SOPHIBIAN: an amphi-underwater robot
Multiple highly manoeuvrable robots have become the focus of heated discussion lately, especially in applications involving disaster rescue, military missions and underwater or extra-terrestrial explorations. The surroundings concerned are harsh and hazardous terrains, and predictably the malfunctio...
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Format: | Copyright |
Language: | English English |
Published: |
2020
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Online Access: | http://irep.iium.edu.my/81713/1/81713_SOPHIBIAN%20an%20amphi-underwater%20robot_WORK.pdf http://irep.iium.edu.my/81713/12/81713%20SOPHIBIAN%20CR1.pdf http://irep.iium.edu.my/81713/ |
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Institution: | Universiti Islam Antarabangsa Malaysia |
Language: | English English |
Summary: | Multiple highly manoeuvrable robots have become the focus of heated discussion lately, especially in applications involving disaster rescue, military missions and underwater or extra-terrestrial explorations. The surroundings concerned are harsh and hazardous terrains, and predictably the malfunction rate is high. Thus a highly robust autonomous robot that could manoeuvre not only on all terrain but also underwater is of prime importance. One of the most crucial aspects of the legged robot is to optimize the executing patterns of leg-joint angles which is known as gaits. Synthesizing gaits by manual tuning control is a complex and time-consuming task which becomes even more challenging when the vehicles operates underwater. However, the mechanism presented in the literature are focusing on individual mechanism either on-land or underwater gait configuration. In fact, both mechanisms are tackled separately whereas, in a typical application such as surveillance and disaster management, both mechanisms can be integrated and executed appropriately to fulfill bigger objectives in a better optimized relocate position, as well as in faster completion time. When operating on both land and underwater, any motion of the limbs could apply forces to the robot. Efficient gait identification must therefore be modelled to mitigate these unwanted forces while meeting the desired gait properties. This research proposed automatic gait synthesis system for a hybrid amphi-underwater robot. The system utilizes an exponential momentum ant colony optimization which provides randomization and attractive parameter adaptation during the iteration process. The resulting will improve significantly not only maneuvering time but also optimizing total energy usage during operating cycle. |
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