Cognitive Abilities and Flight Performance in Helicopter Pilots across levels of Expertise

Objective: This study examines how cognitive abilities influence actual flight performance in military helicopter pilots of different expertise levels, based on Ackerman's theory of skill acquisition.Background: Ackerman's model states that the predictive role of cognitive abilities shifts across stages: general intelligence (g) in the cognitive stage, perceptual speed (PS) in the associative stage, and psychomotor ability (PM) in the autonomous stage. Few studies have tested this in complex domains such as helicopter piloting.Method: Twenty military helicopter pilots were divided into Co-pilot (N = 10) and Aircraft Commander (N = 10) groups. General intelligence was measured using a matrix reasoning task (similar to Raven's Matrices), perceptual speed with the Symbol Search, and psychomotor ability with the 4-Choice Reaction Time. Flight Performance was evaluated in real flight tasks by instructor pilots, and multiple regression analyses were applied to each group.Results: In the CP group, g was the strongest predictor (t = 4.53, p Conclusion: CP performance relies on general intelligence for procedural integration, while AC performance combines automated skills with strategic cognitive control. The helicopter's inherent instability demands active control over scanning, minimizing the role of perceptual speed.Application: These findings inform pilot training and professional development by highlighting different cognitive demands across expertise levels.