Methods, systems and related graphical user interface displays are provided for assisting operation of a vehicle in a vicinity of a docking location. A docking graphical user interface display includes lateral deviation markers, vertical deviation markers, a first graphical indication with respect to the lateral deviation markers and a second graphical indication with respect to the vertical deviation markers. A position of the first graphical indication with respect to the lateral deviation markers corresponds to a first difference between the current location of the vehicle and the reference stopping location in a lateral direction, and a second position of the second graphical indication with respect to the vertical deviation markers corresponds to a second difference between the current location of the vehicle and the reference stopping location in a longitudinal direction.

Methods, systems and related graphical user interface displays are provided for assisting operation of a vehicle in a vicinity of a docking location. A docking graphical user interface display includes lateral deviation markers, vertical deviation markers, a first graphical indication with respect to the lateral deviation markers and a second graphical indication with respect to the vertical deviation markers. A position of the first graphical indication with respect to the lateral deviation markers corresponds to a first difference between the current location of the vehicle and the reference stopping location in a lateral direction, and a second position of the second graphical indication with respect to the vertical deviation markers corresponds to a second difference between the current location of the vehicle and the reference stopping location in a longitudinal direction.

A system including at least one image acquisition module to acquire images of the environment of the aircraft and of the runway, a module to recognize in the images at least one element representative of at least one contaminant likely to influence the state of the runway, a module to determine at least one property of the contaminant or contaminants and a module to transmit to a user device the property or properties of the contaminant or contaminants. The system allows contaminants to be identified and to be located on the runway or in the environment of the aircraft.

A human-machine interface for displaying an intuitive and accurate graphic representation for assisting in take-off or landing, based on a fully autonomous system essentially using only images captured by embedded cameras and data from avionics systems of the aircraft, the graphic representation including indicators based on a processing of a stream of images taken by embedded cameras and comprising a representation of a runway straight line indicative of the central longitudinal axis of the runway and of at least one deviation indicator representative of the difference between the longitudinal axis of the aircraft and the central longitudinal axis of the runway.

An unmanned aerial vehicle (UAV) expandable landing marker system may include a an expandable volume. The landing marker may be expanded prior to arrival of a UAV delivering an item to be received by the landing marker. The landing marker may be expanded by regulating an amount of fluid in the volume. An anchor may be coupled to the landing marker to restrain movement of the expanded landing marker. An optional retraction mechanism may retract the landing marker. The landing marker can be retracted with the deposited item, moving the item to a location for later retrieval.

An unmanned aerial vehicle (UAV) expandable landing marker system may include a an expandable volume. The landing marker may be expanded prior to arrival of a UAV delivering an item to be received by the landing marker. The landing marker may be expanded by regulating an amount of fluid in the volume. An anchor may be coupled to the landing marker to restrain movement of the expanded landing marker. An optional retraction mechanism may retract the landing marker. The landing marker can be retracted with the deposited item, moving the item to a location for later retrieval.

Systems and methods describe providing field data collection using unmanned aerial vehicles (UAVs). The system receives a request, from a client device, to perform an aerial mission. The system selects a launch hangar, from a group of launch hangars that are in networked communication, to launch a UAV to perform the aerial mission. The system transmits to the UAV from the selected launch hangar, instructions to perform the aerial mission. The system deploys from the selected launch hangar, the UAV to perform the aerial mission and obtain sensor data pertaining to a structure and/or a geographic area. The system receives the UAV at a return hangar which receives the obtained sensor data from the UAV.

Systems and methods describe providing field data collection using unmanned aerial vehicles (UAVs). The system receives a request, from a client device, to perform an aerial mission. The system selects a launch hangar, from a group of launch hangars that are in networked communication, to launch a UAV to perform the aerial mission. The system transmits to the UAV from the selected launch hangar, instructions to perform the aerial mission. The system deploys from the selected launch hangar, the UAV to perform the aerial mission and obtain sensor data pertaining to a structure and/or a geographic area. The system receives the UAV at a return hangar which receives the obtained sensor data from the UAV.

Unmanned aerial vehicle (UAV) navigation systems include a UAV charging pad positioned at a storage facility, a plurality of fiducial markers positioned at the storage facility, and a UAV. Each of the fiducial markers is associated with a fiducial dataset storing a position of the corresponding fiducial marker, and the fiducial datasets are stored in a fiducial map. The UAV includes a camera and logic that when executed causes the UAV to image a first fiducial marker, to access from the fiducial map a first fiducial dataset storing the position of the first fiducial marker, and to navigate based upon the first fiducial dataset.

A display system of an aircraft, able to display a localization marking of a zone of location of an approach light ramp and related method are provided. The display system includes a display unit and an assembly generating a display on the display unit. The display generator is able to display, on approach to a landing strip, a localization marking of a presence zone of an approach light ramp toward the landing strip.