Abstract
Counter-drone technology by using artificial intelligence (AI) is an emerging technology and it is rapidly developing. Considering the recent advances in AI, counter-drone systems with AI can be very accurate and efficient to fight against drones. The time required to engage with the target can be less than other methods based on human intervention, such as bringing down a malicious drone by a machine-gun. Also, AI can identify and classify the target with a high precision in order to prevent a false interdiction with the targeted object. We believe that counter-drone technology with AI will bring important advantages to the threats coming from some drones and will help the skies to become safer and more secure. In this study, a deep reinforcement learning (DRL) architecture is proposed to counter a drone with another drone, the learning drone, which will autonomously avoid all kind of obstacles inside a suburban neighborhood environment. The environment in a simulator that has stationary obstacles such as trees, cables, parked cars, and houses. In addition, another non-malicious third drone, acting as moving obstacle inside the environment was also included. In this way, the learning drone is trained to detect stationary and moving obstacles, and to counter and catch the target drone without crashing with any other obstacle inside the neighborhood. The learning drone has a front camera and it can capture continuously depth images. Every depth image is part of the state used in DRL architecture. There are also scalar state parameters such as velocities, distances to the target, distances to some defined geofences and track, and elevation angles. The state image and scalars are processed by a neural network that joints the two state parts into a unique flow. Moreover, transfer learning is tested by using the weights of the first full-trained model. With transfer learning, one of the best jump-starts achieved higher mean rewards (close to 35 more) at the beginning of training. Transfer learning also shows that the number of crashes during training can be reduced, with a total number of crashed episodes reduced by 65%, when all ground obstacles are included.
Highlights
According to the European Air Traffic Management (ATM) master plan drone roadmap [1], the unmanned aerial Vehicles (UAV), known as drones, will scale their flights and their operations beyond visual line of sight (BVLOS) will cover most of the air traffic by 2035
A deep reinforcement learning (DRL) architecture is proposed to counter a drone with another drone, the learning drone, which will autonomously avoid all kind of obstacles inside a suburban neighborhood environment
Transfer learning shows that the number of crashes during training can be reduced, with a total number of crashed episodes reduced by 65%, when all ground obstacles are included
Summary
According to the European Air Traffic Management (ATM) master plan drone roadmap [1], the unmanned aerial Vehicles (UAV), known as drones, will scale their flights and their operations beyond visual line of sight (BVLOS) will cover most of the air traffic by 2035. Has shown to be very adequate for dealing with such growth, for instance by enabling distributed approaches for collision avoidance [2]. This increase on the number of drones in the airspace worldwide attracts people who can misuse the UAVs. Under the latest drone regulation it is stated. Sensors 2020, 20, 2320 that drones should not enter restricted zones, such as airports, but there is no clear countering drone solutions yet. In 2018, a drone caused a huge problem in Gatwick London Airport. The number of drones will increase and it is obvious that they can cause more serious problems. The threat is coming and counter measurements should be taken
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