FlipWalker: Self-Inverting Robot Locomotion Inspired by ‘Jacob’s Ladder’ Falling Block Illusion Toy

Abstract

This study presents a novel, underactuated robot locomotion system inspired by the Jacob's Ladder illusion toy, aimed at overcoming challenges encountered by wheeled locomotion on rugged and soft terrains. The system comprises interconnected body segments using flexible wires, offering inherent robustness and scalability due to its simple design. The motion is achieved through servo-controlled rotations, with joint locations adapting as segments pivot around each other. These segments utilize wires as hinges and tension-based constraints, enabling perpetual rotations, thereby propelling the robot forward while remaining flat on the ground. The manufacturing process involves rapid 3D printing for housing and CNC machining for PCB board fabrication. Flexible hinges are attached using threaded bolts, providing tension adjustability. The robot's microcontroller setup involves separate controllers for each body segment, communicating with a central offboard microcontroller for sensor data aggregation, configuration determination, and servo control. This modular design ensures easy addition and removal of segments without disrupting the overall electrical connectivity. The developed locomotion system showcases potential for enhanced adaptability and performance in challenging terrains.