System of Systems Simulation driven Urban Air Mobility Vehicle Design

Prakasha, Prajwal S.; Ratei, Patrick; Naeem, Nabih; Nagel, Björn; Bertram, Oliver

doi:10.2514/6.2021-3200

Cited by 14 publications

(6 citation statements)

References 23 publications

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“…torque and speeds for the electric motors. Furthermore, the methodology has already been integrated into a higher-level simulation model in order to show the influence of the onboard systems on the design and operation of an UAM system [20]. For further research, a full-electric architecture based on batteries as well as a hybrid powertrain architecture with fuel cells and batteries will be investigated.…”

Section: Viconclusion and Outlookmentioning

confidence: 99%

UAM Vehicle Design with Emphasis on Electric Powertrain Architectures

Bertram

2022

AIAA SCITECH 2022 Forum

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The research on the system architecture of Urban Air Mobility (UAM) vehicles is a vital part within the DLR internal project HorizonUAM. One of the project goals in HorizonUAM is the development of a system concept for an air taxi. This includes research on safe and certifiable onboard systems. The aim of this article is to present results and findings with emphasis on electric powertrain architectures in the multirotor air taxi design. A preliminary design methodology was developed therefor, which enables the examination of full-electric, turbo-electric and hybrid-electric powertrains. This methodology was used in a design study to investigate the influence of different powertrain architectures on the multirotor design. Different evaluation parameters, parameter sweeps and technology exploration of batteries and fuel cell systems were applied to analyze and evaluate their impact on the UAM vehicle design. The main design drivers are the mass of the energy sources and the overall powertrain efficiency, which have a direct impact on the evaluation parameters like power and energy efficiency, maximum take-off mass, and payload fraction. The study showed that different powertrain architectures could lead to opposite vehicle design criteria. Therefore, a clear solution for an advantageous powertrain architecture could not be found. Hybrid-electric solutions, e.g. fuel cell and battery systems or parallel hybrid-electric systems, offer the possibility of increasing efficiency in different flight phases through suitable power management while increasing system complexity. The disadvantage of a high battery mass of a full-electric solution could thus be at least partially reduced.

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Section: Viconclusion and Outlookmentioning

confidence: 99%

UAM Vehicle Design with Emphasis on Electric Powertrain Architectures

Bertram

2022

AIAA SCITECH 2022 Forum

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“…Distributed, autonomous, and semi-autonomous decision-making has shifted the paradigm of system design, leading to the popularity of SoS in various engineering design applications such as the Internet of Things, 6 autonomous vehicles, 7 urban air mobility vehicle design, 8 smart grids, [9][10][11] fractionated satellite systems where detection, processing, and communication tasks are dynamically assigned to members of the satellite cluster 12,13 ; sustainable manufacturing systems, 14,15 communication networks in which the frequency spectrum is dynamically allocated for efficient use, 16 and groups of unmanned, autonomous vehicles (such as aerial drones) that dynamically assign tasks among themselves and can utilize information gathered by other group members. 17 In most of these applications, resources such as energy, communication bandwidth, computation, and memory are constrained, necessitating an efficient and adaptable resource allocation strategy to accommodate the intricate and evolving dynamics of SoS.…”

Section: Resource Allocation In Systems Of Systemsmentioning

confidence: 99%

“…For outputs (dependent variables), we track the scores of agents at each time step, calculated by the distance between each landmark and the closest corresponding agents; the total costs of resources at each time step; and the overall system performance, which is the agents' scores minus the total resource costs. We modify the experiment settings according to resource budgets (2,4,6,8,10) and the level of coordination (low-level, mid-level, and high-level).…”

Section: Experiments Implementationmentioning

confidence: 99%

The SoS conductor: Orchestrating resources with iterative agent‐based reinforcement learning

Chen,

Heydari

2024

Systems Engineering

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We introduce a novel resource management approach for Systems of Systems (SoS), utilizing hierarchical deep reinforcement learning, iterating with agent‐based simulation. A key innovation of this method is its ability to balance top‐down SoS management with the autonomy of individual systems. This is achieved by dynamically allocating resources to each system, thereby modifying the range of options they can autonomously choose from. This dynamic option adjustment is a powerful approach to managing the trade‐off between centralized efficiency and decentralized autonomous actions of the systems, enabling the SoS to maintain the systems' autonomy while ensuring efficient SoS governance. The method, validated through a case study, not only demonstrates the potential and efficacy of the learning framework but also reveals how, using this method, minor performance sacrifices can lead to substantial improvements in resource efficiency.

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“…An SoS simulation framework presented in Figure 1 is utilized for this study, developed through past research of the authors [4] and extended in the accompanying work as part of the underlying proceedings [5]. The SoS simulation framework connects aircraft design methodologies with an agentbased simulation, each of these two main components are designed to be extendible where detailed analysis can be integrated within, such as but not limited to onboard system and powertrain sizing [6] into aircraft design, or detailed vertiport and trajectory simulations into the collaborative SoS simulation as part of the ongoing work in HorizonUAM. Furthermore, in previous work life cycle assessment methodologies were integrated into the SoS simulation framework to understand the impact of subsystem, system and operational parameters at the environmental impact level, however this aspect is not included in this study.…”

Section: System Of Systems Simulation Frameworkmentioning

confidence: 99%

“…Furthermore, in previous work life cycle assessment methodologies were integrated into the SoS simulation framework to understand the impact of subsystem, system and operational parameters at the environmental impact level, however this aspect is not included in this study. For detailed explanation of the sizing methods used in this study the reader is directed to [6,7] and for the description of the modelling and simulation of the SoS simulation, including assumptions, processes and interactions of stakeholders, the reader is directed to the accompanying work [5].…”

Section: System Of Systems Simulation Frameworkmentioning

confidence: 99%

Development of an urban air mobility vehicle family concept by system of systems aircraft design and assessment

Ratei

Naeem

Prakasha

2023

J. Phys.: Conf. Ser.

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The concept of urban air mobility promises a modern air taxi transport solution providing on-demand air mobility and hence time savings compared to congested terrestrial transportation in major cities and metropolitan areas. To make it a reality, vehicles, infrastructure, services, and operations must be developed simultaneously and cross-linked. These interconnections and interactions of the multitude of systems involved necessitate a system of systems approach, which is accounted for and implemented through agent-based simulations. Accordingly, the system of systems simulation framework is tuned to vehicle architecture as well as fleet design and assessment, thus allows to expand the aircraft design process by fleet operations and transport network perspectives. In this paper, the top level aircraft requirements of electric vertical take-off and landing vehicles are investigated by a fleet-centric approach. Herein, two disparate configurations, i.e. multirotor and tiltrotor, are modelled to depict representative wingless and winged configurations. The optimal design points are found and traded off by formulating different measures of effectiveness accounting for conversion of passenger requests, fleet energy consumption, and vehicle load factor. In summary, this study demonstrates the need for system of systems simulations to derive market-and operations-tailored vehicles and fleets. Furthermore, work on heterogeneous fleet compositions is required.

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System of Systems Simulation driven Urban Air Mobility Vehicle Design

Cited by 14 publications

References 23 publications

UAM Vehicle Design with Emphasis on Electric Powertrain Architectures

UAM Vehicle Design with Emphasis on Electric Powertrain Architectures

The SoS conductor: Orchestrating resources with iterative agent‐based reinforcement learning

Development of an urban air mobility vehicle family concept by system of systems aircraft design and assessment

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