A bioinspired Separated Flow wing provides turbulence resilience and aerodynamic efficiency for miniature drones

Luca, Matteo Di; Mintchev, Stefano; Su, Yunxing; Shaw, Eric; Breuer, Kenneth S.

doi:10.1126/scirobotics.aay8533

Cited by 29 publications

(25 citation statements)

References 49 publications

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“…Journal drone quality is positively correlated with the number of foils incorporated by a drone for both sets of drones designed by the AI-assisted and solo designers, respectively. The results, in line with literature on the design of drones [51], help to explain why and how AI assistance improves drone quality.…”

Section: Accepted Manuscript N O T C O P Y E D I T E Dsupporting

confidence: 81%

When Faced With Increasing Complexity: The Effectiveness of Artificial Intelligence Assistance for Drone Design

Song

Zurita

Nolte

et al. 2021

Journal of Mechanical Design

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As Artificial Intelligence (AI) assistance tools become more ubiquitous in engineering design, it becomes increasingly necessary to understand the influence of AI assistance on the design process and design effectiveness. Previous work has shown the advantages of incorporating AI design agents to assist human designers. However, the influence of AI assistance on the behavior of designers during the design process is still unknown. This study examines the differences in participants' design process and effectiveness with and without AI assistance during a complex drone design task using the HyForm design research platform. Data collected from this study is analyzed to assess the design process and effectiveness using quantitative methods, such as Hidden Markov Models and network analysis. The results indicate that AI assistance is most beneficial when addressing moderately complex objectives but exhibits a reduced advantage in addressing highly complex objectives. During the design process, the individual designers working with AI assistance employ a relatively explorative search strategy, while the individual designers working without AI assistance devote more effort to parameter design.

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Section: Accepted Manuscript N O T C O P Y E D I T E Dsupporting

confidence: 81%

When Faced With Increasing Complexity: The Effectiveness of Artificial Intelligence Assistance for Drone Design

Song

Zurita

Nolte

et al. 2021

Journal of Mechanical Design

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“…Another example of robotic systems that could benefit from hair-like sensors are small-scale drones. Many advances have been made in the technology for small-scale drones that are used for a range of applications, from photography to environmental monitoring and mapping [ 125 ]. One limitation of small-scale drones is poor flight control in turbulent conditions [ 125 ].…”

Section: Engineering Applications Of Biologically Inspired Hair Sensorsmentioning

confidence: 99%

“…Many advances have been made in the technology for small-scale drones that are used for a range of applications, from photography to environmental monitoring and mapping [ 125 ]. One limitation of small-scale drones is poor flight control in turbulent conditions [ 125 ]. Wind gusts and turbulence can lead to stall, which both drones and flying animals alike encounter.…”

Section: Engineering Applications Of Biologically Inspired Hair Sensorsmentioning

confidence: 99%

Mechanosensory Hairs and Hair-like Structures in the Animal Kingdom: Specializations and Shared Functions Serve to Inspire Technology Applications

Boublil

Diebold

Moss

2021

Sensors

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Biological mechanosensation has been a source of inspiration for advancements in artificial sensory systems. Animals rely on sensory feedback to guide and adapt their behaviors and are equipped with a wide variety of sensors that carry stimulus information from the environment. Hair and hair-like sensors have evolved to support survival behaviors in different ecological niches. Here, we review the diversity of biological hair and hair-like sensors across the animal kingdom and their roles in behaviors, such as locomotion, exploration, navigation, and feeding, which point to shared functional properties of hair and hair-like structures among invertebrates and vertebrates. By reviewing research on the role of biological hair and hair-like sensors in diverse species, we aim to highlight biological sensors that could inspire the engineering community and contribute to the advancement of mechanosensing in artificial systems, such as robotics.

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“…The separated boundary layer is highly unstable and could dramatically affect the aerodynamic efficiency by undergoing a laminar-to-turbulent transition (Di Luca et al. 2020). Aiming at aerodynamic optimization, this separation-induced transition has been extensively explored by the academic community (Burgmann, Dannemann & Schröder 2008; Hain et al.…”

Section: Introductionmentioning

confidence: 99%

Wake-induced transition in the low-Reynolds-number flow over a multi-element airfoil

Wang

2021

J. Fluid Mech.

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A bioinspired Separated Flow wing provides turbulence resilience and aerodynamic efficiency for miniature drones

Cited by 29 publications

References 49 publications

When Faced With Increasing Complexity: The Effectiveness of Artificial Intelligence Assistance for Drone Design

When Faced With Increasing Complexity: The Effectiveness of Artificial Intelligence Assistance for Drone Design

Mechanosensory Hairs and Hair-like Structures in the Animal Kingdom: Specializations and Shared Functions Serve to Inspire Technology Applications

Wake-induced transition in the low-Reynolds-number flow over a multi-element airfoil

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