TY - GEN
T1 - Terrain Classification Using Mars Raw Images Based on Deep Learning Algorithms with Application to Wheeled Planetary Rovers
AU - Guo, Junlong
AU - Zhang, Xingyang
AU - Dong, Yunpeng
AU - Xue, Zhao
AU - Huang, Bo
N1 - Publisher Copyright:
Copyright © 2022 by the International Society for Terrain-Vehicle Systems. All rights reserved.
PY - 2022
Y1 - 2022
N2 - Scene information plays a crucial role in motion control, attitude perception, and path planning for wheeled planetary rovers (WPRs). Terrain recognition is the fundamental component of scene recognition. Due to the rich information, visual sensors are usually used in terrain classification. However, teleoperation delay prevents WPRs from using visual information efficiently. End-to-end learning method of deep learning (DL) that does not need complex image preprocessing was proposed to deal with this issue. This paper first built a terrain dataset (consists of loose sand, bedrock, small rock, large rock, and outcrop) using real Mars images to directly support You Only Look Once (YOLOv5) to test its performance on terrain classification. Because the capability of end-to-end training scheme is positively correlated with dataset, the performance of YOLOv5 can be significantly improved by exploiting orders of magnitude more data. The best combination of hyperparameters and models was achieved by slightly tuning YOLOv5, and data augmentation was also applied to optimize its accuracy. Furthermore, its performance was compared with two other end-to-end network architectures. Deep learning algorithms can be used in the future planetary exploration missions, such as WPRs autonomy improvement, traversability analysis, and avoiding getting trapped.
AB - Scene information plays a crucial role in motion control, attitude perception, and path planning for wheeled planetary rovers (WPRs). Terrain recognition is the fundamental component of scene recognition. Due to the rich information, visual sensors are usually used in terrain classification. However, teleoperation delay prevents WPRs from using visual information efficiently. End-to-end learning method of deep learning (DL) that does not need complex image preprocessing was proposed to deal with this issue. This paper first built a terrain dataset (consists of loose sand, bedrock, small rock, large rock, and outcrop) using real Mars images to directly support You Only Look Once (YOLOv5) to test its performance on terrain classification. Because the capability of end-to-end training scheme is positively correlated with dataset, the performance of YOLOv5 can be significantly improved by exploiting orders of magnitude more data. The best combination of hyperparameters and models was achieved by slightly tuning YOLOv5, and data augmentation was also applied to optimize its accuracy. Furthermore, its performance was compared with two other end-to-end network architectures. Deep learning algorithms can be used in the future planetary exploration missions, such as WPRs autonomy improvement, traversability analysis, and avoiding getting trapped.
KW - Mars raw images
KW - deep convolutional neural network
KW - terrain classification
KW - wheeled planetary rover
UR - https://www.scopus.com/pages/publications/85219600991
U2 - 10.56884/WSDO4112
DO - 10.56884/WSDO4112
M3 - 会议稿件
AN - SCOPUS:85219600991
T3 - Proceedings of the 11th Asia-Pacific Regional Conference of the ISTVS
SP - 147
EP - 153
BT - Proceedings of the 11th Asia-Pacific Regional Conference of the ISTVS
PB - International Society for Terrain-Vehicle Systems
T2 - 11th Asia-Pacific Regional Conference of the International Society for Terrain-Vehicle Systems, ISTVS 2022
Y2 - 26 September 2022 through 28 September 2022
ER -