Embedded System-Based Malaria Detection From Blood Smear Images Using Lightweight Deep Learning Model

IF 3 4区 计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Abdus Salam, S. M. Nahid Hasan, Md. Jawadul Karim, Shamim Anower, Md Nahiduzzaman, Muhammad E. H. Chowdhury, M. Murugappan
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引用次数: 0

Abstract

The disease of malaria, transmitted by female Anopheles mosquitoes, is highly contagious, resulting in numerous deaths across various regions. Microscopic examination of blood cells remains one of the most accurate methods for malaria diagnosis, but it is time-consuming and can produce inaccurate results occasionally. Due to machine learning and deep learning advances in medical diagnosis, improved diagnostic accuracy can now be achieved while costs can be reduced compared to conventional microscopy methods. This work utilizes an open-source dataset with 26 161 blood smear images in RGB for malaria detection. Our preprocessing resized the original dimensions of the images into 64 × 64 due to the limitations in computational complexity in developing embedded systems-based malaria detection. We present a novel embedded system approach using 119 154 trainable parameters in a lightweight 17-layer SqueezeNet model for the automatic detection of malaria. Incredibly, the model is only 1.72 MB in size. An evaluation of the model's performance on the original NIH malaria dataset shows that it has exceptional accuracy, precision, recall, and F1 scores of 96.37%, 95.67%, 97.21%, and 96.44%, respectively. Based on a modified dataset, the results improved further to 99.71% across all metrics. Compared to current deep learning models, our model significantly outperforms them for malaria detection, making it ideal for embedded systems. This model has also been rigorously tested on the Jetson Nano B01 edge device, demonstrating a rapid single image prediction time of only 0.24 s. The fusion of deep learning with embedded systems makes this research a crucial step toward improving malaria diagnosis. In resource-constrained settings, the model's lightweight architecture and accuracy enhancements hold great promise for addressing the critical challenge of malaria detection.

利用轻量级深度学习模型,基于嵌入式系统从血液涂片图像中检测疟疾
疟疾是由雌性按蚊传播的疾病,具有高度传染性,导致各地无数人死亡。显微镜检查血细胞仍然是诊断疟疾最准确的方法之一,但这种方法耗时较长,偶尔也会产生不准确的结果。由于机器学习和深度学习在医疗诊断领域的进步,现在可以实现更高的诊断准确性,同时与传统的显微镜检查方法相比可以降低成本。这项工作利用了一个开源数据集,其中包含 26 161 张 RGB 血涂片图像,用于疟疾检测。由于在开发基于嵌入式系统的疟疾检测时受到计算复杂度的限制,我们的预处理将图像的原始尺寸调整为 64 × 64。我们提出了一种新颖的嵌入式系统方法,在轻量级 17 层 SqueezeNet 模型中使用 119 154 个可训练参数来自动检测疟疾。令人难以置信的是,该模型的大小仅为 1.72 MB。对模型在原始 NIH 疟疾数据集上的性能进行的评估表明,该模型的准确率、精确率、召回率和 F1 分数分别为 96.37%、95.67%、97.21% 和 96.44%,表现优异。基于修改后的数据集,所有指标的结果进一步提高到 99.71%。与当前的深度学习模型相比,我们的模型在疟疾检测方面明显优于它们,是嵌入式系统的理想选择。该模型还在 Jetson Nano B01 边缘设备上进行了严格测试,结果表明单张图像的快速预测时间仅为 0.24 秒。深度学习与嵌入式系统的融合使这项研究朝着改善疟疾诊断迈出了关键一步。在资源有限的环境下,该模型的轻量级架构和准确性的提高为应对疟疾检测这一关键挑战带来了巨大希望。
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来源期刊
International Journal of Imaging Systems and Technology
International Journal of Imaging Systems and Technology 工程技术-成像科学与照相技术
CiteScore
6.90
自引率
6.10%
发文量
138
审稿时长
3 months
期刊介绍: The International Journal of Imaging Systems and Technology (IMA) is a forum for the exchange of ideas and results relevant to imaging systems, including imaging physics and informatics. The journal covers all imaging modalities in humans and animals. IMA accepts technically sound and scientifically rigorous research in the interdisciplinary field of imaging, including relevant algorithmic research and hardware and software development, and their applications relevant to medical research. The journal provides a platform to publish original research in structural and functional imaging. The journal is also open to imaging studies of the human body and on animals that describe novel diagnostic imaging and analyses methods. Technical, theoretical, and clinical research in both normal and clinical populations is encouraged. Submissions describing methods, software, databases, replication studies as well as negative results are also considered. The scope of the journal includes, but is not limited to, the following in the context of biomedical research: Imaging and neuro-imaging modalities: structural MRI, functional MRI, PET, SPECT, CT, ultrasound, EEG, MEG, NIRS etc.; Neuromodulation and brain stimulation techniques such as TMS and tDCS; Software and hardware for imaging, especially related to human and animal health; Image segmentation in normal and clinical populations; Pattern analysis and classification using machine learning techniques; Computational modeling and analysis; Brain connectivity and connectomics; Systems-level characterization of brain function; Neural networks and neurorobotics; Computer vision, based on human/animal physiology; Brain-computer interface (BCI) technology; Big data, databasing and data mining.
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