Taxonomy to Unify Fault Tolerance Regimes for Automotive Systems: Defining Fail-Operational, Fail-Degraded, and Fail-Safe

Stolte, Torben; Ackermann, Stefan; Graubohm, Robert; Jatzkowski, Inga; Klamann, Björn; Winner, Hermann; Maurer, Markus

doi:10.1109/tiv.2021.3129933

Cited by 19 publications

(15 citation statements)

References 47 publications

(52 reference statements)

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“…We can prevent too frequent state switching by increasing the (fair, poor) thresholds. For instance, the platooning vehicles exhibit better string stability and LV tracking for the thresholds (2,6), (3,5), (3,6), (4,5), and (4,6); see the speed profiles in Figure 7. The corresponding distance profiles show that the inter-vehicle gaps are between 5-10 m for all except the last two vehicles.…”

Section: Impacts Of Fair Poor Thresholds On String Stability and Fuel...mentioning

confidence: 99%

“…To better understand how the RTM governs switching between the states in Figure 2, let us take a closer look at the distance profiles of vehicle 6 (d 6 ) with thresholds (2, 3) and (4,6) in Figure 7 The state machine in Figure 2 dictates that a vehicle should adopt the PLATOON & GA state when c2l is fair and c2f is good. To this end, vehicle 6 upgrades its performance by adopting the PLATOON & GA state, and d 6 becomes 6.25 m at around 73 s, continuing until 78 s. Then communication with the LV becomes poor again, and vehicle 6 increases its gap to degrade its performance in order to prioritize safety over fuel efficiency by adopting the CACC state.…”

Section: Impacts Of Fair Poor Thresholds On String Stability and Fuel...mentioning

confidence: 99%

“…Any safety-critical system should be fault-tolerant, e.g., include fail-operational and/or fail-safe states, to mitigate the effects of failures [2]. Fail-operational in this context implies that a platoon should provide certain critical functionalities and remain at least as safe as it was before the temporary communication outage occurred, i.e., a nominal performance in terms of safety should always be ensured [4]. In order to facilitate the failoperational state, the platooning vehicles should gracefully degrade their performance in terms of, e.g., fuel efficiency, during runtime in a way that is proportionally related to the level of transient communication errors [5].…”

Section: Introductionmentioning

confidence: 99%

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Characterization of Transient Communication Outages Into States to Enable Autonomous Fault Tolerance in Vehicle Platooning

Hasan

Girs

Uhlemann

2023

IEEE Open J. Intell. Transp. Syst.

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The benefits of platooning, e.g., fuel efficiency, road throughput enhancement, driver offload, etc., have sparked an interest in a more connected, intelligent, and sustainable transportation ecosystem. However, efficient platooning is realized through wireless communications, characterized by transient connectivity, which is caused by occasional packet losses. Being a safety-critical system of systems, a platoon must be fail-operational even during transient connectivity. Moreover, a platoon should be capable of transitioning into a fail-safe state upon encountering a hazard. To this end, we propose a strategy for classifying the transient communication outages incurred by platooning vehicles into states. Furthermore, a state machine using these states to enable safe automated platooning is proposed that also defines the transitions between the states based on the nature and levels of transient connectivity and hazards. To achieve this, a graceful degradation and upgradation method is proposed, such that the platoon can remain fail-operational by adjusting, e.g., the automated controller and/or the inter-vehicle gaps based on the current communication quality. An emergency braking strategy is also proposed to enable a fast transition into a fail-safe state, should the platoon encounter a hazard. Rigorous simulation studies show that the proposed strategies enable fault-tolerant automated platooning also during transient connectivity.

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Section: Impacts Of Fair Poor Thresholds On String Stability and Fuel...mentioning

confidence: 99%

Section: Impacts Of Fair Poor Thresholds On String Stability and Fuel...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Characterization of Transient Communication Outages Into States to Enable Autonomous Fault Tolerance in Vehicle Platooning

Hasan

Girs

Uhlemann

2023

IEEE Open J. Intell. Transp. Syst.

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“…The new requirement for Autonomous Driving / Advanced Driver-Assistance Systems (AD/ADAS)) is that the vehicle must be fault-tolerant, i.e. it must continue operation even in the presence of failure [20], [21]. Thus, the NGIVN shall also migrate from being fail-safe to being fail-operational.…”

Section: Volume XX 2022mentioning

confidence: 99%

Elastic Gateway Functional Safety Architecture and Deployment: A Case Study

et al. 2022

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The automotive industry has started its transformation towards Software-Defined Vehicles. This transformation is driven by the rise of the number of vehicle features, the high complexity of these features and their constraining availability requirements which affect all the players (Original Equipment Manufacturers, Tier1 and Tier2) of the sector. In the context of this transformation, our target, from functional safety point of view, is to, inter alia, provide an easy-to-use and safety-compliant execution and development flow and simplify the development and argumentation for safety by providing a) a pre-certified execution environment with safety design patterns and best-in-class safety measures and b) processes and tooling to minimize the system integrator's effort. Therefore, in this work we propose a top-down approach where we first define a New Generation In-Vehicle Network, NGIVN, capable of fulfilling the performance (e.g. high bandwidth, low end-2-end delay), safety-related availability (e.g. Autonomous Driving / Advanced Driver-Assistance Systems (AD/ADAS) up to SAE level 5) and safety requirements of modern vehicles. Also, we illustrate the advantages of this approach by deriving the functional and safety attributes of an Automotive Gateway SoC, named Elastic Gateway and destined to be part of the NGIVN. Through the deployment of the Elastic Gateway functional safety concept we demonstrate the flexibility provided by our approach with regards to the design of elements of the NGIVN.

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“…The V2V failure and the radar failure is the hazardous event in the platoon system. [27] distinguished between different fault-tolerant mechanism. It's a fail-degraded system if it can provide its specified functionality with below nominal performance.…”

Section: B Fault-tolerant Mechanismmentioning

confidence: 99%

An Extendable Maneuver Management Framework with Fault-Tolerant Mechanism for Vehicle Platoon Control System in Highway Scenario

Liu¹,

Luo²,

Li³

et al. 2022

Preprint

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Vehicle platoon often face the problem of lack of scalability of maneuvers in practical applications. Once a new scenario is added, the original program may no longer be available. To deal with this problem, this paper introduces a two-dimensional maneuver management framework with faulttolerant mechanism on the basis of the proposed hierarchical architecture for the platoon control system. Maneuvers and roles are two dimensions, based on which the management strategies are decoupled. This makes each vehicle in the platoon has the ability to execute management strategies of various maneuvers and the new maneuver could be extended without revising the existing part. The fault-tolerant mechanism is designed as a maneuver triggered by hardware failures to keep safe before taking over. Furthermore, three typical maneuvers are selected for case studies to illustrate how the management strategies in this framework work. Finally, a comprehensive simulation scenario integrating different maneuvers is designed and a real-world implementation using micro-vehicles is conducted. Result shows that the proposed two-dimensional framework could effectively deal with various maneuvers and satisfy the computational real-time requirements.

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Taxonomy to Unify Fault Tolerance Regimes for Automotive Systems: Defining Fail-Operational, Fail-Degraded, and Fail-Safe

Cited by 19 publications

References 47 publications

Characterization of Transient Communication Outages Into States to Enable Autonomous Fault Tolerance in Vehicle Platooning

Characterization of Transient Communication Outages Into States to Enable Autonomous Fault Tolerance in Vehicle Platooning

Elastic Gateway Functional Safety Architecture and Deployment: A Case Study

An Extendable Maneuver Management Framework with Fault-Tolerant Mechanism for Vehicle Platoon Control System in Highway Scenario

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