Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

A quadrotor is proposed than can both fly and roll. The proposed robot employs passively reconfigurable structures to enable the rolling, tightly coupling the attitude of the robot to the rolling cage. The benefits are precise rolling and turning control as well as improved rolling efficiency. The passively reconfigurable structures are enabled by pre-stretched elastic springs to generate a nonlinear restoring torque. The robot leveraged the superior maneuverability in the rolling mode to take photos of the surroundings at different tilting and panning angles to construct a panoramic image. Besides, the results of the power measurements show a significant reduction in the cost of transport brought by at low speed, equating to a 15-fold extension in the operational range.

A remote health care apparatus is disclosed that incorporates a drone device and a health kit. The drone device includes one or more communication devices, and the drone device is capable of two-way auditory and visual communication. The health kit is capable of being transported by the drone device and can be detached from the drone device. In one embodiment, the health kit contains one or more medical devices selected from the group consisting of biometric measuring devices, specimen collection devices and lab testing tools.

Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Disclosed are devices, systems and methods for mission-adaptable aerial vehicle. In some aspects, a mission-adaptable aerial vehicle includes a configuration having swappable, manipulatable, and interchangeable sections and components connectable by a connection and fastening system able to be modified by an end-user in the field. In some embodiments, a mission-adaptable aerial vehicle can be configured to include a main center body extending along a longitudinal direction, a wing with a lateral cross-sectional airfoil shape, and/or stabilizer and control surface structures with corresponding cross-sectional airfoil shapes.

Systems, methods, and device include a vehicle for providing horizontal directional control in a first transportation mode and a second transportation mode. The vehicle is an unmanned aerial vehicle with the duct defining a ducted air pathway with a central axis. One or more propellor(s) are arranged to move air through the ducted air pathway. One or more flap(s) are movable between multiple positions that vary a distance between ends of the flap(s) and the central axis. The first transportation mode includes three-dimensional control by the propellor(s) and flap(s), and the second transportation mode includes two-dimensional control with the control by the propellor(s) and flap(s). The three-dimensional control includes a first flap position that corresponds to a forward direction and the two-dimensional control includes a second flap position that corresponds to the forward direction, the second flap position being an opposite position relative to the first flap position.

A flying robot includes a body portion, a propulsion portion including a plurality of propulsion units configured to generate propulsion force by driving rotor blades, the plurality of propulsion units being provided at the body portion, a plurality of leg portions configured to support the body portion, each leg portion of the plurality of leg portions including at least one joint and being configured to be able to change a posture of the leg portion, and a controller configured to control the plurality of leg portions when landing on a landing surface from a flying state, and the controller controls part or all of at least one leg portion among the plurality of leg portions to adjust a tilt of the body portion from when the at least one leg portion comes into contact with the landing surface until when landing on the landing surface is completed.

A flying robot includes a body portion, a propulsion portion including a plurality of propulsion units configured to generate propulsion force by driving rotor blades, the plurality of propulsion units being provided at the body portion, a plurality of leg portions configured to support the body portion, each leg portion of the plurality of leg portions including at least one joint and being configured to be able to change a posture of the leg portion, and a controller configured to control the plurality of leg portions when landing on a landing surface from a flying state, and the controller controls part or all of at least one leg portion among the plurality of leg portions to adjust a tilt of the body portion from when the at least one leg portion comes into contact with the landing surface until when landing on the landing surface is completed.

A modular and reconfigurable aircraft including a first aircraft module, a second aircraft module, a plurality of connectors, and a coupler. The first aircraft module can include a polyhedral cage structure, a propeller disposed in an interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. The second aircraft module can include a polyhedral cage structure, a propeller disposed in the interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. A plurality of connectors can be configured to couple the polyhedral cage structure of the first aircraft module to the polyhedral cage structure of the second aircraft module. A coupler can be configured to attach a payload to the polyhedral cage structure of the first aircraft module.

A modular and reconfigurable aircraft including a first aircraft module, a second aircraft module, a plurality of connectors, and a coupler. The first aircraft module can include a polyhedral cage structure, a propeller disposed in an interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. The second aircraft module can include a polyhedral cage structure, a propeller disposed in the interior of the polyhedral cage structure, and a motor disposed in the interior of the polyhedral cage structure and configured to drive the propeller. A plurality of connectors can be configured to couple the polyhedral cage structure of the first aircraft module to the polyhedral cage structure of the second aircraft module. A coupler can be configured to attach a payload to the polyhedral cage structure of the first aircraft module.