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Main Authors: Vogel, Dylan, Baines, Robert, Church, Joseph, Lotzer, Julian, Werner, Karl, Hutter, Marco
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.17731
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author Vogel, Dylan
Baines, Robert
Church, Joseph
Lotzer, Julian
Werner, Karl
Hutter, Marco
author_facet Vogel, Dylan
Baines, Robert
Church, Joseph
Lotzer, Julian
Werner, Karl
Hutter, Marco
contents Quadruped robots are proliferating in industrial environments where they carry sensor payloads and serve as autonomous inspection platforms. Despite the advantages of legged robots over their wheeled counterparts on rough and uneven terrain, they are still unable to reliably negotiate a ubiquitous feature of industrial infrastructure: ladders. Inability to traverse ladders prevents quadrupeds from inspecting dangerous locations, puts humans in harm's way, and reduces industrial site productivity. In this paper, we learn quadrupedal ladder climbing via a reinforcement learning-based control policy and a complementary hooked end effector. We evaluate the robustness in simulation across different ladder inclinations, rung geometries, and inter-rung spacings. On hardware, we demonstrate zero-shot transfer with an overall 90% success rate at ladder angles ranging from 70° to 90°, consistent climbing performance during unmodeled perturbations, and climbing speeds 232x faster than the state of the art. This work expands the scope of industrial quadruped robot applications beyond inspection on nominal terrains to challenging infrastructural features in the environment, highlighting synergies between robot morphology and control policy when performing complex skills. More information can be found at the project website: https://sites.google.com/leggedrobotics.com/climbingladders.
format Preprint
id arxiv_https___arxiv_org_abs_2409_17731
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robust Ladder Climbing with a Quadrupedal Robot
Vogel, Dylan
Baines, Robert
Church, Joseph
Lotzer, Julian
Werner, Karl
Hutter, Marco
Robotics
Quadruped robots are proliferating in industrial environments where they carry sensor payloads and serve as autonomous inspection platforms. Despite the advantages of legged robots over their wheeled counterparts on rough and uneven terrain, they are still unable to reliably negotiate a ubiquitous feature of industrial infrastructure: ladders. Inability to traverse ladders prevents quadrupeds from inspecting dangerous locations, puts humans in harm's way, and reduces industrial site productivity. In this paper, we learn quadrupedal ladder climbing via a reinforcement learning-based control policy and a complementary hooked end effector. We evaluate the robustness in simulation across different ladder inclinations, rung geometries, and inter-rung spacings. On hardware, we demonstrate zero-shot transfer with an overall 90% success rate at ladder angles ranging from 70° to 90°, consistent climbing performance during unmodeled perturbations, and climbing speeds 232x faster than the state of the art. This work expands the scope of industrial quadruped robot applications beyond inspection on nominal terrains to challenging infrastructural features in the environment, highlighting synergies between robot morphology and control policy when performing complex skills. More information can be found at the project website: https://sites.google.com/leggedrobotics.com/climbingladders.
title Robust Ladder Climbing with a Quadrupedal Robot
topic Robotics
url https://arxiv.org/abs/2409.17731