Kavli Affiliate: Morteza Gharib
| First 5 Authors: Fengze Xie, Fengze Xie, , ,
| Summary:
Fixed-wing unmanned aerial vehicles (UAVs) offer endurance and efficiency but
lack low-speed agility due to highly coupled dynamics. We present an end-to-end
sensing-to-control pipeline that combines bio-inspired hardware,
physics-informed dynamics learning, and convex control allocation. Measuring
airflow on a small airframe is difficult because near-body aerodynamics,
propeller slipstream, control-surface actuation, and ambient gusts distort
pressure signals. Inspired by the narwhal’s protruding tusk, we mount in-house
multi-hole probes far upstream and complement them with sparse, carefully
placed wing pressure sensors for local flow measurement. A data-driven
calibration maps probe pressures to airspeed and flow angles. We then learn a
control-affine dynamics model using the estimated airspeed/angles and sparse
sensors. A soft left/right symmetry regularizer improves identifiability under
partial observability and limits confounding between wing pressures and
flaperon inputs. Desired wrenches (forces and moments) are realized by a
regularized least-squares allocator that yields smooth, trimmed actuation.
Wind-tunnel studies across a wide operating range show that adding wing
pressures reduces force-estimation error by 25-30%, the proposed model degrades
less under distribution shift (about 12% versus 44% for an unstructured
baseline), and force tracking improves with smoother inputs, including a 27%
reduction in normal-force RMSE versus a plain affine model and 34% versus an
unstructured baseline.
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