Scheduling Analysis under Fault Bursts

Many, Florian; Doose, David

doi:10.1109/rtas.2011.19

Cited by 25 publications

(37 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For example, electromagnetic interference (EMI) caused by lighting strikes may cause incorrect computation and bit flips in architectural registers. Other examples are automotive and avionics systems exposed to higher EMI levels when passing airport radar or communication facilities (Many and Doose 2011).…”

Section: Error Fault and Application Modelmentioning

confidence: 99%

Real-time scheduling algorithm for safety-critical systems on faulty multicore environments

Pathan

2016

Real-Time Syst

View full text Add to dashboard Cite

An algorithm (called FTM) for scheduling of real-time sporadic tasks on a multicore platform is proposed. Each task has a deadline by which it must complete its non-erroneous execution. The FTM algorithm executes backups in order to recover from errors caused by non-permanent and permanent hardware faults. The worst-case schedulability analysis of FTM algorithm is presented considering an applicationlevel error model, which is independent of the stochastic behavior of the underlying hardware-level fault model. Then, the stochastic behavior of hardware-level fault model is plugged in to the analysis to derive the probability of meeting all the deadlines. Such probabilistic guarantee is the level of assurance (i.e., reliability) regarding the correct functional and timing behaviors of the system. One of the salient features of FTM algorithm is that it executes some backups in active redundancy to exploit the parallel multicore architecture while other backups passively to avoid unnecessary execution of too many active backups. This paper also proposes a scheme to determine for each task the number of backups that should run in active redundancy in order to increase the probability of meeting all the deadlines. The effectiveness of the proposed approach is demonstrated using an example application.

show abstract

Section: Error Fault and Application Modelmentioning

confidence: 99%

Real-time scheduling algorithm for safety-critical systems on faulty multicore environments

Pathan

2016

Real-Time Syst

View full text Add to dashboard Cite

show abstract

“…More recently, there has been a growing interest in dealing with scenarios where faults follow a random pattern over a bounded time window and impose a potentially continuous disturbance to the computational activities [8]- [11]. In that new framework called the fault burst model, the fault distribution within the interval under consideration is not known.…”

Section: Introductionmentioning

confidence: 99%

“…For example, short voltage fluctuations due to power supply jitters or electromagnetic interference (EMI) caused by short-lived atmospheric effects (e.g., lightning strikes) may cause incorrect computations in the core logic and bit flips in architectural registers. Other examples may be found in automotive and avionics areas, where the real-time system controlling a vehicle or unmanned system may be exposed to higher EMI levels when passing near airport radar and communication facilities [8], [10].…”

Section: Introductionmentioning

confidence: 99%

Real-time scheduling under fault bursts with multiple recovery strategy

Haque

Aydın

Zhu

2014

2014 IEEE 19th Real-Time and Embedded Technology and Applications Symposium (RTAS)

View full text Add to dashboard Cite

Abstract-In this paper, we consider the feasibility problem of a set of real-time jobs which may be subject to a fault burst during execution. A fault burst represents a time interval during which multiple jobs may incur faults; hence multiple recoveries may be needed. We show that determining the feasibility of a real-time system, which may be subject to a fault burst that may last at most ∆ time units, is an NP-Hard problem even when the exact position of the fault burst is known a priori. However, in a practical system, the fault burst may occur at any arbitrary and unpredictable time. We develop feasibility analysis by assuming multiple recovery strategy where, in addition to the job at the end of which the fault is detected, all preempted tasks are also reexecuted. We formally characterize the overhead that a scheduler incurs due to a fault burst and present a generic recovery strategy, called ∆-idling, that is shown to minimize the worst-case overhead for any priority-driven scheduling algorithm. Next, we analyze periodic task systems. We show that the preemptive EDF policy, when coupled with ∆-idling, provides the highest possible utilization bound 1 2(1 − ∆ P min ), where Pmin is the smallest task period. We also present an empirical evaluation of the EDF policy with ∆-idling over synthetically generated task sets, and show that it offers a clear improvement over the naive EDF policy that triggers the recovery tasks as soon as an error is detected.

show abstract

“…As mentioned before, soft errors occur more frequently than hard errors in modern computing systems. While soft errors can occur in both single-core and multi-core platforms, a majority of current researches are focused on single-core platforms [52,39,8,89,131] and only a few on multi-core platforms.…”

Section: Energy-oblivious Fault-tolerant Techniquesmentioning

confidence: 99%

“…The advantage of this approach is that the reliability can be quantified and the impacts of DVFS to reliability can also be taken into consideration. However, to precisely identify the parameters for the reliability model can be challenging, especially when faults usually occur in a burst manner [89].…”

Section: Related Workmentioning

confidence: 99%

Energy-aware Fault-tolerant Scheduling for Hard Real-time Systems

Han¹

View full text Add to dashboard Cite

Scheduling Analysis under Fault Bursts

Cited by 25 publications

References 16 publications

Real-time scheduling algorithm for safety-critical systems on faulty multicore environments

Real-time scheduling algorithm for safety-critical systems on faulty multicore environments

Real-time scheduling under fault bursts with multiple recovery strategy

Energy-aware Fault-tolerant Scheduling for Hard Real-time Systems

Contact Info

Product

Resources

About