An automated system for mitigating risk from a wind turbine includes a plurality of optical imaging sensors. A controller receives and analyzes images from the optical imaging sensors to automatically send a signal to curtail operation of the wind turbine to a predetermined risk mitigating level when the controller determines from images received from the optical imaging sensors that an airborne animal is at risk from the wind turbine.

An automated system for mitigating risk from a wind turbine includes a plurality of optical imaging sensors. A controller receives and analyzes images from the optical imaging sensors to automatically send a signal to curtail operation of the wind turbine to a predetermined risk mitigating level when the controller determines from images received from the optical imaging sensors that an airborne animal is at risk from the wind turbine.

An automated system for mitigating risk from a wind farm. The automated system may include an array of a plurality of image capturing devices independently mounted in a wind farm. The array may include a plurality of low resolution cameras and at least one high resolution camera. The plurality of low resolution cameras may be interconnected and may detect a spherical field surrounding the wind farm. A server is in communication with the array of image capturing devices. The server may automatically analyze images to classify an airborne object captured by the array of image capturing devices in response to receiving the images.

An automated system for mitigating risk from a wind farm. The automated system may include an array of a plurality of image capturing devices independently mounted in a wind farm. The array may include a plurality of low resolution cameras and at least one high resolution camera. The plurality of low resolution cameras may be interconnected and may detect a spherical field surrounding the wind farm. A server is in communication with the array of image capturing devices. The server may automatically analyze images to classify an airborne object captured by the array of image capturing devices in response to receiving the images.

A selectively perceptible wind turbine system provides illumination in a low intensity and wavelength invisible to the human eye, but visible to certain bats. This illumination deters bats and other flying animals from going near the turbine without becoming a nuisance. At least one ultraviolet (UV) illumination source produces at least one UV beam with a wavelength of approximately 200 nm to approximately 400 nm. This UV beam extends between the UV illumination source and at least one turbine blade surface of a turbine blade. Contact between the UV beam and the turbine blade surface forms an illumination interface with a power density of less than 100 W/cm.sup.2.

A selectively perceptible wind turbine system provides illumination in a low intensity and wavelength invisible to the human eye, but visible to certain bats. This illumination deters bats and other flying animals from going near the turbine without becoming a nuisance. At least one ultraviolet (UV) illumination source produces at least one UV beam with a wavelength of approximately 200 nm to approximately 400 nm. This UV beam extends between the UV illumination source and at least one turbine blade surface of a turbine blade. Contact between the UV beam and the turbine blade surface forms an illumination interface with a power density of less than 100 W/cm.sup.2.

A wind turbine ID marker arrangement to enable a wind turbine installation to be identified from the air, the ID marker arrangement comprising a display surface to which a pattern of tiles are removably attached.

A wind turbine ID marker arrangement to enable a wind turbine installation to be identified from the air, the ID marker arrangement comprising a display surface to which a pattern of tiles are removably attached.

A method for determining a rotor orientation of a rotor of a wind turbine, the rotor having a rotor blade, to a method for determining a geographical position of a rotor of a wind turbine, the rotor having a rotor blade, to a wind turbine and to a wind farm. A method for determining a rotor orientation of a rotor of a wind turbine, the rotor having a rotor blade, comprising the steps of: receiving at least two sets of position data of a GNSS receiver arranged in the rotor blade, the two sets of position data representing two different horizontal positions of the GNSS receiver; and ascertaining the rotor orientation of the rotor on the basis of the position data.

The present invention is an aircraft lighting system. In particular, the present invention is directed to an aircraft lighting system with light that is directed toward an aircraft's engines to deter bird strikes. The lighting system for a jet-powered aircraft has at least one light mounted on an aircraft fuselage aimed at an engine inlet of an engine nacelle of the aircraft. The illumination from the light comprises ultraviolet light between 300 and 400 nm in wavelength and the light flashes at a pre-determined frequency preferably between 1 and 3 Hz. Additional lights can be mounted on the engine nacelles to illuminate outer engine nacelles. Preferably, the engine of the aircraft also has blades coated in fluorescent or iridescent paint to increase the reflectivity of the blades to further illuminate the blades of the engine. The lighting system preferably automatically illuminates the engine inlets during take-off and descent.