We present a unified model-based and data-driven approach for quadrupedal planning and control to achieve dynamic locomotion over uneven terrain. We utilize on-board proprioceptive and exteroceptive feedback to map sensory information and desired base velocity commands into footstep plans using a reinforcement learning (RL) policy. This RL policy is trained in simulation over a wide range of procedurally generated terrains. When run online, the system tracks the generated footstep plans using a model-based motion controller. We evaluate the robustness of our method over a wide variety of complex terrains. It exhibits behaviors that prioritize stability over aggressive locomotion. Additionally, we introduce two ancillary RL policies for corr...
© 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
To dynamically traverse challenging terrain, legged robots need to continually perceive and reason a...
Robotic technologies will continue to enter new applications in addition to automated manufacturing ...
The ability to form support contacts at discontinuous locations makes legged robots suitable for loc...
Quadruped robots possess advantages on different terrains over other types of mobile robots by virtu...
This paper presents a control framework that combines model-based optimal control and reinforcement ...
Legged locomotion can extend the operational domain of robots to some of the most challenging enviro...
This paper presents a control framework that combines model-based optimal control and reinforcement ...
This paper addresses the problem of legged locomotion in non-flat terrain. As legged robots such as ...
Deep reinforcement learning (DRL) offers a promising approach for the synthesis of control policies ...
We present a novel approach to legged locomotion over rough terrain that is thoroughly rooted in opt...
Abstract—We present a novel approach to legged locomotion over rough terrain that is thoroughly root...
Legged robots promise an advantage over traditional wheeled systems, however, most legged robots are...
Abstract: Learning controllers that reproduce legged locomotion in nature have been a long-time goa...
Today’s robotic quadruped systems can walk over a diverse set of natural and complex terrains. Appro...
© 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
To dynamically traverse challenging terrain, legged robots need to continually perceive and reason a...
Robotic technologies will continue to enter new applications in addition to automated manufacturing ...
The ability to form support contacts at discontinuous locations makes legged robots suitable for loc...
Quadruped robots possess advantages on different terrains over other types of mobile robots by virtu...
This paper presents a control framework that combines model-based optimal control and reinforcement ...
Legged locomotion can extend the operational domain of robots to some of the most challenging enviro...
This paper presents a control framework that combines model-based optimal control and reinforcement ...
This paper addresses the problem of legged locomotion in non-flat terrain. As legged robots such as ...
Deep reinforcement learning (DRL) offers a promising approach for the synthesis of control policies ...
We present a novel approach to legged locomotion over rough terrain that is thoroughly rooted in opt...
Abstract—We present a novel approach to legged locomotion over rough terrain that is thoroughly root...
Legged robots promise an advantage over traditional wheeled systems, however, most legged robots are...
Abstract: Learning controllers that reproduce legged locomotion in nature have been a long-time goa...
Today’s robotic quadruped systems can walk over a diverse set of natural and complex terrains. Appro...
© 2022 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
To dynamically traverse challenging terrain, legged robots need to continually perceive and reason a...
Robotic technologies will continue to enter new applications in addition to automated manufacturing ...