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基于数字范式的蜜蜂在动态障碍物场景中视觉-运动协调的自动监测平台-FlyDetector

FlyDetector-Automated Monitoring Platform for the Visual-Motor Coordination of Honeybees in a Dynamic Obstacle Scene Using Digital Paradigm.

机构信息

School of Mechanical Engineering, Nantong University, Nantong 226019, China.

Shanghai Aerospace System Engineering Institute, Shanghai 201108, China.

出版信息

Sensors (Basel). 2023 Aug 10;23(16):7073. doi: 10.3390/s23167073.

DOI:10.3390/s23167073
PMID:37631609
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10458728/
Abstract

Vision plays a crucial role in the ability of compound-eyed insects to perceive the characteristics of their surroundings. Compound-eyed insects (such as the honeybee) can change the optical flow input of the visual system by autonomously controlling their behavior, and this is referred to as visual-motor coordination (VMC). To analyze an insect's VMC mechanism in dynamic scenes, we developed a platform for studying insects that actively shape the optic flow of visual stimuli by adapting their flight behavior. Image-processing technology was applied to detect the posture and direction of insects' movement, and automatic control technology provided dynamic scene stimulation and automatic acquisition of perceptual insect behavior. In addition, a virtual mapping technique was used to reconstruct the visual cues of insects for VMC analysis in a dynamic obstacle scene. A simulation experiment at different target speeds of 1-12 m/s was performed to verify the applicability and accuracy of the platform. Our findings showed that the maximum detection speed was 8 m/s, and triggers were 95% accurate. The outdoor experiments showed that flight speed in the longitudinal axis of honeybees was more stable when facing dynamic barriers than static barriers after analyzing the change in geometric optic flow. Finally, several experiments showed that the platform can automatically and efficiently monitor honeybees' perception behavior, and can be applied to study most insects and their VMC.

摘要

视觉在复眼昆虫感知周围环境特征的能力中起着至关重要的作用。复眼昆虫(如蜜蜂)可以通过自主控制行为来改变视觉系统的光流输入,这被称为视觉-运动协调(VMC)。为了分析昆虫在动态场景中的 VMC 机制,我们开发了一个平台,通过适应其飞行行为来主动塑造视觉刺激的光流,从而研究昆虫。图像处理技术用于检测昆虫运动的姿势和方向,自动控制技术提供动态场景刺激和昆虫感知行为的自动获取。此外,使用虚拟映射技术来重建昆虫的视觉线索,以便在动态障碍物场景中进行 VMC 分析。在 1-12 m/s 的不同目标速度下进行了模拟实验,以验证平台的适用性和准确性。我们的研究结果表明,最大检测速度为 8 m/s,触发准确率为 95%。通过分析几何光流的变化,发现蜜蜂在面对动态障碍物时的纵向飞行速度比面对静态障碍物时更稳定。最后,几项实验表明,该平台可以自动高效地监测蜜蜂的感知行为,可用于研究大多数昆虫及其 VMC。

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本文引用的文献

1
Insect-inspired AI for autonomous robots.受昆虫启发的人工智能用于自主机器人。
Sci Robot. 2022 Jun 15;7(67):eabl6334. doi: 10.1126/scirobotics.abl6334.
2
Small brains for big science.大脑虽小,科研不小。
Curr Opin Neurobiol. 2021 Dec;71:77-83. doi: 10.1016/j.conb.2021.09.007. Epub 2021 Oct 14.
3
Visual and movement memories steer foraging bumblebees along habitual routes.视觉和运动记忆引导觅食的大黄蜂沿着习惯的路线行进。
J Exp Biol. 2021 Jun 1;224(11). doi: 10.1242/jeb.237867. Epub 2021 Jun 11.
4
Animal Cognition: The Self-Image of a Bumblebee.动物认知:大黄蜂的自我形象。
Curr Biol. 2021 Feb 22;31(4):R207-R209. doi: 10.1016/j.cub.2020.12.027.
5
The Antarium: A Reconstructed Visual Reality Device for Ant Navigation Research.蚁室:一种用于蚂蚁导航研究的重构虚拟现实设备。
Front Behav Neurosci. 2020 Nov 10;14:599374. doi: 10.3389/fnbeh.2020.599374. eCollection 2020.
6
Bumblebees perceive the spatial layout of their environment in relation to their body size and form to minimize inflight collisions.大黄蜂通过感知自身大小和形状与周围环境的空间布局关系,来最小化飞行中的碰撞。
Proc Natl Acad Sci U S A. 2020 Dec 8;117(49):31494-31499. doi: 10.1073/pnas.2016872117. Epub 2020 Nov 23.
7
The grand challenges of .···的重大挑战。
Sci Robot. 2018 Jan 31;3(14). doi: 10.1126/scirobotics.aar7650.
8
Animals in Virtual Environments.虚拟环境中的动物。
IEEE Trans Vis Comput Graph. 2020 May;26(5):2073-2083. doi: 10.1109/TVCG.2020.2973063. Epub 2020 Feb 13.
9
Opponent processes in visual memories: A model of attraction and repulsion in navigating insects' mushroom bodies.视觉记忆中的对手进程:导航昆虫的蘑菇体中吸引和排斥的模型。
PLoS Comput Biol. 2020 Feb 5;16(2):e1007631. doi: 10.1371/journal.pcbi.1007631. eCollection 2020 Feb.
10
The role of optic flow pooling in insect flight control in cluttered environments.在杂乱环境中昆虫飞行控制中光流聚合的作用。
Sci Rep. 2019 May 22;9(1):7707. doi: 10.1038/s41598-019-44187-2.