Experimental mitigation of large-amplitude transverse gusts via closed-loop pitch control

TL;DR

This paper presents an experimental closed-loop pitch control strategy based on classical unsteady aerodynamic theories to mitigate large-amplitude transverse gusts, improving flight safety and stability across various conditions.

Contribution

It develops and experimentally validates a physics-based lift regulation control strategy using Wagner and Kussner theories for gust mitigation without prior gust knowledge.

Findings

Successful generalization to different gust strengths and directions

Enhanced stability and robustness through feedback gain tuning

Flow physics analysis reveals key factors in lift transient mitigation

Abstract

Air vehicles of all scales are susceptible to large-amplitude gusts that may lead to vehicle damage and instability. Therefore, effective physics-based control strategies and an understanding of the dominant unsteady flow physics underpinning gust encounters are desired to improve safety and reliability of flight in these conditions. To this end, this paper develops and experimentally demonstrates a proportional output-feedback lift regulation strategy based on the classical unsteady aerodynamic theories of Wagner and Kussner for wings encountering large-amplitude transverse gusts without a priori knowledge of gust strength or onset time. The tested vertical gust velocities ranged between 25% and 71% of the freestream speed. This strategy is found to successfully generalize to gusts of different strengths and directions, as well as wings at pre- and post-stall angles of attack. In addition, this paper applies dynamical systems analysis to Wagner's aerodynamic model to reveal the effect of the pitch-axis location, pitch input, and closed-loop feedback gains on the stability and robustness of the system along with the flow physics responsible. The real-time output feedback control strategy is experimentally tested in a water tow tank facility equipped with a transverse gust generator. Time-resolved force and flow-field measurements are used to discover the salient flow physics during these encounters and illustrate how closed-loop actuation mitigates their lift transients.