2013, pp 1–3

    Google Scholar 

  20. Ahmetovic D (2013) Smartphone-assisted mobility in urban environments for visually impaired users through computer vision and sensor fusion. In: 2013 IEEE 14th international conference on mobile data management, Milan 3–6 June 2013, pp 15–18

    Google Scholar 

  21. Tahat AA (2009) A wireless ranging system for the blind long-cane utilizing a smart-phone. In: 10th inteneration conference on telecommunications, ConTEL 2009, Zagreb, 8–10 June 2009, pp 111–117

    Google Scholar 

  22. Bujacz M, Baranski P, Moranski M, Strumillo P, Materka A (2008) Remote guidance for the blind—a proposed teleassistance system and navigation trials. In: 2008 conference on human system interactions, Krakow, 25–27 May 2008, pp 888–892

    Google Scholar 

  23. El-Koka A, Hwang DK (2012) Advanced electronics based smart mobility aid for the visually impaired society. In: 14th international conference on advanced communication technology (ICACT), Pyeongchang, 19–22 Feb 2012, pp 257–261

    Google Scholar 

  24. Andò B, Baglio S, Marletta V, Pitrone N (2009) A mixed inertial & RF-ID orientation tool for the visually impaired. In: IEEE SSD’09, 6th international multi-conference on systems, signals and devices, Djerba, Tunisia, 23–26 Mar 2009, pp 1–6

    Google Scholar 

  25. Andò B, Baglio S, Lombardo CO, Marletta V (2014) An advanced tracking solution fully based on native sensing features of smartphone. In: IEEE sensors applications symposium (SAS) 2014, Queenstown, New Zealand, 18–20 Feb 2014

    Google Scholar 

  26. Andò B, Baglio S, La Malfa S, Marletta V (2011) A sensing architecture for mutual user-environment awareness case of study: a mobility aid for the visually impaired. IEEE Sens J 11(3):634–640

    Article  Google Scholar 

  27. Andò B, Baglio S, Lombardo CO, Marletta V, Pergolizzi EA, Pistorio A (2013) RESIMA: a new WSN based paradigm to assist weak people in indoor environment. IEEE M&N2013, pp 1–4

    Google Scholar 

  28. Loftin RB (2003) Multisensory perception: beyond the visual in visualization. IEEE J Comput Sci Eng 5(4):56–58

    Google Scholar 

  29. Klatzky RL, Lederman SJ (1999) The haptic glance: a route to rapid object identification and manipulation. In: Gopher D, Koriats A (eds) Attention and performance XVII. Cognitive regulations of performance: interaction of theory and application, Mahwah, NJ, Erlbaum, pp 165–196

    Google Scholar 

  30. Varalakshmi BD, Thriveni J, Venugopal KR, Patnaik LM (2012) Haptics: state of the art survey. IJCSI Int J Comput Sci 9(5, 3):234–244

    Google Scholar 

  31. Panëels S, Roberts JC (2010) Review of designs for haptic data visualization. IEEE Trans Haptics 3(2):119–137

    Google Scholar 

  32. Moustakas K, Nikolakis G, Kostopoulos K, Tzovaras D, Strintzis MG (2007) Haptic rendering of visual data for the visually impaired. IEEE Multimedia 14(1):62–72

    Article  Google Scholar 

  33. Schloerb DW, Lahav O, Desloge JG, Srinivasan MA (2010) BlindAid: virtual environment system for self-reliant trip planning and orientation and mobility training. In: IEEE haptics symposium 2010, Waltham, Massachusetts, USA, 25–26 Mar 2010, pp 363–370

    Google Scholar 

  34. Akhter S, Mirsalahuddin J, Marquina FB, Islam S, Sareen S (2011) A smartphone-based haptic vision substitution system for the blind. In: 2011 IEEE 37th annual northeast bioengineering conference (NEBEC), pp 1–2, Troy, NY, 1–3 Apr 2011

    Google Scholar 

  35. Horvath S, Galeotti J, Bing W, Klatzky R, Siegel M, Stetten G (2014) FingerSight: fingertip haptic sensing of the visual environment. IEEE J Trans Eng Health Med 2

    Google Scholar 

  36. Hayward V, Astley OR, Cruz-Hernandez M, Grant D Robles-De-La-Torre G (2004) Haptic interfaces and devices. Sens Rev 24(1):16–29

    Google Scholar 

  37. Cassidy B, Cockton G, Coventry L (2013) A haptic ATM interface to assist visually impaired users. In: Proceeding of the 15th international ACM SIGACCESS conference on computers and accessibility, pp 1–8

    Google Scholar 

  38. Yoshino K, Shinoda H (2014) Contactless touch interface supporting blind touch interaction by aerial tactile stimulation. IEEE haptics symposium (HAPTICS), Houston, TX, 23–26 Feb 2014, pp 347–350

    Google Scholar 

  39. Patomäki S, Raisamo R, Salo J, Pasto V, Hippula A (2004) Experiences on haptic interfaces for visually impaired young children. In: Proceedings of the 6th international conference on multimodal interfaces (ICMI’04), 13–15 Oct 2004, pp 281–288

    Google Scholar 

  40. Andò B, Baglio S, Lombardo CO, Marletta V (2015) An event polarized paradigm for ADL detection in AAL context. IEEE Trans Instrum Meas 64(7):1814–1825

    Article  Google Scholar 

  41. Andò B, Baglio S, Lombardo CO, Marletta V (2016) A multi-sensor data fusion approach for ADL and fall classification. IEEE Trans Instrum Meas 65(9):1960–1967

    Article  Google Scholar 

  42. Andò B, Baglio S, Lombardo CO, Marletta V, Pergolizzi EA (2015) Fall & ADL detection methodologies for AAL. In: Proceedings of the second national conference on sensors, Roma 19–21 Feb 2014. Lecture notes in electrical engineering, vol 319. Springer, pp 427–432

    Google Scholar 

  43. Andò B, Baglio S, Pitrone N (2008) A contactless haptic cane for blind people. In: Proceedings of 12th IMEKO TC1 & TC7 joint symposium on man science and measurement, 3–5 Sept 2008, Annecy, France, pp 147–152

    Google Scholar 

  44. Andò B, Baglio S, Lombardo CO, Marletta V, Pergolizzi E, Pistorio A, Valastro A (2015) An electronic cane with a haptic interface for mobility tasks. In: Andò B, Siciliano P, Marletta V, Monteriù A (eds) Ambient assisted living, Italian forum 2014, biosystems and biorobotics. Springer, pp 189–200

    Google Scholar 

  45. Andò B, Baglio S, Marletta V, Valastro A (2015) A haptic solution to assist visually impaired in mobility tasks. IEEE Trans Hum-Mach Syst 45(5):641–646

    Article  Google Scholar 

  46. Andò B, Baglio S, Bulsara AR, Marletta V, Medico I, Medico S (2013) A double piezo—snap through buckling device for energy harvesting. In: IEEE 17th international conference on solid-state sensors, actuators and microsystems (TRANSDUCERS & EUROSENSORS XXVII), Barcelona, 16–20 June 2013, pp 43–45

    Google Scholar 

  47. Andò B, Baglio S, Bulsara AR, Marletta V (2013) A bistable buckled beam based approach for vibrational energy harvesting. Sens Actuators, A 211:153–161

    Article  Google Scholar 

  48. Andò B, Baglio S, Bulsara AR, Marletta V, Ferrari V, Ferrari M (2015) A low-cost snap-through buckling inkjet printed device for vibrational energy harvesting. IEEE Sens J 15(6):3209–3220

    Article  Google Scholar 

  49. Andò B, Baglio S, Bulsara AR, Marletta V (2014) A wireless sensor node powered by nonlinear energy harvester. IEEE Sensors 2014, Valencia, Spain, 2–5 Nov 2014

    Google Scholar 

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Author information

Authors and Affiliations

  1. DIEEI—University of Catania, v.le A. Doria 6, 95125, Catania, Italy

    Bruno Andò, Salvatore Baglio, Vincenzo Marletta & Angelo Valastro

Authors
  1. Bruno Andò
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  2. Salvatore Baglio
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  3. Vincenzo Marletta
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  4. Angelo Valastro
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Corresponding author

Correspondence to Bruno Andò .

Editor information

Editors and Affiliations

  1. Scuola Superiore Sant'Anna , Pontedera, Italy

    Filippo Cavallo

  2. DIEEI, Università degli Studi di Catania , Catania, Italy

    Vincenzo Marletta

  3. Università Politecnica delle Marche , Ancona, Italy

    Andrea Monteriù

  4. Campus Ekotecne, IMM-CNR, Lecce, Italy

    Pietro Siciliano

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Andò, B., Baglio, S., Marletta, V., Valastro, A. (2017). A Tilt Compensated Haptic Cane for Obstacle Detection. In: Cavallo, F., Marletta, V., Monteriù, A., Siciliano, P. (eds) Ambient Assisted Living. ForItAAL 2016. Lecture Notes in Electrical Engineering, vol 426. Springer, Cham. https://doi.org/10.1007/978-3-319-54283-6_11

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  • DOI: https://doi.org/10.1007/978-3-319-54283-6_11

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  • Publisher Name: Springer, Cham

  • Print ISBN: 978-3-319-54282-9

  • Online ISBN: 978-3-319-54283-6

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