针对季节性流感部署护理机器人:基于障碍物加权控制的快速社会距离检测和寻隙算法

IF 2.3 4区 计算机科学 Q3 ROBOTICS
Guoqiang Fu, Yina Wang, Junyou Yang, Shuoyu Wang
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引用次数: 0

摘要

季节性流感是当前全球面临的一个重大公共卫生问题。尽管世界卫生组织(WHO)建议保持社交距离是阻止流感疾病传播的最佳方法之一,但保持社交距离缺乏可控性的问题却普遍存在。在这种担忧的驱使下,本文开发了一种快速社交距离监测解决方案,它将基于 PyTorch 的轻量级单目视觉检测模型与反透视映射(IPM)技术相结合,使护理机器人能够从单目图像中恢复三维室内信息并检测行人之间的距离,然后通过统计分析场景内人与人之间的距离,将公共场所划分为不同的风险等级,从而进行实时动态的感染风险评估,即快速 DeepSOCIAL(FDS)。首先,FDS 模型使用基于 PyTorch 的轻量级单级检测器直接生成物体类别和位置的概率,这使护理机器人在降低内存消耗的同时获得显著的实时性能提升。此外,FDS 模型采用了改进的空间金字塔池化策略,引入了更多分支和不同内核大小的并行池化,这将有利于捕捉多种尺度的上下文信息,从而提高检测精度。最后,护理机器人引入了基于障碍物加权控制的寻隙策略(GSOWC),以适应危险的室内消毒任务,同时在未知和杂乱的环境中快速避开障碍物。通过广泛的评估,验证了 FDS 在护理机器人平台上的性能,与七种最先进的方法相比,FDS 的性能更加优越,并揭示了 FDS 模型能够更好地检测社会距离。总之,采用快速 DeepSOCIAL 模型(FDS)的护理机器人将是一种创新方法,由于其快速、非接触和成本低廉的特点,它将为应对这场季节性流感灾难做出有效贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Deployment of nursing robot for seasonal flu: fast social distancing detection and gap-seeking algorithm based on obstacles-weighted control

Deployment of nursing robot for seasonal flu: fast social distancing detection and gap-seeking algorithm based on obstacles-weighted control

Seasonal flu is currently a major public health issue the world is facing. Although the World Health Organization (WHO) suggests social distancing is one of the best ways to stop the spread of the flu disease, the lack of controllability in keeping a social distance is widespread. Spurred by this concern, this paper developed a fast social distancing monitoring solution, which combines a lightweight PyTorch-based monocular vision detection model with inverse perspective mapping (IPM) technology, enabling the nursing robot to recover 3D indoor information from a monocular image and detect the distance between pedestrians, then conducts a live and dynamic infection risk assessment by statistically analyzing the distance between the people within a scene and ranking public places into different risk levels, called Fast DeepSOCIAL (FDS). First, the FDS model generates the probability of an object’s category and location directly using a lightweight PyTorch-based one-stage detector, which enables a nursing robot to obtain significant real-time performance gains while reducing memory consumption. Additionally, the FDS model utilizes an improved spatial pyramid pooling strategy, which introduces more branches and parallel pooling with different kernel sizes, which will be beneficial in capturing the contextual information at multiple scales and thus improving detection accuracy. Finally, the nursing robot introduces a gap-seeking strategy based on obstacles-weighted control (GSOWC) to adapt to dangerous indoor disinfection tasks while quickly avoiding obstacles in an unknown and cluttered environment. The performance of the FDS on the nursing robot platform is verified through extensive evaluation, demonstrating its superior performance compared to seven state-of-the-art methods and revealing that the FDS model can better detect social distance. Overall, a nursing robot employing the Fast DeepSOCIAL model (FDS) will be an innovative approach that effectively contributes to dealing with this seasonal flu disaster due to its fast, contactless, and inexpensive features.

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来源期刊
CiteScore
5.70
自引率
4.00%
发文量
46
期刊介绍: The journal directs special attention to the emerging significance of integrating robotics with information technology and cognitive science (such as ubiquitous and adaptive computing,information integration in a distributed environment, and cognitive modelling for human-robot interaction), which spurs innovation toward a new multi-dimensional robotic service to humans. The journal intends to capture and archive this emerging yet significant advancement in the field of intelligent service robotics. The journal will publish original papers of innovative ideas and concepts, new discoveries and improvements, as well as novel applications and business models which are related to the field of intelligent service robotics described above and are proven to be of high quality. The areas that the Journal will cover include, but are not limited to: Intelligent robots serving humans in daily life or in a hazardous environment, such as home or personal service robots, entertainment robots, education robots, medical robots, healthcare and rehabilitation robots, and rescue robots (Service Robotics); Intelligent robotic functions in the form of embedded systems for applications to, for example, intelligent space, intelligent vehicles and transportation systems, intelligent manufacturing systems, and intelligent medical facilities (Embedded Robotics); The integration of robotics with network technologies, generating such services and solutions as distributed robots, distance robotic education-aides, and virtual laboratories or museums (Networked Robotics).
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