How ADAS alert resources match the Driver-Vehicle-Environment system model: an analysis of co-design data
Resumo
Driver behavior and interaction with Advanced Driver Assistance Systems (ADAS) play a vital role in realizing their full safety potential. In light of this, in-depth studies on the user experience (UX) of ADAS are of paramount importance to achieve the expected improvements in road safety. The Driver-Vehicle-Environment (DVE) system model integrates human perspectives with vehicle dynamics and environmental factors to provide insights into the interactions within this system. In this paper, we analyze the elements of ADAS alert prototypes proposed in co-design sessions. Our main goal was to check whether these proposals considered important elements of the DVE model. As a contribution, we pointed out elements that could be further explored in co-design sessions of ADAS.Referências
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Birrell, S. A., Fowkes, M., and Jennings, P. A. (2014). Effect of using an in-vehicle smart driving aid on real-world driver performance. IEEE Transactions on Intelligent Transportation Systems, 15(4):1801–1810.
Cacciabue, P. C. and Saad, F. (2008). Behavioural adaptations to driver support systems: a modelling and road safety perspective. Cognition, Technology & Work, 10(1):31–39.
Cicchino, J. B. (2018). Effects of blind spot monitoring systems on police-reported lane-change crashes. Traffic Injury Prevention, 19(6):615–622. PMID: 29927678.
Frison, A.-K., Wintersberger, P., Liu, T., and Riener, A. (2019). Why do you like to drive automated? a context-dependent analysis of highly automated driving to elaborate requirements for intelligent user interfaces. In Proceedings of the 24th International Conference on Intelligent User Interfaces, IUI ’19, page 528–537, New York, NY, USA. Association for Computing Machinery.
Gasser, T. M., Seeck, A., and Walker Smith, B. (2016). Framework conditions for the development of driver assistance systems. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 3, pages 33–68. Springer Cham, Germany, 1 edition.
Kühn, M. and Hannawald, L. (2016). Driver assistance and road safety. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 4, pages 69–90. Springer Cham, Germany, 1 edition.
Li, X., Vaezipour, A., Rakotonirainy, A., Demmel, S., and Oviedo-Trespalacios, O. (2020). Exploring drivers’ mental workload and visual demand while using an in-vehicle hmi for eco-safe driving. Accident Analysis Prevention, 146:105756.
Lisboa, P., Dos Santos, F., Ribeiro, H., Campos, P., and Zaina, L. (2023). Making roads safer: a vehicle blind spot alert system co-designed with end-users. In Proceedings of the XXII Brazilian Symposium on Human Factors in Computing Systems, IHC ’23, New York, NY, USA. Association for Computing Machinery.
Orlovska, J., Novakazi, F., Lars-Ola, B., Karlsson, M., Wickman, C., and Söderberg, R. (2020). Effects of the driving context on the usage of automated driver assistance systems (adas) - naturalistic driving study for adas evaluation. Transportation Research Interdisciplinary Perspectives, 4:100093.
SAE International (2021). Taxonomy and definitions for terms related to driving automation systems for on-road motor vehicles. Technical report, Society of Automobile Engineers.
Weller, G. and Schlag, B. (2016). Behavioral aspects of driver assistance systems. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 5, pages 91–107. Springer Cham, Germany, 1 edition.
Antony, M. M. and Whenish, R. (2021). Advanced Driver Assistance Systems (ADAS), pages 165–181. Springer International Publishing, Cham.
Birrell, S. A., Fowkes, M., and Jennings, P. A. (2014). Effect of using an in-vehicle smart driving aid on real-world driver performance. IEEE Transactions on Intelligent Transportation Systems, 15(4):1801–1810.
Cacciabue, P. C. and Saad, F. (2008). Behavioural adaptations to driver support systems: a modelling and road safety perspective. Cognition, Technology & Work, 10(1):31–39.
Cicchino, J. B. (2018). Effects of blind spot monitoring systems on police-reported lane-change crashes. Traffic Injury Prevention, 19(6):615–622. PMID: 29927678.
Frison, A.-K., Wintersberger, P., Liu, T., and Riener, A. (2019). Why do you like to drive automated? a context-dependent analysis of highly automated driving to elaborate requirements for intelligent user interfaces. In Proceedings of the 24th International Conference on Intelligent User Interfaces, IUI ’19, page 528–537, New York, NY, USA. Association for Computing Machinery.
Gasser, T. M., Seeck, A., and Walker Smith, B. (2016). Framework conditions for the development of driver assistance systems. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 3, pages 33–68. Springer Cham, Germany, 1 edition.
Kühn, M. and Hannawald, L. (2016). Driver assistance and road safety. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 4, pages 69–90. Springer Cham, Germany, 1 edition.
Li, X., Vaezipour, A., Rakotonirainy, A., Demmel, S., and Oviedo-Trespalacios, O. (2020). Exploring drivers’ mental workload and visual demand while using an in-vehicle hmi for eco-safe driving. Accident Analysis Prevention, 146:105756.
Lisboa, P., Dos Santos, F., Ribeiro, H., Campos, P., and Zaina, L. (2023). Making roads safer: a vehicle blind spot alert system co-designed with end-users. In Proceedings of the XXII Brazilian Symposium on Human Factors in Computing Systems, IHC ’23, New York, NY, USA. Association for Computing Machinery.
Orlovska, J., Novakazi, F., Lars-Ola, B., Karlsson, M., Wickman, C., and Söderberg, R. (2020). Effects of the driving context on the usage of automated driver assistance systems (adas) - naturalistic driving study for adas evaluation. Transportation Research Interdisciplinary Perspectives, 4:100093.
SAE International (2021). Taxonomy and definitions for terms related to driving automation systems for on-road motor vehicles. Technical report, Society of Automobile Engineers.
Weller, G. and Schlag, B. (2016). Behavioral aspects of driver assistance systems. In Winner, H., Hakuli, S., Lotz, F., and Singer, C., editors, Handbook of Driver Assistance Systems, chapter 5, pages 91–107. Springer Cham, Germany, 1 edition.
Publicado
07/10/2024
Como Citar
CAMILO, Bruna Salvaia; ZAINA, Luciana.
How ADAS alert resources match the Driver-Vehicle-Environment system model: an analysis of co-design data. In: PÔSTERES E DEMONSTRAÇÕES - SIMPÓSIO BRASILEIRO DE FATORES HUMANOS EM SISTEMAS COMPUTACIONAIS (IHC), 23. , 2024, Brasília/DF.
Anais [...].
Porto Alegre: Sociedade Brasileira de Computação,
2024
.
p. 139-143.
DOI: https://doi.org/10.5753/ihc_estendido.2024.243933.
