부산대학교 도서관

Purcell's planar three-link microswimmer is a classic model of swimming at low-Reynolds-number fluid, inspired by motion of flagellated microorganisms. Many works analyzed this model, assuming that the two joint angles are directly prescribed in phase-shifted periodic inputs. In this work, we study a more realistic scenario by considering an extension of this model which accounts for joints' elasticity and mechanical actuation of periodic torques, so that the joint angles are dynamically evolving. Numerical analysis of the swimmer's dynamics reveals multiplicity of periodic solutions, depending on parameters of the inputs - frequency and amplitude of excitation, as well as joints' stiffness. We numerically study bifurcations, stability transitions, and symmetry breaking of the periodic solutions, demonstrating that this simple model displays rich nonlinear dynamic behavior with actuated-elastic joints.