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Main Authors: Robert, Clément, Vissiere, Alain, Company, Olivier, Noire, Pierre, Roux, Thierry, Krut, Sébastien
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.07141
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author Robert, Clément
Vissiere, Alain
Company, Olivier
Noire, Pierre
Roux, Thierry
Krut, Sébastien
author_facet Robert, Clément
Vissiere, Alain
Company, Olivier
Noire, Pierre
Roux, Thierry
Krut, Sébastien
contents Thermal expansion is a significant source of positioning error in high-precision hexapod robots (Gough-Stewart platforms). Any variation in the temperature of the hexapod's parts induces expansion, which alters their kinematic model and reduces the robot's accuracy and repeatability. These variations may arise from internal heat sources (such as motors, encoders, and electronics) or from environmental changes. In this study, a method is proposed to anticipate and therefore correct the thermal drift of one of the hexapod precision electro-mechanical actuators. This method is based on determining a model that links the expansion state of the actuator at any given moment to the temperature of some well-chosen points on its surface. This model was initially developed theoretically. Its coefficients were then adjusted experimentally on a specific test-bench, based on a rigorous measurement campaign of actuator expansion using a high-precision interferometric measurement system. Experimental validation demonstrates a reduction of thermally induced expansion by more than 80%. This paves the way for thermal drift correction across the entire robot or similar robotics parts.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07141
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Model-based thermal drift compensation for high-precision hexapod robot actuators
Robert, Clément
Vissiere, Alain
Company, Olivier
Noire, Pierre
Roux, Thierry
Krut, Sébastien
Robotics
Thermal expansion is a significant source of positioning error in high-precision hexapod robots (Gough-Stewart platforms). Any variation in the temperature of the hexapod's parts induces expansion, which alters their kinematic model and reduces the robot's accuracy and repeatability. These variations may arise from internal heat sources (such as motors, encoders, and electronics) or from environmental changes. In this study, a method is proposed to anticipate and therefore correct the thermal drift of one of the hexapod precision electro-mechanical actuators. This method is based on determining a model that links the expansion state of the actuator at any given moment to the temperature of some well-chosen points on its surface. This model was initially developed theoretically. Its coefficients were then adjusted experimentally on a specific test-bench, based on a rigorous measurement campaign of actuator expansion using a high-precision interferometric measurement system. Experimental validation demonstrates a reduction of thermally induced expansion by more than 80%. This paves the way for thermal drift correction across the entire robot or similar robotics parts.
title Model-based thermal drift compensation for high-precision hexapod robot actuators
topic Robotics
url https://arxiv.org/abs/2603.07141