{"title":"增强目标跟踪:基于网格的新型甲虫天线搜索算法和感知混淆的检测。","authors":"Yixuan Lu, Chencong Ma, Dechao Chen","doi":"10.3390/biomimetics9090567","DOIUrl":null,"url":null,"abstract":"<p><p>Unmanned aerial vehicle target tracking is a complex task that encounters challenges in scenarios involving limited computing resources, real-time requirements, and target confusion. This research builds on previous work and addresses challenges by proposing a grid-based beetle antennae search algorithm and designing a lightweight multi-target detection and positioning method, which integrates interference-sensing mechanisms and depth information. First, the grid-based beetle antennae search algorithm's rapid convergence advantage is combined with a secondary search and rollback mechanism, enhancing its search efficiency and ability to escape local extreme areas. Then, the You Only Look Once (version 8) model is employed for target detection, while corner detection, feature point extraction, and dictionary matching introduce a confusion-aware mechanism. This mechanism effectively distinguishes potentially confusing targets within the field of view, enhancing the system's robustness. Finally, the depth-based localization of the target is performed. To verify the performance of the proposed approach, a series of experiments were conducted on the grid-based beetle antennae search algorithm. Comparisons with four mainstream intelligent search algorithms are provided, with the results showing that the grid-based beetle antennae search algorithm excels in the number of iterations to convergence, path length, and convergence speed. When the algorithm faces non-local extreme-value-area environments, the speed is increased by more than 89%. In comparison with previous work, the algorithm speed is increased by more than 233%. Performance tests on the confusion-aware mechanism by using a self-made interference dataset demonstrate the model's high discriminative ability. The results also indicate that the model meets the real-time requirements.</p>","PeriodicalId":8907,"journal":{"name":"Biomimetics","volume":"9 9","pages":""},"PeriodicalIF":3.4000,"publicationDate":"2024-09-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11430007/pdf/","citationCount":"0","resultStr":"{\"title\":\"Enhancing Target Tracking: A Novel Grid-Based Beetle Antennae Search Algorithm and Confusion-Aware Detection.\",\"authors\":\"Yixuan Lu, Chencong Ma, Dechao Chen\",\"doi\":\"10.3390/biomimetics9090567\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Unmanned aerial vehicle target tracking is a complex task that encounters challenges in scenarios involving limited computing resources, real-time requirements, and target confusion. This research builds on previous work and addresses challenges by proposing a grid-based beetle antennae search algorithm and designing a lightweight multi-target detection and positioning method, which integrates interference-sensing mechanisms and depth information. First, the grid-based beetle antennae search algorithm's rapid convergence advantage is combined with a secondary search and rollback mechanism, enhancing its search efficiency and ability to escape local extreme areas. Then, the You Only Look Once (version 8) model is employed for target detection, while corner detection, feature point extraction, and dictionary matching introduce a confusion-aware mechanism. This mechanism effectively distinguishes potentially confusing targets within the field of view, enhancing the system's robustness. Finally, the depth-based localization of the target is performed. To verify the performance of the proposed approach, a series of experiments were conducted on the grid-based beetle antennae search algorithm. Comparisons with four mainstream intelligent search algorithms are provided, with the results showing that the grid-based beetle antennae search algorithm excels in the number of iterations to convergence, path length, and convergence speed. When the algorithm faces non-local extreme-value-area environments, the speed is increased by more than 89%. In comparison with previous work, the algorithm speed is increased by more than 233%. Performance tests on the confusion-aware mechanism by using a self-made interference dataset demonstrate the model's high discriminative ability. 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引用次数: 0
摘要
无人飞行器目标跟踪是一项复杂的任务,在涉及有限计算资源、实时性要求和目标混淆的场景中会遇到各种挑战。本研究在前人工作的基础上,提出了一种基于网格的甲虫天线搜索算法,并设计了一种集成干扰感应机制和深度信息的轻量级多目标检测和定位方法,从而解决了这一难题。首先,基于网格的甲虫触角搜索算法的快速收敛优势与二次搜索和回滚机制相结合,提高了其搜索效率和摆脱局部极端区域的能力。然后,采用 You Only Look Once(版本 8)模型进行目标检测,同时在拐角检测、特征点提取和字典匹配中引入了混淆感知机制。这种机制能有效区分视野内可能混淆的目标,增强了系统的鲁棒性。最后,对目标进行基于深度的定位。为了验证所提方法的性能,我们在基于网格的甲虫触角搜索算法上进行了一系列实验。实验结果表明,基于网格的甲虫触角搜索算法在收敛迭代次数、路径长度和收敛速度方面表现优异。当该算法面对非局部极值区域环境时,速度提高了 89% 以上。与之前的工作相比,算法速度提高了 233% 以上。使用自制干扰数据集对混淆感知机制进行的性能测试表明,该模型具有很高的判别能力。结果还表明,该模型符合实时性要求。
Enhancing Target Tracking: A Novel Grid-Based Beetle Antennae Search Algorithm and Confusion-Aware Detection.
Unmanned aerial vehicle target tracking is a complex task that encounters challenges in scenarios involving limited computing resources, real-time requirements, and target confusion. This research builds on previous work and addresses challenges by proposing a grid-based beetle antennae search algorithm and designing a lightweight multi-target detection and positioning method, which integrates interference-sensing mechanisms and depth information. First, the grid-based beetle antennae search algorithm's rapid convergence advantage is combined with a secondary search and rollback mechanism, enhancing its search efficiency and ability to escape local extreme areas. Then, the You Only Look Once (version 8) model is employed for target detection, while corner detection, feature point extraction, and dictionary matching introduce a confusion-aware mechanism. This mechanism effectively distinguishes potentially confusing targets within the field of view, enhancing the system's robustness. Finally, the depth-based localization of the target is performed. To verify the performance of the proposed approach, a series of experiments were conducted on the grid-based beetle antennae search algorithm. Comparisons with four mainstream intelligent search algorithms are provided, with the results showing that the grid-based beetle antennae search algorithm excels in the number of iterations to convergence, path length, and convergence speed. When the algorithm faces non-local extreme-value-area environments, the speed is increased by more than 89%. In comparison with previous work, the algorithm speed is increased by more than 233%. Performance tests on the confusion-aware mechanism by using a self-made interference dataset demonstrate the model's high discriminative ability. The results also indicate that the model meets the real-time requirements.