Abstract
This paper discusses a couple of issues that are at the center of discussions in the development of advanced driver assistance systems (ADAS) and their effects from the viewpoints of the joint cognitive systems. The first is the issue of authority and responsibility. It is argued that machine may be given authority to improve safety and to alleviate possible damages, even in the framework of human-centered automation. The second is the issue of the overtrust in and overreliance on ADAS, in which it is argued that possibilities and types of overtrust or overreliance may vary depending on characteristics of ADAS. The importance of the design of human–machine interface and human–machine interactions is included in the discussions.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles and news from researchers in related subjects, suggested using machine learning.References
Billings CE (1992) Human-centered aircraft automation: a concept and guidelines (NASA Techn. Mem. 103885). NASA-Ames Research Center, Mountain View
Billings CE (1997) Aviation automation—the search for a human-centered approach. LEA, Mahwah
Cacciabue PC (2004) Guide to applying human factors methods: human error and accident management in safety critical systems. Springer, Berlin
Convention on Road Traffic (1968) 1993 version & amendments in 2006
Endsley MR, Kiris EO (1995) The out-of-the-loop performance problem and the level of control in automation. Hum Factors 37(2):3181–3194
Flight International (2006, March 22). Airbus studies emergency traffic avoidance system to act without pilots
Flight International (2009, August 18–24). XWB could auto descend in cabin pressure emergency
Hollnagel E (1999) From function allocation to function congruence. In: Dekker SWA, Hollnagel E (eds) Coping with computers in the cockpit. Ashgate, London, pp 29–53
Hollnagel E (2003) Prologomenon to cognitive task design. In: Hollnagel E (ed) Handbook of cognitive task design. LEA, Mahwah, pp 3–15
Hollnagel E (2006) A function-centred approach to joint driver-vehicle system design. Cogn Tech Work 8(3):169–173
Hollnagel E, Bye A (2000) Principles for modeling function allocation. Int J Human–Comp Stud 52:253–265
Hollnagel E, Woods DD (2005) Joint cognitive systems: foundations of cognitive systems engineering. CRC Press, Boca Raton
ICAO (1998) Human factors training manual (Doc 9683-AN/950)
Inagaki T (1993) Situation-adaptive degree of automation for system safety. In: Proceedings 2nd IEEE international workshop on robot and human communication, pp 231–236
Inagaki T (2000a) Situation-adaptive autonomy: dynamic trading of authority between human and automation. In: Proceedings of HFES 44th annual meeting, pp 3.13–3.16
Inagaki T (2000b) Situation-adaptive autonomy for time-critical takeoff decisions. Int J Modell Simul 20(2):175–180
Inagaki T (2003) Adaptive automation: sharing and trading of control. In: Hollnagel E (ed) Handbook of cognitive task design. LEA, Mahwah, pp 147–169
Inagaki T (2006) Design of human–machine interactions in light of domain-dependence of human-centered automation. Cogn Tech Work 8(3):161–167
Inagaki T, Furukawa H (2004) Computer simulation for the design of authority in the adaptive cruise control systems under possibility of driver’s over-trust in automation. In: Proceedings of the IEEE SMC conference, pp 3932–3937
Inagaki T, Inoue K (1993) Adaptive choice of a safety management scheme upon an alarm under supervisory control of a large-complex system. Reliab Eng Syst Saf 31(1):81–87
Inagaki T, Itoh M (2010) Theoretical framework for analysis and evaluation of human’s overtrust in and overreliance on advanced driver assistance systems. In: Proceedings of the European conference on human centered design for intelligent transport systems (to appear)
Inagaki T, Sheridan TB (2008) Authority and responsibility in human–machine systems: is machine-initiated trading of authority permissible in the human-centered automation framework? In: Proceedings of the applied human factors and ergonomics 2008 (CD-ROM), 10 p
Inagaki T, Stahre J (2004) Human supervision and control in engineering and music: similarities, dissimilarities, and their implications. Proc IEEE 92(4):589–600
Inagaki T, Takae Y, Moray N (1999) Automation and human interface for takeoff safety. In: Proceedings of the tenth international symposium on aviation psychology, pp 402–407
Inagaki T, Itoh M, Nagai Y (2006) Efficacy and acceptance of driver support under possible mismatches between driver’s intent and traffic conditions. In: Procedings of the HFES 50th annual meeting, pp 280–283
Inagaki T, Itoh M, Nagai Y (2007a) Driver support functions under resource-limited situations. In: Proceedings of the HFES 51st annual meeting, pp 176–180
Inagaki T, Itoh M, Nagai Y (2007b) Support by warning or by action: which is appropriate under mismatches between driver intent and traffic conditions? IEICE Trans Fundam E90-A(11):264–272
Klein G (1993) A recognition-primed decision (RPD) model of rapid decision making. In: Klein G et al (eds) Decision making in action. Ablex, New York, pp 138–147
Lee JD, Moray N (1992) Trust, control strategies and allocation of function in human-machine systems. Ergonomics 35(10):1243–1270
Moray N, Inagaki T, Itoh M (2000) Adaptive automation, trust, and self-confidence in fault management of time-critical tasks. J Exp Psychol Appl 6(1):44–58
Parasuraman R, Riley V (1997) Humans and automation: use, misuse, disuse, abuse. Hum Factors 39(2):230–253
Parasuraman R, Bhari T, Deaton JE, Morrison JG, Barnes M (1992) Theory and design of adaptive automation in aviation systems (Progress Rep. No. NAWCADWAR-92033-60). Naval Air Development Center Aircraft Division
Sarter NB, Woods DD (1995) How in the world did we ever get into that mode? Mode error and awareness in supervisory control. Hum Factors 37(1):5–19
Sarter NB, Woods DD, Billings CE (1997) Automation surprises. In: Salvendy G (ed) Handbook of human factors and ergonomics, 2nd edn. Wiley, New York, pp 1926–1943
Scerbo MW (1996) Theoretical perspectives on adaptive automation. In: Parasuraman R, Mouloua M (eds) Automation and human performance. LEA, Mahwah, pp 37–63
Scerbo MW, Freeman FG, Mikulka PJ, Parasuraman R, Di Nocero F, Prinzel LJ III (2001) The efficacy of psychophysiological measures for implementing adaptive technology. NASA/TP-2001-211018
Sheridan TB (1992) Telerobotics, automation, and human supervisory control. MIT Press, Cambridge
Sheridan TB (2002) Humans and automation: system design and research issues. Human Factors and Ergonomics Society & Wiley, Santa Monica & New York
Sheridan TB, Ferrel WR (1974) Man–machine systems. MIT Press, Cambridge
Wickens CD (1994) Designing for situation awareness and trust in automation. In: Proceedings of IFAC integrated systems engineering, pp 77–82
Woods D (1989) The effects of automation on human’s role: experience from non-aviation industries. In: Norman S, Orlady H (eds) Flight deck automation: promises and realities (NASA CR-10036). NASA-Ames Research Center, Mountain View, pp 61–85
Woods DD, Hollnagel E (2006) Joint cognitive systems: patterns in cognitive systems engineering. CRC Press, Boca Raton
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Inagaki, T. Traffic systems as joint cognitive systems: issues to be solved for realizing human-technology coagency. Cogn Tech Work 12, 153–162 (2010). https://doi.org/10.1007/s10111-010-0143-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10111-010-0143-6