A fishing system includes an unmanned aerial vehicle and a fishing line fixing portion placed on a main body of the unmanned aerial vehicle, the fishing line fixing portion including a first fixing portion for fixing a fishing line and a second fixing portion detachably connected to the first fixing portion. The unmanned aerial vehicle includes an imaging device, a fish school tracking processing unit configured to identify a fish in imaging data captured by the imaging device and control the unmanned aerial vehicle to track the fish. A connection between the first fixing portion and the second fixing portion is released when the fish is hooked on an artificial bait attached to a first end of the fishing line.

The present invention relates to an unmanned aerial tree harvesting system comprising a remotely and/or autonomously controlled UAV, an autonomously and/or remotely controlled tree harvesting tool configured for holding and/or delimbing and/or cutting at least a portion of a tree trunk attached underneath the UAV via at least one cord, a means configured for detecting rotational motion and/or pendulum motion of the tree harvesting tool, means attached to the UAV configured for detecting trees from above, at least one remotely and/or autonomously controlled forcing means, attached to the tree harvesting tool, configured for at least damping detected pendulum motion of the tree harvesting tool.

The present invention relates to an unmanned aerial tree harvesting system comprising a remotely and/or autonomously controlled UAV, an autonomously and/or remotely controlled tree harvesting tool configured for holding and/or delimbing and/or cutting at least a portion of a tree trunk attached underneath the UAV via at least one cord, a means configured for detecting rotational motion and/or pendulum motion of the tree harvesting tool, means attached to the UAV configured for detecting trees from above, at least one remotely and/or autonomously controlled forcing means, attached to the tree harvesting tool, configured for at least damping detected pendulum motion of the tree harvesting tool.

An imaging system can include a first and second camera configured to capture first and second sets of oblique images along first and second scan paths, respectively, on an object area. A drive is coupled to a scanning mirror structure, having at least one mirror surface, and configured to rotate the structure about a scan axis based on a scan angle. The first and second cameras each have an optical axis set at an oblique angle to the scan axis and include a respective lens to focus first and second imaging beams reflected from the mirror surface to an image sensor located in each of the cameras. The first and second imaging beams captured by their respective cameras can vary according to the scan angle. Each of the image sensors captures respective sets of oblique images by sampling the imaging beams at first and second values of the scan angle.

Systems, computer readable medium and methods for autonomous drone stabilization and navigation are disclosed. Example methods include capturing an image using an image capturing device of the autonomous drone, processing the image to identify an object, and navigating the autonomous drone relative to the object to one or more waypoints. The autonomous drone navigates initially based on a relative location of the autonomous drone from the object. The autonomous drone determines a distance from the object based on an estimated size of the object and a number of pixels of an image sensor the object occupies. The autonomous drone determines a height above a ground to assist in navigation. Additionally, the autonomous drone hovers to determine a windspeed.

Systems, computer readable medium and methods for autonomous drone stabilization and navigation are disclosed. Example methods include capturing an image using an image capturing device of the autonomous drone, processing the image to identify an object, and navigating the autonomous drone relative to the object to one or more waypoints. The autonomous drone navigates initially based on a relative location of the autonomous drone from the object. The autonomous drone determines a distance from the object based on an estimated size of the object and a number of pixels of an image sensor the object occupies. The autonomous drone determines a height above a ground to assist in navigation. Additionally, the autonomous drone hovers to determine a windspeed.

A method and a system monitor a movable object in an elevator shaft by an unmanned aerial vehicle (UAV). The UAV is positioned into a wanted location within the elevator shaft, in which the movable object to be monitored is within view of an imaging sensor of the UAV, and movement of the UAV is automatically synchronized with the movement of the movable object based on UAV's on position and movement characteristics and received status data. Imaging sensor of the UAV obtains image data of the movable object during operation of the elevator and image data is stored and/or sent wirelessly.

A method and a system monitor a movable object in an elevator shaft by an unmanned aerial vehicle (UAV). The UAV is positioned into a wanted location within the elevator shaft, in which the movable object to be monitored is within view of an imaging sensor of the UAV, and movement of the UAV is automatically synchronized with the movement of the movable object based on UAV's on position and movement characteristics and received status data. Imaging sensor of the UAV obtains image data of the movable object during operation of the elevator and image data is stored and/or sent wirelessly.

The unmanned aerial vehicle (UAV) tethered with an optical fiber is an unmanned aerial vehicle, drone or the like carrying an optical device which is tethered to an external light source. The light source may be a ground-based laser. The optical device is connected to, and optically coupled with, the light source by a tether including at least one optical fiber. A stabilizer may be mounted on the optical device for stabilizing orientation and direction thereof. The optical device may include at least one collimator and at least one focusing lens for shaping and focusing the received light for output to a selected target.

The unmanned aerial vehicle (UAV) tethered with an optical fiber is an unmanned aerial vehicle, drone or the like carrying an optical device which is tethered to an external light source. The light source may be a ground-based laser. The optical device is connected to, and optically coupled with, the light source by a tether including at least one optical fiber. A stabilizer may be mounted on the optical device for stabilizing orientation and direction thereof. The optical device may include at least one collimator and at least one focusing lens for shaping and focusing the received light for output to a selected target.