Towards Indoor Suctionable Object Classification and Recycling: Developing a Lightweight AI Model for Robot Vacuum Cleaners

IF 2.5 4区 综合性期刊 Q2 CHEMISTRY, MULTIDISCIPLINARY Applied Sciences-Basel Pub Date : 2023-09-06 DOI:10.3390/app131810031
Qian Huang
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Abstract

Robot vacuum cleaners have gained widespread popularity as household appliances. One significant challenge in enhancing their functionality is to identify and classify small indoor objects suitable for safe suctioning and recycling during cleaning operations. However, the current state of research faces several difficulties, including the lack of a comprehensive dataset, size variation, limited visual features, occlusion and clutter, varying lighting conditions, the need for real-time processing, and edge computing. In this paper, I address these challenges by investigating a lightweight AI model specifically tailored for robot vacuum cleaners. First, I assembled a diverse dataset containing 23,042 ground-view perspective images captured by robot vacuum cleaners. Then, I examined state-of-the-art AI models from the existing literature and carefully selected three high-performance models (Xception, DenseNet121, and MobileNet) as potential model candidates. Subsequently, I simplified these three selected models to reduce their computational complexity and overall size. To further compress the model size, I employed post-training weight quantization on these simplified models. In this way, our proposed lightweight AI model strikes a balance between object classification accuracy and computational complexity, enabling real-time processing on resource-constrained robot vacuum cleaner platforms. I thoroughly evaluated the performance of the proposed AI model on a diverse dataset, demonstrating its feasibility and practical applicability. The experimental results show that, with a small memory size budget of 0.7 MB, the best AI model is L-w Xception 1, with a width factor of 0.25, whose resultant object classification accuracy is 84.37%. When compared with the most accurate state-of-the-art model in the literature, this proposed model accomplished a remarkable memory size reduction of 350 times, while incurring only a slight decrease in classification accuracy, i.e., approximately 4.54%.
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面向室内可移动物体的分类和回收:开发机器人吸尘器的轻量级AI模型
机器人真空吸尘器作为家用电器已经得到了广泛的普及。增强其功能的一个重大挑战是在清洁操作期间识别和分类适合安全吸吸和回收的小型室内物体。然而,目前的研究面临着一些困难,包括缺乏全面的数据集、尺寸变化、有限的视觉特征、遮挡和杂波、不同的光照条件、实时处理的需求以及边缘计算。在本文中,我通过研究专门为机器人吸尘器量身定制的轻量级AI模型来解决这些挑战。首先,我组装了一个多样化的数据集,其中包含由机器人真空吸尘器捕获的23,042张地面视角图像。然后,我从现有文献中检查了最先进的人工智能模型,并仔细选择了三个高性能模型(Xception, DenseNet121和MobileNet)作为潜在的模型候选。随后,我对这三个选择的模型进行了简化,以降低它们的计算复杂度和总体尺寸。为了进一步压缩模型的大小,我对这些简化的模型使用了训练后的权值量化。这样,我们提出的轻量级AI模型在物体分类精度和计算复杂度之间取得了平衡,能够在资源受限的机器人吸尘器平台上实现实时处理。我在不同的数据集上全面评估了所提出的AI模型的性能,证明了其可行性和实用性。实验结果表明,在内存预算为0.7 MB的情况下,最佳的AI模型是L-w Xception 1,其宽度因子为0.25,最终的目标分类准确率为84.37%。与文献中最精确的最先进的模型相比,该模型实现了显着的内存大小减少了350倍,而分类精度仅略有下降,即大约4.54%。
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来源期刊
Applied Sciences-Basel
Applied Sciences-Basel CHEMISTRY, MULTIDISCIPLINARYMATERIALS SCIE-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
5.30
自引率
11.10%
发文量
10882
期刊介绍: Applied Sciences (ISSN 2076-3417) provides an advanced forum on all aspects of applied natural sciences. It publishes reviews, research papers and communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files and software regarding the full details of the calculation or experimental procedure, if unable to be published in a normal way, can be deposited as supplementary electronic material.
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