Litcius/Paper detail

A physical model of mantis shrimp for exploring the dynamics of ultrafast systems

Emma Steinhardt, Nak-seung Patrick Hyun, Je‐Sung Koh, Gregory Freeburn, Michelle Rosen, Zeynep Temel, S. N. Patek, Robert J. Wood

2021Proceedings of the National Academy of Sciences63 citationsDOIOpen Access PDF

Abstract

Efficient and effective generation of high-acceleration movement in biology requires a process to control energy flow and amplify mechanical power from power density-limited muscle. Until recently, this ability was exclusive to ultrafast, small organisms, and this process was largely ascribed to the high mechanical power density of small elastic recoil mechanisms. In several ultrafast organisms, linkages suddenly initiate rotation when they overcenter and reverse torque; this process mediates the release of stored elastic energy and enhances the mechanical power output of extremely fast, spring-actuated systems. Here we report the discovery of linkage dynamics and geometric latching that reveals how organisms and synthetic systems generate extremely high-acceleration, short-duration movements. Through synergistic analyses of mantis shrimp strikes, a synthetic mantis shrimp robot, and a dynamic mathematical model, we discover that linkages can exhibit distinct dynamic phases that control energy transfer from stored elastic energy to ultrafast movement. These design principles are embodied in a 1.5-g mantis shrimp scale mechanism capable of striking velocities over 26 m [Formula: see text] in air and 5 m [Formula: see text] in water. The physical, mathematical, and biological datasets establish latching mechanics with four temporal phases and identify a nondimensional performance metric to analyze potential energy transfer. These temporal phases enable control of an extreme cascade of mechanical power amplification. Linkage dynamics and temporal phase characteristics are easily adjusted through linkage design in robotic and mathematical systems and provide a framework to understand the function of linkages and latches in biological systems.

Topics & Concepts

Mechanical energyTorqueAccelerationControl theory (sociology)Mechanical systemComputer scienceLinkage (software)Biological systemUltrashort pulsePhysicsMechanicsPower (physics)Artificial intelligenceClassical mechanicsBiologyControl (management)OpticsGeneLaserQuantum mechanicsBiochemistryThermodynamicsBiomimetic flight and propulsion mechanismsMicro and Nano RoboticsRobotic Locomotion and Control