Abstract
The present work describes the virtual prototyping procedure of car turn-signal switches using a dedicated haptic feedback system. Although turn-signal switches have mechanisms with simple geometry, simulating the “feeling” during its operation is still a challenge. In order to allow ergonomics designers to directly assess the comfort of operation, a dedicated haptic system was developed for reproducing the force feedback that would characterize a real turn-signal switch. For the accurate haptic feedback generation and rendering purpose, a detailed computer-aided design model of the switch was developed together with a multibody simulation. For the design purpose a novel method for the synthesis of the cam mechanism was also developed, starting from an imposed force profile that was previously validated on the haptic device, for which the cam geometry is determined. Thus, the proposed approach enables the designer to also design the “feel” of the switch, and directly manufacture a good model, simplifying the usual iterative process necessary to implement the desired force profile. Finally, an example of virtual prototyping of a turn-signal switch is presented demonstrating the usability of the proposed method and the haptic system.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Burnett GE, Porter JM (2001) Ubiquitous computing within cars: designing controls for non-visual use. Int J Hum Comput Stud 55(4):521–531
Moreau G, Fuchs P, Stergiopoulos P (2004) Applications of virtual reality in the manufacturing industry: from design review to ergonomic studies. Mec Ind 5(2):171–179
Canfield T, Disz T, Papka M, Stevens R, Huang M, Taylor V, Chen J (1996) Toward realtime interactive virtual prototyping of mechanical systems: experiences coupling virtual reality with finite element analysis. In: High performance computing conference 1996, New Orleans
Van der Auweraer H, Donders S, Mas P, Janssens K (2007) Breakthrough technologies for virtual prototyping of automotive and aerospace structures. In: ASI on product engineering: tools and methods based on virtual reality (Series: Intelligent Systems, Control and Automation: Science and Engineering), vol 35. Springer, Berlin, pp 397–418
Shigley JE, Mischke CR, Brown TH (2004) Standard handbook of machine design. McGraw-Hill Professional, New York. ISBN 0071441646
Mathew GK, Tesar D (1976) Cam system design: the dynamic synthesis and analysis of the one degree of freedom model, mechanism and machine theory, vol 11. Pergamon Press, London, pp 247–257
Lederer P (1993) Dynamische synthese der übertagungsfunktion eines kurvengetriebes. Mech Mach Theory 28:23–29
Weir DW, Peshkin M, Colgate JE (2004) The haptic profile: capturing the feel of switches. In: Proceedings of the 12th international symposium on haptic interfaces for virtual environment and teleoperator systems, HAPTICS 2004, Chicago, pp 186–193
MacLean KE (1996) Haptic camera: a technique for characterizing and playing back haptic properties of real environments. In: Proceedings of the ASME Dynamic Systems and Control Division, Atlanta, 1996, pp 245–252
Colton MB, Hollerbach, JM (2007) Reality-based haptic force models of buttons and switches. In: IEEE international conference on robotics and automation (ICRA ‘07), Rome
Colton MB, Hollerbach JM (2007) Haptic models of an automotive turn-signal switch: identification and playback results. In: IEEE international conference on robotics and automation (ICRA ‘07), Rome
Swindells C, MacLean KE (2007) Capturing the dynamics of mechanical knobs. In: Proceedings of the 2nd world haptics conference (WHC ‘07), Tsukuba, pp 194–199
Swindells C, Maksakov E, MacLean KE, Chung V (2006) The role of prototyping tools for haptic behavior design. In: Proceedings of IEEE symposium on haptic interfaces for virtual environments and teleoperator systems (HAPTICS 2006), Arlington, pp 161–168
Erdelyi H, Talaba D (accepted) A novel method for the dynamic synthesis of cam mechanisms with imposed driving force profile. Proc Inst Mech Eng C J Mech Eng Sci
Cohen A, Chen E (1999) Six degree-of-freedom haptic system as a desktop virtual prototyping interface. In: Proceedings of the ASME Dynamic Systems and Control Division, Nashville
Rothbart HA (2003) Cam design handbook. McGraw-Hill Professional, New York. ISBN 0071377573
Alexandru P, Talaba D, Alexandru C (2000) Functional design of mechanisms. vol II. Lux Libris Press, Brasov (in Romanian)
Norton R (1992) Design of machinery: an introduction to the synthesis and analysis of mechanisms and machines. McGraw Hill International Editions, New York
Erdelyi H, Cs Antonya, Talaba D (2007) Haptic feedback generation for a car direction indicator switch. In: ASI on product engineering: tools and methods based on virtual reality (Series: Intelligent Systems, Control and Automation: Science and Engineering), vol 35. Springer, Berlin, pp 257–273
Butnaru T, Cs Antonya, Talaba D (2007) A wired haptic system for multimodal VR interaction. In: ASI on product engineering: tools and methods based on virtual reality (Series: Intelligent Systems, Control and Automation: Science and Engineering), vol 35. Springer, Berlin, pp 243–258
Butnaru T (2007) Interfete pentru simularea in realitatea virtuala cu retur de forta a sistemelor mecanice articulate. Ph.D. thesis, Transilvania University of Brasov
Author information
Authors and Affiliations
Corresponding author
Appendix: C ++ program flowchart
Appendix: C ++ program flowchart
Rights and permissions
About this article
Cite this article
Erdelyi, H., Talaba, D. Virtual prototyping of a car turn-signal switch using haptic feedback. Engineering with Computers 26, 99–110 (2010). https://doi.org/10.1007/s00366-009-0152-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00366-009-0152-3