基于TensorRT加速推理的电梯内电动车检测系统
Electric Two-Wheelers Detection System in Elevator Based on TensorRT Accelerated In-ference
DOI: 10.12677/CSA.2022.124086, PDF,   
作者: 高胥智, 魏伟波:青岛大学,计算机科学技术学院,山东 青岛;王 静:青岛市崂山区育才学校,山东 青岛
关键词: YOLOXTensorRTJetsonNano目标检测深度学习YOLOX TensorRT JetsonNano Object Detection Deep Learning
摘要: 电动车入户充电存在安全隐患,容易发生火灾,针对高层住户电动车入户充电的问题,本文提出了基于TensorRT加速推理的电梯内电动车检测系统,通过在电梯内部署电动车检测设备来有效遏制高层住户电动车入户的问题。该系统使用YOLOX网络训练目标检测模型,数据类型分为电动摩托车、电动自行车与自行车三类,通过模型迁移将训练好的目标检测模型部署到JetsonNano设备上,该设备通过Jetson-GPIO来做到对电梯的控制。实验结果表明,基于TensorRT加速推理的电梯内电动车检测系统,在性能与识别准确率上均优于传统方法,该设备能够有效遏制高层住户电动车入户问题。
Abstract: Electric two-wheelers charging at home has potential safety hazards and is prone to fires. In order to solve the problem of charging electric two-wheelers at home by high-rise residents, this paper proposes an electric two-wheelers detection system in elevators based on TensorRT accelerated inference. By deploying electric two-wheelers detection equipment in the elevator, this situation can be effectively contained. The system uses YOLOX to train the target detection model to distinguish electric motorcycles, electric bicycles and bicycles, and then deploys the trained target detection model to JetsonNano devices through model of migration. The device uses Jetson-GPIO to control the elevator. Experimental results show that the electric two-wheelers target detection system in elevators based on TensorRT accelerated inference is superior to traditional methods in performance and accuracy. The equipment can effectively curb the problem of electric two-wheelers entering the homes of high-rise residents.
文章引用:高胥智, 魏伟波, 王静. 基于TensorRT加速推理的电梯内电动车检测系统[J]. 计算机科学与应用, 2022, 12(4): 847-857. https://doi.org/10.12677/CSA.2022.124086

参考文献

[1] 刘纯银. 治理电动车“上楼入户”要疏堵结合[N]. 钦州日报, 2021-07-13(002).
[2] 史一棋, 孙立极. 解决电动自行车停放和充电问题需综合施策[N]. 人民日报, 2021-07-05(007).
[3] 吴文诩. 禁止电动车“上楼入户”须下“狠手” [N]. 新华每日电讯, 2021-05-12(011).
[4] 静子. 电动车出电梯, 安全意识进人心[J]. 人民周刊, 2021(9): 18.
[5] 张文韬. 基于边缘计算的电动车入户充电检测方法研究[D]: [硕士学位论文]. 合肥: 安徽建筑大学, 2021.
[6] Ge, Z., Liu, S.T., Wang, F., Li, Z.M. and Sun, J. (2021) YOLOX: Exceeding YOLO Series in 2021. [Google Scholar] [CrossRef
[7] 周立君, 刘宇, 白璐, 刘飞, 王亚伟. 使用TensorRT进行深度学习推理[J]. 应用光学, 2020, 41(2): 337-341.
[8] 施一飞. 对使用TensorRT加速AI深度学习推断效率的探索[J]. 科技视界, 2017(31): 26-27.
[9] Jeong, E., Kim, J., Tan, S., Lee, J. and Ha, S. (2021) Deep Learning Inference Parallelization on Heterogeneous Processors with TensorRT. IEEE Embedded Systems Letters, 14, 15-18.
[10] 陈欢. 基于YOLO的移动端视频目标跟踪的设计与实现[D]: [硕士学位论文]. 哈尔滨: 黑龙江大学, 2021.
[11] Chen, Y.-C., Fathoni, H. and Yang, C.-T. (2020) Implementation of Fire and Smoke Detection Using DeepStream and Edge Computing Approachs. 2020 International Conference on Pervasive Artificial Intelligence (ICPAI), Taipei, 3-5 December 2020, 272-275. [Google Scholar] [CrossRef
[12] Uddin, M.I., Alamgir, M.S., Rahman, M.M., Bhuiyan, M.S. and Moral, M.A. (2021) AI Traffic Control System Based on DeepStream and IoT Using NVIDIA Jetson Nano. 2021 2nd International Conference on Robotics, Electrical and Signal Processing Techniques (ICREST), DHAKA, 5-7 January 2021, 115-119. [Google Scholar] [CrossRef
[13] Süzen, A., Duman, B. and Şen, B. (2020) Benchmark Analysis of Jetson TX2. Jetson Nano and Raspberry PI Using Deep-CNN. 2020 International Congress on Hu-man-Computer Interaction, Optimization and Robotic Applications (HORA), Ankara, 26-28 June 2020, 1-5. [Google Scholar] [CrossRef