Robust Maintenance Scheduling of Aircraft Fleet: A Hybrid Simulation-Optimization Approach

Shahmoradi-Moghadam, Hani; Safaei, Nima; Sadjadi, Seyed Jafar

doi:10.1109/access.2021.3053714

Cited by 11 publications

(3 citation statements)

References 39 publications

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“…Robust optimization is an appealing approach to address the problem with uncertain parameters that are only known to belong to some uncertain set (Zhao et al [21]; Liang et al [22]; Shahmoradi-Moghadam et al [23]). Its objective is to optimize the worst-case objective function (Ben-Tal and Nemirovski, [24]; [25]; Bertsimas and Sim [26]; [27]; Delage and Ye [28]).…”

Section: B Robust Optimization Approachmentioning

confidence: 99%

Robust Dry Bulk Fleet Route Optimization Under Navigation Risk Consideration

Gao¹,

Wang

2021

IEEE Access

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Section: B Robust Optimization Approachmentioning

confidence: 99%

Robust Dry Bulk Fleet Route Optimization Under Navigation Risk Consideration

Gao¹,

Wang

2021

IEEE Access

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“…While the adaptive algorithm falls slightly behind the static algorithm in terms of Ground Time and Time Slack, both critical Key Performance Indicators (KPIs) in aircraft maintenance, it excels significantly in the Change Score metric. This metric gains paramount importance in current maintenance scenarios, as it measures the impact of plan modifications on various aspects such as maintenance personnel, equipment/shop, space, and parallel capacity 11 – 13 . These findings underscore the adaptive algorithm’s exceptional adaptability to handle unexpected changes, making it highly valuable in dynamic maintenance environments where flexibility is of utmost importance.…”

Section: Introductionmentioning

confidence: 99%

Adaptive reinforcement learning for task scheduling in aircraft maintenance

Silva,

Andrade,

Ribeiro

et al. 2023

Sci Rep

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This paper proposes using reinforcement learning (RL) to schedule maintenance tasks, which can significantly reduce direct operating costs for airlines. The approach consists of a static algorithm for long-term scheduling and an adaptive algorithm for rescheduling based on new maintenance information. To assess the performance of both approaches, three key performance indicators (KPIs) are defined: Ground Time, representing the hours an aircraft spends on the ground; Time Slack, measuring the proximity of tasks to their due dates; and Change Score, quantifying the similarity level between initial and adapted maintenance plans when new information surfaces. The results demonstrate the efficacy of RL in producing efficient maintenance plans, with the algorithms complementing each other to form a solid foundation for routine tasks and real-time responsiveness to new information. While the static algorithm performs slightly better in terms of Ground Time and Time Slack, the adaptive algorithm excels overwhelmingly in terms of Change Score, offering greater flexibility in handling new maintenance information. The proposed RL-based approach can improve the efficiency of aircraft maintenance and has the potential for further research in this area.

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“…), for the operation and maintenance (O&M) of mechanical components. While a significant body of work has focused on simulation/optimisation frameworks to solve the maintenance task scheduling problem of a fleet of aircraft [7][8][9][10], in this work we will mainly focus on previous RL applications. Several recent studies [11,12] proposed novel RL frameworks to optimise the O&M of a single mechanical component (e.g., pump/turbine/turbofan engine) and demonstrated that it can find optimal policies when compared to traditional maintenance strategies.…”

Section: Introductionmentioning

confidence: 99%

Aircraft fleet availability optimisation: a reinforcement learning approach

Vos,

Peng,

Lee

et al. 2023

Aeronaut. j.

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A fleet of aircraft can be seen as a set of degrading systems that undergo variable loads as they fly missions and require maintenance throughout their lifetime. Optimal fleet management aims to maximise fleet availability while minimising overall maintenance costs. To achieve this goal, individual aircraft, with variable age and degradation paths, need to operate cooperatively to maintain high fleet availability while avoiding mechanical failure by scheduling preventive maintenance actions. In recent years, reinforcement learning (RL) has emerged as an effective method to optimise complex sequential decision-making problems. In this paper, an RL framework to optimise the operation and maintenance of a fleet of aircraft is developed. Three cases studies, with varying number of aircraft in the fleet, are used to demonstrate the ability of the RL policies to outperform traditional operation/maintenance strategies. As more aircraft are added to the fleet, the combinatorial explosion of the number of possible actions is identified as a main computational limitation. We conclude that the RL policy has potential to support fleet management operators and call for greater research on the application of multi-agent RL for fleet availability optimisation.

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Robust Maintenance Scheduling of Aircraft Fleet: A Hybrid Simulation-Optimization Approach

Cited by 11 publications

References 39 publications

Robust Dry Bulk Fleet Route Optimization Under Navigation Risk Consideration

Robust Dry Bulk Fleet Route Optimization Under Navigation Risk Consideration

Adaptive reinforcement learning for task scheduling in aircraft maintenance

Aircraft fleet availability optimisation: a reinforcement learning approach

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