Zhenyu Gan scite author profile

In this paper, we systematically investigate passive gaits that emerge from the natural mechanical dynamics of a bipedal system. We use an energetically conservative model of a simple spring-leg biped that exhibits well-defined swing leg dynamics. Through a targeted continuation of periodic motions of this model, we systematically identify different gaits that emerge from simple bouncing in place. We show that these gaits arise along one-dimensional manifolds that bifurcate into different branches with distinctly different motions. The branching is associated with repeated breaks in symmetry of the motion. Among others, the resulting passive dynamic gaits include walking, running, hopping, skipping and galloping. Our work establishes that the most common bipedal gaits can be obtained as different oscillatory motions (or nonlinear modes) of a single mechanical system with a single set of parameter values. For each of these gaits, the timing of swing leg motion and vertical motion is matched. This work thus supports the notion that different gaits are primarily a manifestation of the underlying natural mechanical dynamics of a legged system. Our results might explain the prevalence of certain gaits in nature, and may provide a blueprint for the design and control of energetically economical legged robots.

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Passive Dynamics Explain Quadrupedal Walking, Trotting, and Tölting

Gan

Wiestner

Weishaupt

et al. 2015

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This paper presents a simplistic passive dynamic model that is able to create realistic quadrupedal walking, tölting, and trotting motions. The model is inspired by the bipedal spring loaded inverted pendulum (SLIP) model and consists of a distributed mass on four massless legs. Each of the legs is either in ground contact, retracted for swing, or is ready for touch down with a predefined angle of attack. Different gaits, that is, periodic motions differing in interlimb coordination patterns, are generated by choosing different initial model states. Contact patterns and ground reaction forces (GRFs) evolve solely from these initial conditions. By identifying appropriate system parameters in an optimization framework, the model is able to closely match experimentally recorded vertical GRFs of walking and trotting of Warmblood horses, and of tölting of Icelandic horses. In a detailed study, we investigated the sensitivity of the obtained solutions with respect to all states and parameters and quantified the improvement in fitting GRF by including an additional head and neck segment. Our work suggests that quadrupedal gaits are merely different dynamic modes of the same structural system and that we can interpret different gaits as different nonlinear elastic oscillations that propel an animal forward.

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On the Dynamic Similarity Between Bipeds and Quadrupeds: A Case Study on Bounding

Gan

Jiao

Remy

2018

IEEE Robot. Autom. Lett.

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Optimal configuration of series and parallel elasticity in a 2D Monoped

Yesilevskiy

Gan

Remy

2016

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This paper uses optimal control to simultaneously optimize the motion and morphology of a realistic model of a 2D Monoped. In particular, we compare the energetics of four different actuator configurations: a parallel elastic actuator (PEA) in the hip and a series elastic actuator in the leg (SEA), series hip and parallel leg, series hip and series leg, and parallel hip and parallel leg. We use realistic models with mass in the legs and feet, damping in the springs, and detailed DC electric motor models. The comparison is carried out for the cost of transport of three energetic measures: positive motor work, electrical losses, and positive electrical work, and evaluated as a function of velocity. In our optimization we include motor parameters, stiffness, and spring pre-compression terms as free variables, ensuring that we compare the energetically optimal version of each configuration at each velocity. We show that for the positive motor work and the electrical losses costs of transport (COT), the parallel hip and series leg configuration is energetically optimal. For the electrical work, the optimal configuration is speed dependent, with series hip and parallel leg optimal at low speeds, and both series hip series leg and parallel hip series leg optimal at high speeds.

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Toward Controllable Hydraulic Coupling of Joints in a Wearable Robot

2018

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In this paper, we develop theoretical foundations for a new class of rehabilitation robot: body powered devices that route power between a user’s joints. By harvesting power from a healthy joint to assist an impaired joint, novel bimanual and self-assist therapies are enabled. This approach complements existing robotic therapies aimed at promoting recovery of motor function after neurological injury. We employ hydraulic transmissions for routing power, or equivalently for coupling the motions of a user’s joints. Fluid power routed through flexible tubing imposes constraints within a limb or between homologous joints across the body. Variable transmissions allow constraints to be steered on the fly, and simple valve switching realizes free space and locked motion. We examine two methods for realizing variable hydraulic transmissions: using valves to switch among redundant cylinders (digital hydraulics) or using an intervening electromechanical link. For both methods, we present a rigorous mathematical framework for describing and controlling the resulting constraints. Theoretical developments are supported by experiments using a prototype fluid-power exoskeleton.

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Zhenyu Gan

All common bipedal gaits emerge from a single passive model

Passive Dynamics Explain Quadrupedal Walking, Trotting, and Tölting

On the Dynamic Similarity Between Bipeds and Quadrupeds: A Case Study on Bounding

Optimal configuration of series and parallel elasticity in a 2D Monoped

Toward Controllable Hydraulic Coupling of Joints in a Wearable Robot

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