Add to ORKGContemporary autopilot systems for unmanned aerial vehicles (UAVs) are far more limited in their flight envelope as compared to experienced human pilots, thereby restricting the conditions UAVs can operate in and the types of missions they can accomplish autonomously. This paper proposes a deep reinforcement learning (DRL) controller to handle the nonlinear attitude control problem, enabling extended flight envelopes for fixed-wing UAVs. A proof-of-concept controller using the proximal policy optimization (PPO) algorithm is developed, and is shown to be capable of stabilizing a fixed-wing UAV from a large set of initial conditions to reference roll, pitch and airspeed values. The training process is outlined and key factors for its progress...
Machine learning is an ever-expanding field of research with a wide range of potential applications....
To achieve the perception-based autonomous control of UAVs, schemes with onboard sensing and computi...
To control unmanned aerial systems, we rarely have a perfect system model. Safe and aggressive plann...
Contemporary autopilot systems for unmanned aerial vehicles (UAVs) are far more limited in their fli...
This paper presents a robust technique for an Unmanned Aerial Vehicle (UAV) with the ability to fly ...
We present a deep neural net-based controller trained by a model-free reinforcement learning (RL) al...
Deep reinforcement learning is a promising method for training a nonlinear attitude controller for f...
Autonomous systems extend upon human capabilities and can be equipped with superhuman attributes in ...
Reinforcement Learning (RL) is a learning paradigm where an agent learns a task by trial and error. ...
The use of multi-rotor UAVs in industrial and civil applications has been extensively encouraged by ...
In this paper we apply deep reinforcement learning techniques on a multicopter for learning a stable...
This thesis investigates the possibility of using reinforcement learning (RL) techniques to create a...
This research study presents a new adaptive attitude and altitude controller for an aerial robot. Th...
A novel intelligent controller selection method for quadrotor attitude and altitude control is prese...
Deep Reinforcement Learning (DRL) is attracting increasing interest due to its ability to learn how ...
Machine learning is an ever-expanding field of research with a wide range of potential applications....
To achieve the perception-based autonomous control of UAVs, schemes with onboard sensing and computi...
To control unmanned aerial systems, we rarely have a perfect system model. Safe and aggressive plann...
Contemporary autopilot systems for unmanned aerial vehicles (UAVs) are far more limited in their fli...
This paper presents a robust technique for an Unmanned Aerial Vehicle (UAV) with the ability to fly ...
We present a deep neural net-based controller trained by a model-free reinforcement learning (RL) al...
Deep reinforcement learning is a promising method for training a nonlinear attitude controller for f...
Autonomous systems extend upon human capabilities and can be equipped with superhuman attributes in ...
Reinforcement Learning (RL) is a learning paradigm where an agent learns a task by trial and error. ...
The use of multi-rotor UAVs in industrial and civil applications has been extensively encouraged by ...
In this paper we apply deep reinforcement learning techniques on a multicopter for learning a stable...
This thesis investigates the possibility of using reinforcement learning (RL) techniques to create a...
This research study presents a new adaptive attitude and altitude controller for an aerial robot. Th...
A novel intelligent controller selection method for quadrotor attitude and altitude control is prese...
Deep Reinforcement Learning (DRL) is attracting increasing interest due to its ability to learn how ...
Machine learning is an ever-expanding field of research with a wide range of potential applications....
To achieve the perception-based autonomous control of UAVs, schemes with onboard sensing and computi...
To control unmanned aerial systems, we rarely have a perfect system model. Safe and aggressive plann...