Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator

C.A.J. Hanselaar; Y. Fu; A. Terechko; J. Seemann; T. Beurskens; E. Silvas; W. P.M.H. Heemels

doi:10.1109/IV55156.2024.10588686

Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator

C.A.J. Hanselaar, Y. Fu, A. Terechko, J. Seemann, T. Beurskens, E. Silvas, W. P.M.H. Heemels

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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Abstract

The transition from advanced driver assistance systems to highly automated vehicles proves to be difficult, as the driver is no longer a safety fallback for the latter systems. One of the main challenges is formed by edge cases in the encountered driving scenarios that trigger functional insufficiencies in automated driving (AD) systems. Functional insufficiencies, for the sake of understanding, may be viewed as an inappropriate understanding of or response to a scenario in an AD system, which in turn causes dangerous vehicle behavior. Prior research suggests that using an architecture capable of including redundant heterogeneous AD systems as separate channels, such as the Safety Shell, can mitigate some of these functional insufficiencies. However, this benefit has only been evaluated in limited and deterministic simulation environments. To overcome this, our objectives in this paper are to (i) develop an experimental method for extensive testing of such architectures, and (ii) to assess the suitability of the Safety Shell architecture to handle edge cases with this new method. Using the developed experimental setup we observe a significant safety and availability increase of the Safety Shell compared to the included individual AD channels in the tested scenarios. Finally, our study provides insight into the requirements for the evaluated AD channels.

Original language	English
Title of host publication	35th IEEE Intelligent Vehicles Symposium, IV 2024
Publisher	Institute of Electrical and Electronics Engineers
Pages	1764-1771
Number of pages	8
ISBN (Electronic)	979-8-3503-4881-1
DOIs	https://doi.org/10.1109/IV55156.2024.10588686
Publication status	Published - 15 Jul 2024
Event	35th IEEE Intelligent Vehicles Symposium, IV 2024 - Jeju Island, Korea, Republic of Duration: 2 Jun 2024 → 5 Jun 2024

Conference

Conference	35th IEEE Intelligent Vehicles Symposium, IV 2024
Country/Territory	Korea, Republic of
City	Jeju Island
Period	2/06/24 → 5/06/24

Keywords

Architecture
Automated Vehicles
Faults
Functional Insufficiencies
Safety

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10.1109/IV55156.2024.10588686

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Hanselaar, C. A. J., Fu, Y., Terechko, A., Seemann, J., Beurskens, T., Silvas, E., & Heemels, W. P. M. H. (2024). Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator. In 35th IEEE Intelligent Vehicles Symposium, IV 2024 (pp. 1764-1771). Article 10588686 Institute of Electrical and Electronics Engineers. https://doi.org/10.1109/IV55156.2024.10588686

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title = "Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator",

abstract = "The transition from advanced driver assistance systems to highly automated vehicles proves to be difficult, as the driver is no longer a safety fallback for the latter systems. One of the main challenges is formed by edge cases in the encountered driving scenarios that trigger functional insufficiencies in automated driving (AD) systems. Functional insufficiencies, for the sake of understanding, may be viewed as an inappropriate understanding of or response to a scenario in an AD system, which in turn causes dangerous vehicle behavior. Prior research suggests that using an architecture capable of including redundant heterogeneous AD systems as separate channels, such as the Safety Shell, can mitigate some of these functional insufficiencies. However, this benefit has only been evaluated in limited and deterministic simulation environments. To overcome this, our objectives in this paper are to (i) develop an experimental method for extensive testing of such architectures, and (ii) to assess the suitability of the Safety Shell architecture to handle edge cases with this new method. Using the developed experimental setup we observe a significant safety and availability increase of the Safety Shell compared to the included individual AD channels in the tested scenarios. Finally, our study provides insight into the requirements for the evaluated AD channels.",

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Hanselaar, CAJ, Fu, Y, Terechko, A, Seemann, J, Beurskens, T, Silvas, E & Heemels, WPMH 2024, Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator. in 35th IEEE Intelligent Vehicles Symposium, IV 2024., 10588686, Institute of Electrical and Electronics Engineers, pp. 1764-1771, 35th IEEE Intelligent Vehicles Symposium, IV 2024, Jeju Island, Korea, Republic of, 2/06/24. https://doi.org/10.1109/IV55156.2024.10588686

Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator. / Hanselaar, C.A.J.; Fu, Y.; Terechko, A. et al.
35th IEEE Intelligent Vehicles Symposium, IV 2024. Institute of Electrical and Electronics Engineers, 2024. p. 1764-1771 10588686.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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AB - The transition from advanced driver assistance systems to highly automated vehicles proves to be difficult, as the driver is no longer a safety fallback for the latter systems. One of the main challenges is formed by edge cases in the encountered driving scenarios that trigger functional insufficiencies in automated driving (AD) systems. Functional insufficiencies, for the sake of understanding, may be viewed as an inappropriate understanding of or response to a scenario in an AD system, which in turn causes dangerous vehicle behavior. Prior research suggests that using an architecture capable of including redundant heterogeneous AD systems as separate channels, such as the Safety Shell, can mitigate some of these functional insufficiencies. However, this benefit has only been evaluated in limited and deterministic simulation environments. To overcome this, our objectives in this paper are to (i) develop an experimental method for extensive testing of such architectures, and (ii) to assess the suitability of the Safety Shell architecture to handle edge cases with this new method. Using the developed experimental setup we observe a significant safety and availability increase of the Safety Shell compared to the included individual AD channels in the tested scenarios. Finally, our study provides insight into the requirements for the evaluated AD channels.

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Y2 - 2 June 2024 through 5 June 2024

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Evaluation of the Safety Shell Architecture for Automated Driving in a Realistic Simulator

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