Relative position determination method for multiple unmanned aerial, marine and land vehicles

What is claimed is: 1. A relative position determination method performed by a processor for multiple unmanned aerial vehicles based on a camera and direct observation in multiple unmanned aerial vehicle systems and the method comprising the steps of: a. performing a predefined movement in different relative poses by target unmanned aerial vehicle (UAV T ) vehicle; b. collecting data by the observer unmanned aerial vehicle (UAV O ) by recording the trajectory on the image plane corresponding to the observer unmanned aerial vehicle (UAV O ) performing the predefined movement of the target unmanned aerial vehicle (UAV T ) at different relative poses to enable recording of trajectory and actual data for many different relative pose values, by watching target unmanned aerial vehicle (UAV T ) through the camera on itself; c. performing deep learning model training using the collected data, by the observer unmanned aerial vehicle (UAV O ); d. performing a predefined movement of target (collaborator/friend) unmanned aerial (UAV T ); e. taking the image of an observer unmanned aerial vehicle (UAV O ) by means of an image capture unit and checking whether there is a target unmanned aerial vehicle on the image taken; f. determining the bounding box information which is corner point, width and height information, by the observer unmanned aerial vehicle (UAV O ) if the target unmanned aerial vehicle (UAV T ) is detected in the received image; g. returning to step e if the target unmanned aerial vehicle (UAV T ) is not detected in the received image; h. tracking the target using image tracking algorithms using bounding box information, by the observer unmanned aerial vehicle (UAV O ); i. extracting features, by the observer unmanned aerial vehicle (UAV O ), between consecutive points using bounding box information, preferably taking into account the relationships between the position of the center point of the bounding box in the current and previous images; j. calculating the 6-DOF relative position between the observer aerial vehicle (UAV O ) and the target aerial vehicle (UAV T ) by providing the extracted features as input to a deep learning model, by the observer unmanned aerial vehicle (UAV O ); and k. detecting the relative position between the observer aerial vehicle (UAV O ) and the target aerial vehicle (UAV T ).