Deep Learning for Precise Robot Position Prediction in Logistics

Authors

  • Chang Che The George Washington University, Mechanical Engineering, Atlanta, Georgia, USA
  • Bo Liu Zhejiang University, Hangzhou, Zhejiang, China
  • Shulin Li Trine University, Information Studies, Phoenix, Arizona, USA
  • Jiaxin Huang Trine University, Information Studies, Phoenix, Arizona, USA
  • Hao Hu Zhejiang University, Hangzhou, Zhejiang, China

DOI:

https://doi.org/10.53469/jtpes.2023.03(10).05

Keywords:

Logistics Automation, Robot Control, Sensor Data Analysis, Deep Learning, Position Prediction

Abstract

This study presents an interdisciplinary investigation at the nexus of mechanical engineering and computer science, aimed at advancing the field of logistics automation. In response to the escalating demands of global cargo transportation, the integration of these disciplines assumes paramount importance. Conducted within the domain of Dortmund University of Technology’s Material Flow and Warehousing Chair, this research focuses on the precise control of robots, a task contingent on accurate positional information. Leveraging a controlled internal logistics precinct, the study delves into the transformation of raw sensor data, comprising accelerometers, gyroscopes, and magnetometers, into precise position predictions. This process entails meticulous data preprocessing, encompassing synchronization and calibration procedures, yielding crucial parameters such as absolute velocity and accelerations along both parallel and perpendicular axes. The study employs deep learning, specifically a 2D Convolutional Neural Network (2D-CNN), for predictive modeling. This architecture excels in extracting intricate spatial features from sensor data. Training is conducted under the guidance of an Asymmetric Gaussian loss function, custom-tailored to accommodate the idiosyn- crasies of real-world sensor data. The results evince the efficacy of this approach, evidenced by remarkably low mean squared errors in predicting robot positions. Beyond its immediate applications in logistics automation, this research underscores the potential of interdisciplinary collaboration in addressing complex sensor data challenges.

References

Sebastian Thrun. Probabilistic robotics. Communications of the ACM, 45(3):52–57, 2002.

Alberto Elfes. Sonar-based real-world mapping and navigation. IEEE Journal on Robotics and Automation, 3(3):249–265, 1987.

Michael Montemerlo, Sebastian Thrun, Daphne Koller, Ben Wegbreit, et al. Fastslam: A factored solution to the simulta- neous localization and mapping problem. Aaai/iaai, 593598, 2002.

Tim Bailey, Juan Nieto, and Eduardo Nebot. Consistency of the fastslam algorithm. In Proceedings 2006 IEEE Interna- tional Conference on Robotics and Automation, 2006. ICRA 2006., pages 424–429. IEEE, 2006.

Jesse Levinson, Jake Askeland, Jan Becker, Jennifer Dolson, David Held, Soeren Kammel, J Zico Kolter, Dirk Langer, Oliver Pink, Vaughan Pratt, et al. Towards fully autonomous driving: Systems and algorithms. In 2011 IEEE intelligent vehicles symposium (IV), pages 163–168. IEEE, 2011.

Andre Mateus, David Ribeiro, Pedro Miraldo, and Jacinto C Nascimento. Efficient and robust pedestrian detection using deep learning for human-aware navigation. Robotics and Autonomous Systems, 113:23–37, 2019.

Song Tianbo, Hu Weijun, Cai Jiangfeng, Liu Weijia, Yuan Quan, and He Kun. Bio-inspired swarm intelligence: a flocking project with group object recognition. In 2023 3rd International Conference on Consumer Electronics and Computer Engineering (ICCECE), pages 834–837. IEEE, 2023.

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Published

2023-10-31

How to Cite

Che, C., Liu, B., Li, S., Huang, J., & Hu, H. (2023). Deep Learning for Precise Robot Position Prediction in Logistics. Journal of Theory and Practice of Engineering Science, 3(10), 36–41. https://doi.org/10.53469/jtpes.2023.03(10).05