The main part of an AGV includes its body, motor, driver, processor, and sensors, which are more or less the same in all types of AGVs, and addons vary depending on the application and the work environment. Even recently, they have been used in libraries to carry books on shelves. The group's use in the industry ranges from applications for carrying pallets, carts, and utensils to helping the elderly or transporting medicine to hospitals. Sci.Automated guided vehicles (AGVs) are popular subsets of robots that come in various shapes and sizes. Magán E., et al.: Driver drowsiness detection by applying deep learning techniques to sequences of images. In: 2019 International Conference on Robots & Intelligent System (ICRIS). 1–6 (2019)ĭuo, N., et al.: A deep reinforcement learning based Mapless navigation algorithm using continuous actions. of Information and Communication Technology for Embedded Systems (IC-ICTES), Bangkok, Thailand, pp. Maolanon, P., Sukvichai, K., Chayopitak, N., Takahashi, A.: Indoor room identify and mapping with virtual based SLAM using furnitures and household objects relationship based on CNNs. Zhao, X., Jia, H., Ni, Y.: A novel three-dimensional object detection with the modified You only look once method. In: 2018 Latin American Robotic Symposium, 2018 Brazilian Symposium on Robotics (SBR) and 2018 Workshop on Robotics in Education (WRE), Pessoa, Brazil, pp. 1–5 (2018)īersan, D., Martins, R., Campos, M., Nascimento, E.R.: Semantic map augmentation for robot navigation: a learning approach based on visual and depth data. In: 2018 IEEE International Conference on Automation, Quality and Testing, Robotics (AQTR), Cluj-Napoca, Romania, pp. Lucian, A., Sandu, A., Orghidan, R., Moldovan, D.: Human leg detection from depth sensing. In: 2017 International Conference on Communication and Signal (2017) Tenguria, R., Parkhedkar, S., Modak, N., Madan, R., Tondwalkar, A.: Design framework for general purpose object recognition on a robotic platform. Redmon, J., Farhadi, A.: YOLOv3: an incremental improvement. In: Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Las Vegas, NV, USA, pp. Redmon, J., Divvala, S., Girshick, R., Farhadi, A.: You only look once: unified, real-time object detection. Ren, S., He, K., Girshick, R., Sun, J.: Faster R-CNN: towards real-time object detection with region proposal networks. Smprobotics - Autonomous Mobile Robot and Unmanned Ground Vehicles. Lei, T., et al.: Virtual-to-real deep reinforcement learning: continuous control of mobile robots for mapless navigation. Computer Vision and Pattern Recognition (2019). Hu, H.-N., et al.: Joint Monocular 3D Vehicle Detection and Tracking. In: CoRL - 2022 Conference on Robot Learning, Dec 14–18, 2022 – Auckland, NZ. arXiv:1807.00275 (2018)įeng, Z., et al.: Advancing self-supervised monocular depth learning with sparse LiDAR. Computer Vision and Pattern Recognition (cs.CV) Artificial Intelligence (cs.AI) Machine Learning (cs.LG) Robotics (cs.RO). Ma, F., et al.: Self-supervised Sparse-to-Dense: Self-supervised Depth Completion from LiDAR and Monocular Camera. In: 9th International Conference on Control, Automation, Robotics and Vision, ICARCV 2006, pp. Nishimura, S., Itou, K., Kikuchi, T., Takemura, H., Mizoguchi, H.: A study of robotizing daily items for an autonomous carrying system-development of person following shopping cart robot. The experimental findings demonstrate the method's precision and effectiveness including sensors, algorithms, and mapping technologies that enable the robot to identify obstacles and navigate around the AGV. Even with a minimal configuration, the algorithm is appropriate for the automaton. It can function autonomously or manually via the local network. Using its built-in distance tracking algorithm, the robot can also detect and adjust its speed to safely follow the individual in front at an appropriate distance. A customized development of the TensorFlowLite ESP32 module from the TensorFlow CoCo SSD model enables the ESP32-CAM camera module on the robot to self-identify objects and autonomously follow the human object in front. Using a model of a four-wheeled self-propelled robot vehicle, a highly adaptable and modifiable platform AGV was built. This paper proposes a solution for the AGV (Autonomous Guided Vehicles) robot to effectively monitor a moving object using deep learning by enabling the robot to learn and recognize movement patterns.
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