Trajectory generation of straightened knee walking for humanoid robot iCub

Li, Zhibin; Tsagarikis, Nikos G.; Caldwell, Darwin G.; Vanderborght, Bram

doi:10.1109/icarcv.2010.5707828

Cited by 17 publications

(15 citation statements)

References 17 publications

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“…10(a) depicts Roboray's dynamic walking. Roboray performs fully knee stretched-walking compared to the conventional knee bent walkers requiring larger knee joint torques [17]. Fig.…”

Section: A Walking On Level Groundmentioning

confidence: 99%

Control design to achieve dynamic walking on a bipedal robot with compliance

Lim

Lee

Kim

et al. 2012

2012 IEEE International Conference on Robotics and Automation

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We propose a control framework for dynamic bipedal locomotion with compliant joints. A novel 3D dynamic walking is achieved by utilizing natural dynamics of the system. It is done by 1) driving robot joints directly with the posturebased state machine and 2) controlling tendon-driven compliant actuators. To enlarge gait's basin attraction for stable walking, we also adaptively plan step-to-step motion and compensate stance/swing motion. Final joint input is described by a superposition of state machine control torques and compensation torques of balancers. Various walking styles are easily generated by composing straight and turning gait-primitives and such walking is effectively able to adapt on various environments. Our proposed method is applied to a torque controlled robot platform, Roboray. Experimental results show that gaits are able to traverse inclined and rough terrains with bounded variations, and the result gaits are human-like comparing the conventional knee bent walkers.

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“…10(a) depicts Roboray's dynamic walking. Roboray performs fully knee stretched-walking compared to the conventional knee bent walkers requiring larger knee joint torques [17]. Fig.…”

Section: A Walking On Level Groundmentioning

confidence: 99%

Control design to achieve dynamic walking on a bipedal robot with compliance

Lim

Lee

Kim

et al. 2012

2012 IEEE International Conference on Robotics and Automation

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show abstract

“…From the 3D feasible space, we can compute the 2D feasibility region, F 2D ⊂ R 2 , in the x-y plane where the CoM must be located, shown as the shaded green region in Figure 4. To do so, we assume that the distance from the CoM to each hip can be treated as a constant, a fairly common [10] and accurate assumption due to the mass distribution on most humanoid robots. This allows us to offset the sphere origins from the ankle locations, defining the blue circles in Figure 4 as s l and s r , enabling us to directly consider the CoM rather than the hip locations as in Figure 3.…”

Section: Center Of Mass Adjustment Calculationmentioning

confidence: 99%

“…Several works have attempted to address planning and control of appropriate height trajectories for straighter legs. In [10], the authors presented an approach for generating straightened-knee trajectories by combining model predictive control (MPC) of the ZMP to generate horizontal CoM trajectories with a spring-damper approach to generate vertical CoM trajectories. Alternatively, [11] used linear differential inclusion to incorporate these height trajectories directly into the MPC, resulting in relatively natural, cyclical motions of the CoM.…”

Section: Introductionmentioning

confidence: 99%

“…While some previous works are capable of generating kinematically feasible height trajectories [10], [11], these approaches, along with most others, typically rely on arbitrarily chosen single and double support phase durations. While kinematic feasibility of the CoM height plan is guaranteed, this has the fundamental limitation of ignoring the effects of step timing on the resulting horizontal CoM plans.…”

Section: Introductionmentioning

confidence: 99%

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Capture point trajectories for reduced knee bend using step time optimization

Griffin

Bertrand

Wiedebach

et al. 2017

2017 IEEE-RAS 17th International Conference on Humanoid Robotics (Humanoids)

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Traditional force-controlled bipedal walking utilizes highly bent knees, resulting in high torques as well as inefficient, and unnatural motions. Even with advanced planning of center of mass height trajectories, significant amounts of knee-bend can be required due to arbitrarily chosen step timing. In this work, we present a method that examines the effects of adjusting the step timing to produce plans that only require a specified amount of knee bend to execute. We define a quadratic program that optimizes the step timings and is executed using a simple iterative feedback approach to account for higher order terms. We then illustrate the effectiveness of this algorithm by comparing the walking gait of the simulated Atlas humanoid with and without the algorithm, showing that the algorithm significantly reduces the required knee bend for execution. We aim to later use this approach to achieve natural, efficient walking motions on humanoid robot platforms.

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“…The general objective becomes to design trajectories that result in the robot's legs being as straight as possible without violating the kinematics or the centroidal dynamics. In [10], the authors presented an approach for generating straightened-knee trajectories by modeling the legs as spring dampers to compute the CoM height after generating horizontal trajectories using model predictive control (MPC) of the ZMP. Alternatively, [11] used linear differential inclusion to incorporate these height trajectories directly into the MPC, resulting in relatively natural, cyclic motions of the CoM.…”

Section: Introductionmentioning

confidence: 99%

Straight-Leg Walking Through Underconstrained Whole-Body Control

Griffin

Wiedebach

Bertrand

et al. 2018

2018 IEEE International Conference on Robotics and Automation (ICRA)

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We present an approach for achieving a natural, efficient gait on bipedal robots using straightened legs and toe-off. Our algorithm avoids complex height planning by allowing a whole-body controller to determine the straightest possible leg configuration at run-time. The controller solutions are biased towards a straight leg configuration by projecting leg joint angle objectives into the null-space of the other quadratic program motion objectives. To allow the legs to remain straight throughout the gait, toe-off was utilized to increase the kinematic reachability of the legs. The toe-off motion is achieved through underconstraining the foot position, allowing it to emerge naturally. We applied this approach of under-specifying the motion objectives to the Atlas humanoid, allowing it to walk over a variety of terrain. We present both experimental and simulation results and discuss performance limitations and potential improvements.

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Trajectory generation of straightened knee walking for humanoid robot iCub

Cited by 17 publications

References 17 publications

Control design to achieve dynamic walking on a bipedal robot with compliance

Control design to achieve dynamic walking on a bipedal robot with compliance

Capture point trajectories for reduced knee bend using step time optimization

Straight-Leg Walking Through Underconstrained Whole-Body Control

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