Conventional control systems for autonomous aircraft use a small number of precise sensors in combination with classical control laws to maintain flight. The sensing systems encode center of mass motion and generally are set-up for flight regimes where rigid body assumptions and linear flight dynamics models are valid. Gain scheduling is used to overcome some of the limitations from these assumptions, taking advantage of well-tuned controllers over a range of design points. In contrast, flying animals achieve efficient and robust flight control by taking advantage of highly non-linear structural dynamics and aerodynamics. It has been suggested that the distributed arrays of flow and force sensors found in flying animals could be behind thei...
High-angles-of-attack dynamics of aircraft are complicated with dangerous phenomena such as wing roc...
In this work, a learning model-free control method is proposed for accurate trajectory tracking and ...
The paper introduces a control technique for autonomous formation flight that does not require inter...
Flying animals exploit highly nonlinear dynamics to achieve efficient and robust flight control. It ...
Small fixed-wing unmanned aerial systems (UAS) may require increased agility when operating in turbu...
Recent research suggests that the information obtained from arrays of sensors distributed on the win...
Conventional control systems for autonomous aircraft use a small number of precise sensors encoding ...
The energy efficiency and flight endurance of small unmanned aerial vehicles (SUAVs) can be improved...
Unmanned Aerial Vehicles (UAV) design may involve issues on redundancy of the systems due to restric...
This paper presents a nonlinear gust-attenuation controller based on constrained neural-network (NN)...
This article proposes an adaptive flight framework that integrates a discrete-time incremental nonli...
In this work, a new intelligent control strategy based on neural networks is proposed to cope with s...
Inspired by the exceptional flight ability of birds and insects, a bio-inspired neural adaptive flig...
Arrays of sensors distributed on the wing of fixed-wing vehicles can provide information not directl...
This thesis presents the development of small, inexpensive unmanned aerial vehicles (UAVs) to achie...
High-angles-of-attack dynamics of aircraft are complicated with dangerous phenomena such as wing roc...
In this work, a learning model-free control method is proposed for accurate trajectory tracking and ...
The paper introduces a control technique for autonomous formation flight that does not require inter...
Flying animals exploit highly nonlinear dynamics to achieve efficient and robust flight control. It ...
Small fixed-wing unmanned aerial systems (UAS) may require increased agility when operating in turbu...
Recent research suggests that the information obtained from arrays of sensors distributed on the win...
Conventional control systems for autonomous aircraft use a small number of precise sensors encoding ...
The energy efficiency and flight endurance of small unmanned aerial vehicles (SUAVs) can be improved...
Unmanned Aerial Vehicles (UAV) design may involve issues on redundancy of the systems due to restric...
This paper presents a nonlinear gust-attenuation controller based on constrained neural-network (NN)...
This article proposes an adaptive flight framework that integrates a discrete-time incremental nonli...
In this work, a new intelligent control strategy based on neural networks is proposed to cope with s...
Inspired by the exceptional flight ability of birds and insects, a bio-inspired neural adaptive flig...
Arrays of sensors distributed on the wing of fixed-wing vehicles can provide information not directl...
This thesis presents the development of small, inexpensive unmanned aerial vehicles (UAVs) to achie...
High-angles-of-attack dynamics of aircraft are complicated with dangerous phenomena such as wing roc...
In this work, a learning model-free control method is proposed for accurate trajectory tracking and ...
The paper introduces a control technique for autonomous formation flight that does not require inter...