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Main Authors: Pretto, Riccardo, Hamandi, Mahmoud, Ali, Abdullah Mohamed, Alcan, Gokhan, Tzes, Anthony, Abu-Dakka, Fares
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.06832
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_version_ 1866915842023751680
author Pretto, Riccardo
Hamandi, Mahmoud
Ali, Abdullah Mohamed
Alcan, Gokhan
Tzes, Anthony
Abu-Dakka, Fares
author_facet Pretto, Riccardo
Hamandi, Mahmoud
Ali, Abdullah Mohamed
Alcan, Gokhan
Tzes, Anthony
Abu-Dakka, Fares
contents Fully actuated omnidirectional UAVs enable independent control of forces and torques along all six degrees of freedom, broadening the operational envelope for agile flight and aerial interaction tasks. However, conventional control allocation methods neglect the asymmetric dynamics of the onboard actuators, which can induce oscillatory motor commands and degrade trajectory tracking during dynamic maneuvers. This work proposes a receding-horizon, actuation-aware allocation strategy that explicitly incorporates asymmetric motor dynamics and exploits the redundancy of over-actuated platforms through nullspace optimization. By forward-simulating the closed-loop system over a prediction horizon, the method anticipates actuator-induced oscillations and suppresses them through smooth redistribution of motor commands, while preserving the desired body wrench exactly. The approach is formulated as a constrained optimal control problem solved online via Constrained iterative LQR. Simulation results on the OmniOcta platform demonstrate that the proposed method significantly reduces motor command oscillations compared to a conventional single-step quadratic programming allocator, yielding improved trajectory tracking in both position and orientation.
format Preprint
id arxiv_https___arxiv_org_abs_2603_06832
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Receding-Horizon Nullspace Optimization for Actuation-Aware Control Allocation in Omnidirectional UAVs
Pretto, Riccardo
Hamandi, Mahmoud
Ali, Abdullah Mohamed
Alcan, Gokhan
Tzes, Anthony
Abu-Dakka, Fares
Robotics
Fully actuated omnidirectional UAVs enable independent control of forces and torques along all six degrees of freedom, broadening the operational envelope for agile flight and aerial interaction tasks. However, conventional control allocation methods neglect the asymmetric dynamics of the onboard actuators, which can induce oscillatory motor commands and degrade trajectory tracking during dynamic maneuvers. This work proposes a receding-horizon, actuation-aware allocation strategy that explicitly incorporates asymmetric motor dynamics and exploits the redundancy of over-actuated platforms through nullspace optimization. By forward-simulating the closed-loop system over a prediction horizon, the method anticipates actuator-induced oscillations and suppresses them through smooth redistribution of motor commands, while preserving the desired body wrench exactly. The approach is formulated as a constrained optimal control problem solved online via Constrained iterative LQR. Simulation results on the OmniOcta platform demonstrate that the proposed method significantly reduces motor command oscillations compared to a conventional single-step quadratic programming allocator, yielding improved trajectory tracking in both position and orientation.
title Receding-Horizon Nullspace Optimization for Actuation-Aware Control Allocation in Omnidirectional UAVs
topic Robotics
url https://arxiv.org/abs/2603.06832