The JSK (Jouhou System Kougaku) team from The University of Tokyo was selected as one of the 32 finalist teams out of 134 applicants to participate in the second edition of the Mohamed Bin Zayed International Robotic Challenge (MBZIRC) held in 2020. One of the challenges (Challenge 1) required an aerial robot to detect, follow and catch a yellow ball hanging underneath a fast-moving drone. In this challenge, we developed an articulated aerial robot that could intercept the target. This study presents reliable vision-based detection, target-trajectory estimation, fast interception-planning, and -control. Furthermore, we discuss outdoor experiments for evaluating our hardware and software systems, as well as the competition results in Abu Dhabi. With our developed system, we achieved third place in Challenge 1, as one of only four teams in the entire competition to successfully intercept the moving target.
A multilinked structure can benefit aerial robots in terms of both maneuvering and manipulation owing to its ability of aerial transformation. A coplanar multilinked model was developed in our previous study. However, the maneuvering and manipulation performances of that model were limited owing to the weak controllability. Therefore, we adopt tilted propellers in this study to enhance controllability.The related design, modeling, and control method are developed to achieve stable hovering and transformation with tilted propellers. Further, state estimation which involves time synchronization between sensors and multilinked kinematics is also presented in this study to enable fully autonomous flight in outdoor environments.The experimental evaluation of the design, modeling, and control method is performed to verify stability during aerial transformation. While, various autonomous outdoor experiments including trajectory following, fast maneuvering for intercepting a target, object grasping for delivery, and blanket manipulation for firefighting are also performed to verify the versatility of the proposed robot platform.To the best of our knowledge, this is the first study of a multilinked aerial robot that can achieve fully autonomous flight and manipulation tasks in an outdoor environment. We also applied our platform in all challenges of the 2020 Mohammed Bin Zayed International Robotics Competition, and we ranked in the third place in Challenge 1 and in the sixth place in Challenge 3 internationally, thereby demonstrating the reliable flight performance in the fields.
Snake-like robots have been developing in recent decades, and various bio-inspired ideas are deployed in both the mechanical and locomotion aspects. In recent years, several studies have proposed state-of-the-art snake-like aerial robots, which are beyond bio-inspiration. The achievement of snake-like aerial robots benefits both aerial maneuvering and manipulation, thereby having importance in various fields, such as industry surveillance and disaster rescue. In this work, we introduce our development of the modular aerial robot which can be considered a snake-like robot with high maneuverability in flight. To achieve such flight, we first proposed a unique thrust vectoring apparatus equipped with dual rotors to enable three-dimensional thrust force. Then, a generalized modeling method based on dynamics approximation is proposed to allocate the wrench in the center-of-gravity (CoG) frame to thrust forces and vectoring angles. We further developed a generalized control framework that can handle both under-actuated and fully actuated models. Finally, we show the experimental results with two different platforms to evaluate the flight stability of the proposed snake-like aerial robot. We believe that the proposed generalized methods can provide a solid foundation for the snake-like aerial robot and its applications regarding maneuvering and manipulation in midair.
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