There is provided a mono-wing aerial device which includes a housing member having disposed thereon electronic components and a power source, including a controller configured to control a thrust unit; a wing member coupled to the housing member, the wing member configured to produce aerodynamic forces for autorotation of the aerial device, the wing member comprising a first edge portion proximal to the housing member and a second edge portion distal to the housing member, wherein the wing member is coupled to the housing member at the first edge portion; and the thrust unit coupled to the wing member at the second edge portion, wherein the thrust unit is configured to generate thrust in a direction substantially tangential to a rotational plane of the wing member. There is also provided a method of forming the mono-wing aerial device.

A method and system for assessing a situation using an unmanned vehicle is disclosed. An unmanned vehicle receives a transmission indicating a situation at a designated location, and then navigates to the designated location. The unmanned vehicle may reach the designated location via air or ground travel, or a combination thereof. The unmanned vehicle receives signals from a first subset of sensors indicating information concerning an environment at the designated location and from a second subset of sensors indicating information concerning one or more objects associated with the situation. The unmanned vehicle then sends one or more transmissions based on the received signals, facilitating rapid determination of the situation.

Various methods for utilizing an unmanned aerial vehicle (UAV) to monitor hazards for a user may include maintaining the UAV at a monitoring position relative to the user, monitoring an area surrounding the user for approaching objects, detecting an approaching object, determining whether the approaching object poses a danger to the user, and performing one or more actions to mitigate the danger of the approaching object in response to determining that the approaching object poses a danger to the user.

The invention relates to a propelled vehicle including: a chassis, a first shaft comprising a crown that is rotationally symmetrical about a first axis and rotatably mounted on the chassis about the first axis of rotation, a first drive system connected to the first shaft and capable of rotating the first shaft about the first axis, which drive system includes a second shaft rotatably mounted on the first shaft about a second axis of rotation orthogonal to the first axis of rotation, the second shaft being supported at two separate points on the first shaft, the points defining the second axis of rotation, and the second shaft supporting at least one propulsion unit of the vehicle, and a second drive system connected to the second shaft and capable of rotating the second shaft about the second axis of rotation.

The invention relates to a propelled vehicle including: a chassis, a first shaft comprising a crown that is rotationally symmetrical about a first axis and rotatably mounted on the chassis about the first axis of rotation, a first drive system connected to the first shaft and capable of rotating the first shaft about the first axis, which drive system includes a second shaft rotatably mounted on the first shaft about a second axis of rotation orthogonal to the first axis of rotation, the second shaft being supported at two separate points on the first shaft, the points defining the second axis of rotation, and the second shaft supporting at least one propulsion unit of the vehicle, and a second drive system connected to the second shaft and capable of rotating the second shaft about the second axis of rotation.

A site management system includes an unmanned airplane being switchable between an airplane mode for high speed flight and a VTOL mode for low speed flight, a working vehicle working in a civil construction site, a shape detection sensor provided in the unmanned airplane to detect a shape of the civil construction site, and an external control apparatus that controls flight of the unmanned airplane, driving of the working vehicle, and driving of the shape detection sensor. The external control apparatus moves the unmanned airplane to an observation area by performing the high speed flight. Further, the external control apparatus detects a shape of the observation area by driving the shape detection sensor while performing the high speed flight or by driving the shape detection sensor while performing low speed flight by switching from the airplane mode to the VTOL mode.

[Object] Provided is a flying device with high safety taking into consideration the influence on a user using the flying device and on surroundings in flight. [Solution] Provided is a flying device including a flying mechanism, and a covering member which is supported by a frame surrounding the flying mechanism and covers at least a portion of the flying mechanism.

An aerial vehicle is programmed or configured to respond to reports of events or conditions within spaces of a facility. The aerial vehicle travels to a location of a reported event or condition and captures data using onboard sensors. The aerial vehicle independently determines whether the reported event or condition is occurring, or is otherwise properly addressed by resources that are available at the location, using images or other data captured by the onboard sensors. Alternatively, the aerial vehicle transmits a request for additional resources to be provided at the location, where necessary. A map of the location generated based on images or other data captured by the onboard sensors may be utilized for any purpose, such as to make one or more recommendations of products that are appropriate for use at the facility.

An aerial vehicle is programmed or configured to respond to reports of events or conditions within spaces of a facility. The aerial vehicle travels to a location of a reported event or condition and captures data using onboard sensors. The aerial vehicle independently determines whether the reported event or condition is occurring, or is otherwise properly addressed by resources that are available at the location, using images or other data captured by the onboard sensors. Alternatively, the aerial vehicle transmits a request for additional resources to be provided at the location, where necessary. A map of the location generated based on images or other data captured by the onboard sensors may be utilized for any purpose, such as to make one or more recommendations of products that are appropriate for use at the facility.

Systems and methods to reduce aerodynamic drag and/or affect flight characteristics of an aerial vehicle may include adjustable fairings associated with one or more components of the aerial vehicle. The adjustable fairings may be coupled to and at least partially surround a motor, propulsion mechanism, motor arm, strut, or other component of an aerial vehicle. In addition, the adjustable fairings may be passively movable between two or more positions responsive to airflow around the fairings, and/or the adjustable fairings may be actively moved between two more positions to affect flight characteristics. Further, the adjustable fairings may include actuatable elements to alter a portion of an outer surface of the fairings to thereby affect flight characteristics. In this manner, adjustable fairings associated with various components of an aerial vehicle may reduce aerodynamic drag and/or may improve control and safety of an aerial vehicle.