Robust equalization of multi-lane electromechanical actuators: Comparative analysis of torque-summed and velocity-summed architectures
Annaz, Fawaz (2025) Robust equalization of multi-lane electromechanical actuators: Comparative analysis of torque-summed and velocity-summed architectures. Aerospace Science and Technology, 168. p. 111129. ISSN 1270-9638
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Abstract
The increasing demand for energy-efficient, low-emission aircraft has accelerated the transition toward all-electric aircraft (AEA), driving the need for highly reliable electromechanical actuators (EMAs) in flight-critical systems. A major challenge in multi-lane EMA configurations lies in torque and velocity disparities caused by component mismatches, sensor drift, and mechanical tolerances. These discrepancies can result in force-fight, increased mechanical stress, and reduced control accuracy, necessitating robust equalisation strategies. This study investigates force equalisation and lane equalisation in torque-summed and velocity-summed EMA architectures to mitigate lane-torque disparities () and enhance system robustness. A four-lane redundant EMA system, originally designed to actuate the inboard aileron of the Sea Harrier aircraft, was modelled in MATLAB–Simulink with a proportional–integral–derivative (PID) controller and Monitoring–Voting–Averaging Devices (MVADs) for feedback processing. Three-phase motor models were included to capture torque-ripple effects, and simulations were conducted across a range of inertial and aerodynamic load conditions. The results show that force equalisation effectively reduces lane-torque disparities in torque-summed architectures, improving load sharing and resilience under tachometer and potentiometer drift. In contrast, the velocity-summed architecture is inherently torque-balanced (lane-torque disparity ΔT is approximately zero), so lane equalisation has limited effect on . A potentiometer bias appears as a steady tracking offset that equalisation alone does not remove. These findings highlight critical trade-offs between architectures and underscore the importance of advanced equalisation and adaptive control strategies to further optimise EMA performance in next-generation all-electric aircraft. Although framed by an aerospace EMA, the methods and conclusions are not domain specific. The closed-form equalisation laws, cross-monitoring, and analysis of sensor-bias mechanisms generalise to multi-lane system architectures in robotics, automotive drive-by-wire, industrial automation, wind-turbine blade-pitch control, marine actuation, and medical and assistive devices.
| Item Type: | Article |
|---|---|
| Identification Number: | 10.1016/j.ast.2025.111129 |
| Dates: | Date Event 20 October 2025 Accepted 22 October 2025 Published Online |
| Uncontrolled Keywords: | All-electric aircraft, Electromechanical actuators, Safety-critical systems, Torque and Velocity summed architectures, Equalisation strategies (force and lane equalisation), Sensor drift, Adaptive and robust control |
| Subjects: | CAH10 - engineering and technology > CAH10-01 - engineering > CAH10-01-01 - engineering (non-specific) |
| Divisions: | Architecture, Built Environment, Computing and Engineering > Engineering |
| Depositing User: | Gemma Tonks |
| Date Deposited: | 01 Dec 2025 13:38 |
| Last Modified: | 01 Dec 2025 13:38 |
| URI: | https://www.open-access.bcu.ac.uk/id/eprint/16741 |
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