Online DCM Trajectory Generation for Push Recovery of Torque-Controlled Humanoid Robots

Shafiee, Milad; Romualdi, Giulio; Dafarra, Stefano; Chavez, Francisco Javier Andrade; Pucci, Daniele

doi:10.1109/humanoids43949.2019.9034996

Cited by 17 publications

(13 citation statements)

References 29 publications

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“…where we used the identities α DS (T DS ) = 0 and γ DS (T DS ) = 1. As Ṽi+1 is the same as Ṽankle during the following single support phase, the result in ( 21) is identical to the one obtained by evaluating (15) for t = 0. On the other hand, Ξankle is discontinuous at the end of the single support phase and the start of the following double support phase (see Fig.…”

Section: B Set Of Dcm Errors Correctable By Ankle Strategy Alonesupporting

confidence: 59%

“…A footstep adaptation algorithm based on DCM dynamics and using an exponential interpolation of the ZMP trajectory was proposed in [15], but the step adaptation was active only during the single support phase. Jeong et al [16] presented a robust walking controller based on the DCM dynamics using an online optimization solver to combine the ankle, hip, and stepping strategies.…”

Section: Introductionmentioning

confidence: 99%

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Online DCM Trajectory Adaptation for Push and Stumble Recovery during Humanoid Locomotion

Mesesan

Englsberger

Ott

2021

2021 IEEE International Conference on Robotics and Automation (ICRA)

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In this paper, we present a highly efficient Divergent Component of Motion (DCM) reference trajectory generator capable of adapting online to large perturbations acting on the center-of-mass (push recovery) and on the swing foot (stumble recovery). For push recovery, we propose an analytic solution for a footstep adjustment strategy based on the DCM dynamics. The proposed algorithm considers double support phases explicitly and is active throughout the motion, i.e., during both single and double support phases. For stumble recovery, we introduce a continuous DCM trajectory adaptation based on the instantaneous tracking error of the swing foot. Our method is highly efficient, computing a push recovery solution within 10 microseconds on the robot hardware. Furthermore, it achieves robust locomotion for large external perturbations, which we demonstrate in simulations and experiments with the humanoid robot TORO.

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Section: B Set Of Dcm Errors Correctable By Ankle Strategy Alonesupporting

confidence: 59%

Section: Introductionmentioning

confidence: 99%

Online DCM Trajectory Adaptation for Push and Stumble Recovery during Humanoid Locomotion

Mesesan

Englsberger

Ott

2021

2021 IEEE International Conference on Robotics and Automation (ICRA)

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“…Throughout the walking process, the ZMP is located in the stable support area, achieving stable control. The ability to reject 400 N and last 0.1 s external force in this paper is better than literature [20], which is 350 N and 0.05 s, respectively, and it also better than literature [21], which is 6.0 Nm. This simulation proves that when the model is disturbed by external forces, it can quickly recover the original stable walking state and achieve the desired goal.…”

Section: Disturbance Recovery In Walkingmentioning

confidence: 55%

Simulation of Disturbance Recovery Based on MPC and Whole-Body Dynamics Control of Biped Walking

Shi

Gao

et al. 2020

Sensors

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Biped robots are similar to human beings and have broad application prospects in the fields of family service, disaster rescue and military affairs. However, simplified models and fixed center of mass (COM) used in previous research ignore the large-scale stability control ability implied by whole-body motion. The present paper proposed a two-level controller based on a simplified model and whole-body dynamics. In high level, a model predictive control (MPC) controller is implemented to improve zero moment point (ZMP) control performance. In low level, a quadratic programming optimization method is adopted to realize trajectory tracking and stabilization with friction and joint constraints. The simulation shows that a 12-degree-of-freedom force-controlled biped robot model, adopting the method proposed in this paper, can recover from a 40 Nm disturbance when walking at 1.44 km/h without adjusting the foot placement, and can walk on an unknown 4 cm high stairs and a rotating slope with a maximum inclination of 10°. The method is also adopted to realize fast walking up to 6 km/h.

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“…Another interesting future work is the implementation of a footstep adjustment algorithm. 43,44,45 This will increase the overall robustness in case of large disturbances acting on the robot.…”

Section: Discussionmentioning

confidence: 99%

A Benchmarking of DCM-Based Architectures for Position, Velocity and Torque-Controlled Humanoid Robots

Romualdi

Dafarra

et al. 2020

Int. J. Human. Robot.

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This paper contributes towards the benchmarking of control architectures for bipedal robot locomotion. It considers architectures that are based on the Divergent Component of Motion (DCM) and composed of three main layers: trajectory optimization, simplified model control, and whole-body QP control layer. While the first two layers use simplified robot models, the whole-body QP control layer uses a complete robot model to produce either desired positions, velocities, or torques inputs at the joint-level. This paper then compares two implementations of the simplified model control layer, which are tested with position, velocity, and torque control modes for the whole-body QP control layer. In particular, both an instantaneous and a Receding Horizon controller are presented for the simplified model control layer. We show also that one of the proposed architectures allows the humanoid robot iCub to achieve a forward walking velocity of 0.3372 meters per second, which is the highest walking velocity achieved by the iCub robot.

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Online DCM Trajectory Generation for Push Recovery of Torque-Controlled Humanoid Robots

Cited by 17 publications

References 29 publications

Online DCM Trajectory Adaptation for Push and Stumble Recovery during Humanoid Locomotion

Online DCM Trajectory Adaptation for Push and Stumble Recovery during Humanoid Locomotion

Simulation of Disturbance Recovery Based on MPC and Whole-Body Dynamics Control of Biped Walking

A Benchmarking of DCM-Based Architectures for Position, Velocity and Torque-Controlled Humanoid Robots

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