Academic Journal of Engineering and Technology Science, 2024, 7(5); doi: 10.25236/AJETS.2024.070506.
Zhaoting Guo
International School of Beijing, Beijing, China
This abstract summarizes a detailed exploration of the design, development, and functionality of a terrain detection robot intended for extraterrestrial exploration. The primary objective of this robot is to enhance the safety and efficiency of space probes by enabling them to navigate diverse terrains without damage. The document elaborates on the robot's design, incorporating innovative features like ground hardness detection through applied force and feedback mechanisms for adaptive movement. Significant research has been referenced to highlight the robot's capability to adapt to various ground types, from swamps to deserts, which typically pose substantial risks to mobility due to their complex surfaces. For instance, technologies like the Probabilistic Neural Network and Support Vector Machines are utilized for surface classification based on texture features extracted using methods such as Local Binary Patterns and Speeded Robust Features. The robot's architecture includes a robust mechanical structure with aluminum alloy components and high-torque motors adapted for different gravitational pulls of various celestial bodies. A pivotal feature of the robot is its ability to reposition itself rather than reverse when encountering impassable terrain, which is facilitated by a unique wheel design and sophisticated control systems. This document also discusses the practical challenges and theoretical implications of designing robotic systems for space exploration, including durability tests over simulated extraterrestrial surfaces and the integration of advanced sensors and AI to improve navigational decisions. The business model outlined in the document's conclusion suggests a strategic approach to commercializing this technology for space exploration applications.
Extraterrestrial Navigation, Terrain Detection, Adaptive Mobility, Robotic Exploration
Zhaoting Guo. Multi-environment Adaptive Terrain Detection and Navigation Robot. Academic Journal of Engineering and Technology Science (2024) Vol. 7, Issue 5: 32-42. https://doi.org/10.25236/AJETS.2024.070506.
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