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Bibliographic Details
Main Authors: Hassan, Muhammad Saud Ul, Vasquez, Derek, Asif, Hamza, Hubicki, Christian
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.05402
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author Hassan, Muhammad Saud Ul
Vasquez, Derek
Asif, Hamza
Hubicki, Christian
author_facet Hassan, Muhammad Saud Ul
Vasquez, Derek
Asif, Hamza
Hubicki, Christian
contents In this paper, we present an energy-conservation based control architecture for stable dynamic motion in quadruped robots. We model the robot as a Spring-loaded Inverted Pendulum (SLIP), a model well-suited to represent the bouncing motion characteristic of running gaits observed in various biological quadrupeds and bio-inspired robotic systems. The model permits leg-orientation control during flight and leg-length control during stance, a design choice inspired by natural quadruped behaviors and prevalent in robotic quadruped systems. Our control algorithm uses the reduced-order SLIP dynamics of the quadruped to track a stable parabolic spline during stance, which is calculated using the principle of energy conservation. Through simulations based on the design specifications of an actual quadruped robot, Ghost Robotics Minitaur, we demonstrate that our control algorithm generates stable bouncing gaits. Additionally, we illustrate the robustness of our controller by showcasing its ability to maintain stable bouncing even when faced with up to a 10% error in sensor measurements.
format Preprint
id arxiv_https___arxiv_org_abs_2511_05402
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stable and Robust SLIP Model Control via Energy Conservation-Based Feedback Cancellation for Quadrupedal Applications
Hassan, Muhammad Saud Ul
Vasquez, Derek
Asif, Hamza
Hubicki, Christian
Robotics
In this paper, we present an energy-conservation based control architecture for stable dynamic motion in quadruped robots. We model the robot as a Spring-loaded Inverted Pendulum (SLIP), a model well-suited to represent the bouncing motion characteristic of running gaits observed in various biological quadrupeds and bio-inspired robotic systems. The model permits leg-orientation control during flight and leg-length control during stance, a design choice inspired by natural quadruped behaviors and prevalent in robotic quadruped systems. Our control algorithm uses the reduced-order SLIP dynamics of the quadruped to track a stable parabolic spline during stance, which is calculated using the principle of energy conservation. Through simulations based on the design specifications of an actual quadruped robot, Ghost Robotics Minitaur, we demonstrate that our control algorithm generates stable bouncing gaits. Additionally, we illustrate the robustness of our controller by showcasing its ability to maintain stable bouncing even when faced with up to a 10% error in sensor measurements.
title Stable and Robust SLIP Model Control via Energy Conservation-Based Feedback Cancellation for Quadrupedal Applications
topic Robotics
url https://arxiv.org/abs/2511.05402