Abstract—In this paper, we formulate a novel hierarchical controller for walking of torque controlled humanoid robots. Our method uses an online whole body optimization approach which generates joint torques, given Cartesian accelerations of different points on the robot. Over such variable translation, we can plan our desired foot trajectories in Cartesian space between starting and ending positions of the foot on the ground. On top level, we use the simplified Linear Inverted Pendulum Model to predict the future motion of the robot. With LIPM, we derive a formulation where the whole system is described by the state of center of mass and footstep locations serve as discrete inputs to this linear system. We then use model predictive control...
Biped robots are inherently unstable because of their complex kinematics as well as dynamics. Despit...
Abstract — Humanoid robots have many potential applica-tions in man-made environments, including per...
International audienceThis paper proposes a novel approach to online replan the walking trajectory o...
International audienceLocomotion of biped robots requires predictive controllers due to its unstable...
IROS 2018A common approach to the generation of walking patterns for humanoid robots consists in ado...
Robust locomotion is a challenging task for humanoid robots, especially when considering dynamic dis...
This paper presents a Model Predictive Control (MPC) scheme capable of generating a 3D gait for a hu...
We propose a locomotion framework for bipedal robots consisting of a new motion planning method, dub...
<p>This thesis presents an online approach for controlling humanoid robots using hierarchical optimi...
Design and control of the bipedal humanoid robot locomotion are challenging areas of research. Accur...
This paper presents a general method for generating walking primitives for anthropomorphic 3D--biped...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
We present a real-time algorithm for humanoid 3D walking and/or running based on a Model Predictive ...
This thesis presents a predictive control approach to generate trajectories for humanoid robots. To ...
This paper proposes a novel orientation-aware model predictive control (MPC) for dynamic humanoid wa...
Biped robots are inherently unstable because of their complex kinematics as well as dynamics. Despit...
Abstract — Humanoid robots have many potential applica-tions in man-made environments, including per...
International audienceThis paper proposes a novel approach to online replan the walking trajectory o...
International audienceLocomotion of biped robots requires predictive controllers due to its unstable...
IROS 2018A common approach to the generation of walking patterns for humanoid robots consists in ado...
Robust locomotion is a challenging task for humanoid robots, especially when considering dynamic dis...
This paper presents a Model Predictive Control (MPC) scheme capable of generating a 3D gait for a hu...
We propose a locomotion framework for bipedal robots consisting of a new motion planning method, dub...
<p>This thesis presents an online approach for controlling humanoid robots using hierarchical optimi...
Design and control of the bipedal humanoid robot locomotion are challenging areas of research. Accur...
This paper presents a general method for generating walking primitives for anthropomorphic 3D--biped...
2018-07-26In this work, we explore computationally lightweight optimization-based methods for planni...
We present a real-time algorithm for humanoid 3D walking and/or running based on a Model Predictive ...
This thesis presents a predictive control approach to generate trajectories for humanoid robots. To ...
This paper proposes a novel orientation-aware model predictive control (MPC) for dynamic humanoid wa...
Biped robots are inherently unstable because of their complex kinematics as well as dynamics. Despit...
Abstract — Humanoid robots have many potential applica-tions in man-made environments, including per...
International audienceThis paper proposes a novel approach to online replan the walking trajectory o...