Fixed Priority Scheduling Strategies for Ambient Energy-Harvesting Embedded Systems

Chetto, Maryline; Masson, Damien; Midonnet, Serge

doi:10.1109/greencom.2011.17

Cited by 9 publications

(13 citation statements)

References 9 publications

(8 reference statements)

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“…The total power P σ0 consumed by the system in the active state is the sum of processor power and total power consumption of the specific subsets of peripherals in use by the running task; thus, at any time, P CP U ≤ P σ0 ≤ P CP U + P dev . As in [7], [8], we do not assume DVFS capability in the system; i.e., task execution takes place at a constant frequency level.…”

Section: A Power Modelmentioning

confidence: 99%

“…In systems with renewable energy, the concept of feasibility is extended to consider also battery (or, energy) failures ( [7], [8]). Specifically, in addition to guaranteeing task completions no later than their respective deadlines, in order to ensure feasibility, the algorithm must also guarantee that the battery level never drops below a certain threshold E low : ∀t, E(t) > E low .…”

Section: Proposed Approachmentioning

confidence: 99%

“…Moreover, thanks to its design principles, it explicitly considers the time/energy overheads involved in the processor state transitions, through the explicit analysis of the break-even times. In contrast, the energy-greedy algorithms (e.g., P F P st [7]) involve online computation of the existing slack to re-charge the battery, which is, in general, of pseudopolynomial complexity. Similarly, the computation-greedy algorithms (e.g., the theoretically optimal P F P ASAP ) result in very frequent invocation and processor state transitions with prohibitive costs on real systems that have non-zero transition overheads.…”

Section: Proposed Approachmentioning

confidence: 99%

“…For fixed-priority real-time embedded systems which are more common in practice, the two well-known algorithms are P F P st (also called EDeg) [7] and P F P asap [8], that represent energy-greedy and computation-greedy algorithms, respectively. In particular, P F P asap is shown to be optimal in [8]: any task set that can be feasibly scheduled by any other fixed-priority energy-harvesting scheduling algorithm can be also scheduled by P F P asap .…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Periodic charging scheme for fixed-priority real-time systems with renewable energy

Bambagini

Aydın

2014

Proceedings of the 9th IEEE International Symposium on Industrial Embedded Systems (SIES 2014)

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Abstract-Energy harvesting systems are gaining increasing importance in the embedded systems domain, as they provide an effective solution to bridge the gap between the energy supply and demand. However, the variable nature of the energy supply rate due to the environmental conditions creates serious challenges for embedded real-time systems targeting predictability.This paper presents a proactive and highly predictable framework, called Periodic Charging Scheme (PCS), for fixed-priority real-time systems with renewable energy. The main idea of the algorithm is to plan in advance for periodic charging and discharging of the battery to avoid energy outage, while still meeting the timing constraints. The algorithm is specifically designed to exploit the low-power states of modern processors, to enable effective power state transitions when the battery is recharged on a periodic basis. We also offer online enhancements to opportunistically extend the duration of charging phases and improve the responsiveness of the potential non-real-time workloads without compromising feasibility. Extensive simulations show that the proposed approach outperforms the state-of-theart algorithms in terms of the number of task sets that meet the timing constraints under specified energy profiles, when a realistic power model with state transition overheads is assumed.

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Section: A Power Modelmentioning

confidence: 99%

Section: Proposed Approachmentioning

confidence: 99%

Section: Proposed Approachmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Periodic charging scheme for fixed-priority real-time systems with renewable energy

Bambagini

Aydın

2014

Proceedings of the 9th IEEE International Symposium on Industrial Embedded Systems (SIES 2014)

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“…Recent work shows that this hypothesis is not realistic [3]. Finally, the problem was addressed by Chetto et al in [4], [5]. A clairvoyant algorithm and several non clairvoyant heuristics was proposed.…”

Section: Introduction and Related Workmentioning

confidence: 99%

The Fixed Priority Scheduling Problem for Energy Harvesting Real-Time Systems

Chandarli

Abdeddaïm

Masson

2012

2012 IEEE International Conference on Embedded and Real-Time Computing Systems and Applications

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Abstract-Energy harvesting is the process of generating electrical energy from environmental sources such as solar panels. In recent years, this term has been frequently applied in the context of small autonomous devices such as wireless sensor nodes. The classical scheduling theory is insufficient for this kind of systems and new scheduling problems arise in this context. Until now, the research on this area focused in trying to improve the efficiency of existing algorithms. Our approach is to complete these efforts by a feasibility theory allowing us to understand why classical optimal algorithms are not efficient anymore with energy constraints.In this paper, we try to establish a schedulability test for a fixed priority real-time scheduling problem with energy constraints. We first introduce the problem and describe the model. Then, to illustrate the difficulty of the problem, we focus on a preemptive fixed priority scheduling policy where all the executions are postponed as long as possible. This policy lets the harvester the maximal amount of time to refill the battery. We call this policy P F PALAP for As Late As Possible. We try to define sufficient and/or necessary schedulability conditions and discuss its potential optimality under some additional assumptions. Then, through simple counter examples, we show that intuitive assumptions are wrong for this scheduling problem, making it very interesting to study.

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The Optimality of PFPasap Algorithm for Fixed-Priority Energy-Harvesting Real-Time Systems

Abdeddaïm

Chandarli

Masson

2013

2013 25th Euromicro Conference on Real-Time Systems

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The paper addresses the real-time fixed-priority scheduling problem for battery-powered embedded systems whose energy storage unit is replenished by an environmental energy source. In this context, a task may meet its deadline only if its cost of energy can be satisfied early enough. Hence, a scheduling policy for such a system should account for properties of the source of energy, capacity of the energy storage unit and tasks cost of energy. Classical fixed-priority schedulers are no more suitable for this model. Based on these motivations, we propose P F PASAP an optimal scheduling algorithm that handles both energy and timing constraints. Furthermore, we state the worst case scenario for non concrete tasksets 1 scheduled with this algorithm and build a necessary and sufficient feasibility condition for non concrete tasksets. Moreover, a minimal bound of the storage unit capacity that keeps a taskset schedulable with P F PASAP is also proposed. Finally, we validate the proposed theory with large scale simulations and compare our algorithm with other existing ones.

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Fixed Priority Scheduling Strategies for Ambient Energy-Harvesting Embedded Systems

Cited by 9 publications

References 9 publications

Periodic charging scheme for fixed-priority real-time systems with renewable energy

Periodic charging scheme for fixed-priority real-time systems with renewable energy

The Fixed Priority Scheduling Problem for Energy Harvesting Real-Time Systems

The Optimality of PFPasap Algorithm for Fixed-Priority Energy-Harvesting Real-Time Systems

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