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Detection of Dorsal Hand Vein Based on Improved YOLO Nano and Embedded System |
Zhao Dechun*, Tian Yuanyuan, Chen Huan, Zhao Zehan, Chen Yi, Yuan Yang |
(College of Bio-information, Chongqing University of Posts and Telecommunications, Chongqing 400065, China) |
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Abstract As the most fundamental medical means, venipuncture remains challenging for medical workers. This paper proposed a vein detection and location method for near infrared image. Firstly, an embedded system based on the near-infrared was designed, by which the vein images of both left and right dorsal hand from 43 subjects were captured to finally build a database composed of 325 dorsal hand vein images after preprocessing. Secondly, YOLO Nano algorithm was improved by trimming the network structure to reduce the model size and the output scale to adapt to the size of the detection target. The spatial pyramid pooling structure was introduced to improve the detection accuracy for its strong detail feature description and efficient feature computation. The database was divided into training set and test set in a proportion of 7∶3 and labeled and expanded. After tested on our embedded system, the results showed that the size of the improved YOLO Nano was reduced by 15%, while the average precision (AP) was increased from 91.68% to 93.23% and the detection time reached 529 ms, reduced by 22% compared to YOLO Nano. The improved YOLO Nano outperformed the original YOLO Nano in terms of both detection speed and accuracy, which realized the detection of puncturable veins.
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Received: 24 September 2021
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Corresponding Authors:
*E-mail: zhaodc@cqupt.edu.cn
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