TY - GEN
T1 - Robust Null-Space Controller with Sliding Mode for Hierarchical Task Execution in Multi-Robot Formations
T2 - 9th Ecuador Technical Chapters Meeting, ETCM 2025
AU - Nazate, Zahid
AU - Andaluz, Gabriela M.
AU - Leica, Paulo
AU - Camacho, Oscar
AU - Proaño, Pablo
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - This work presents a Robust Null Space (RNS) control strategy for hierarchical task execution in multi-robot formations under reference changes. The controller integrates a task-priority null-space framework with a PI-based Sliding Mode Controller (SMC) to enhance tracking performance during reference changes. The proposed scheme addresses two hierarchical tasks: (i) posture regulation as the primary objective and (ii) shape preservation as the secondary objective. Unlike traditional approaches, the RNS controller employs a PI sliding surface to improve convergence and reduce steady-state errors. A Lyapunovbased analysis guarantees the asymptotic stability of the closed-loop system. Experimental validation with a triangular formation of three Turtlebot3 robots shows that the RNS controller achieves up to 26.10% improvement in IAE and 4.43% in ISE over a traditional Null Space controller, demonstrating its robustness and practical effectiveness. These results not only demonstrate the potential of hierarchical control approaches in multi-robot coordination but also provide relevant tools for real-world applications in logistics, cooperative exploration, and collaborative load transportation, where robustness against disturbances and reference changes is critical.
AB - This work presents a Robust Null Space (RNS) control strategy for hierarchical task execution in multi-robot formations under reference changes. The controller integrates a task-priority null-space framework with a PI-based Sliding Mode Controller (SMC) to enhance tracking performance during reference changes. The proposed scheme addresses two hierarchical tasks: (i) posture regulation as the primary objective and (ii) shape preservation as the secondary objective. Unlike traditional approaches, the RNS controller employs a PI sliding surface to improve convergence and reduce steady-state errors. A Lyapunovbased analysis guarantees the asymptotic stability of the closed-loop system. Experimental validation with a triangular formation of three Turtlebot3 robots shows that the RNS controller achieves up to 26.10% improvement in IAE and 4.43% in ISE over a traditional Null Space controller, demonstrating its robustness and practical effectiveness. These results not only demonstrate the potential of hierarchical control approaches in multi-robot coordination but also provide relevant tools for real-world applications in logistics, cooperative exploration, and collaborative load transportation, where robustness against disturbances and reference changes is critical.
KW - formation
KW - multi-robot
KW - Null Space Control
KW - Robust Control
KW - Sliding Mode Control
KW - task-priority
UR - https://www.scopus.com/pages/publications/105032508179
U2 - 10.1109/ETCM67548.2025.11304337
DO - 10.1109/ETCM67548.2025.11304337
M3 - Contribución a la conferencia
AN - SCOPUS:105032508179
T3 - ETCM 2025 - 9th Ecuador Technical Chapters Meeting
BT - ETCM 2025 - 9th Ecuador Technical Chapters Meeting
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 21 October 2025 through 24 October 2025
ER -