Abstract: A main body of an unmanned vehicle is provided. The main body comprises a propulsion-receiving module having a mount point for removably mounting a propulsion source, a payload-receiving module having a mount point for removably mounting a payload, and a damper interposed between the payload-receiving module and the propulsion-receiving module to inhibit transmission of vibrations from the propulsion-receiving module to the payload-receiving module when the payload-receiving module and the propulsion-receiving module are in mechanical communication.

Abstract: Rescue parachute deployment systems (RPDSs) and related techniques are provided to improve the safety and operational flexibility of unmanned aerial vehicles (UAVs). An RPDS includes a canopy assembly, a rotor guard disposed at least partially about the canopy assembly and configured to protect the canopy assembly from rotor strike damage as the canopy assembly is launched through a rotor plane of the UAV, and an ejector assembly configured to deploy the rotor guard into and the canopy assembly through a rotor plane of the UAV. The RPDS may also include a logic device coupled to and/or integrated with the ejector assembly and/or the UAV that is configured to determine a rescue parachute launch condition is active and to control the ejector assembly to deploy the canopy assembly through the rotor plane of the UAV.

Abstract: Techniques for cooling electric motors are disclosed. In one embodiment, a system is provided. The system may include a cooling ring configured to couple to an electric motor of a UAV. The cooling ring may have a circular structure comprising a plurality of air ducts disposed therein. The structure may define an interior cavity. The air ducts may be configured to pass heated air from the interior cavity to an external environment to cool the electric motor. Additional systems and methods are also disclosed.

Abstract: Systems and methods related to landing unmanned aerial vehicles (UAVs) are provided. In one example, a method includes receiving a UAV on a surface of a landing platform. The method may further include operating a positioning device disposed under the surface to locate the UAV. The method may further include operating the positioning device to move the UAV to a location and/or an orientation on the surface. The UAV may comprise landing gear having a plurality of legs, where each leg comprises a shock absorption system. The method may further include operating the shock absorption system during the receiving operation to reduce force received at stress areas of the UAV, and after the receiving operation, operating the shock absorption system to dampen movement by the UAV. Related devices and systems are also provided.

Abstract: Provided herein are systems and methods for an unmanned aerial vehicle (UAV) to skid and roll along an environmental surface. A rollable UAV includes an airframe assembly, a propulsion system, and a logic device configured to communicate with the propulsion system. The airframe assembly includes a cylindrical rolling guard configured to allow the UAV to roll along an environmental surface in contact with the cylindrical rolling guard. The logic device is configured to determine a rolling orientation for the UAV corresponding to the environmental surface, maneuver the UAV to place the cylindrical rolling guard of the airframe assembly in contact with the environmental surface, and roll the airframe assembly of the UAV along the environmental surface at approximately the determined rolling orientation while the cylindrical rolling guard is in contact with the environmental surface.

Abstract: Accessory port systems and methods are provided. In one example, an unmanned aerial vehicle (UAV) includes an accessory port configured to interchangeably attach a plurality of accessory devices to the UAV. The accessory port may have a mechanical interface configured to engage with one of the accessory devices. The mechanical interface may include a locking member configured to physically secure the accessory device to the accessory port. The accessory port may further include an electrical interface configured to electrically connect the accessory device to the UAV. The mechanical interface may be configured to align the accessory device relative to the electrical interface. Related devices, systems, and methods are also provided.

Abstract: Techniques for deicing propellers for mobile platforms are disclosed. In one embodiment, a system is provided. The system may include a propeller comprising a propeller blade having a channel extending from an ingress aperture to an egress aperture along a longitudinal axis of the propeller blade. The system may further include a cowl comprising an air duct configured to direct heated air into the channel to deice the propeller blade. The cowl may be configured to selectively couple to the propeller and an electric motor and form a seal between the cowl and the electric motor to capture the heated air exuded by the electric motor. Additional systems and methods are also disclosed.

Abstract: An airframe assembly for an unmanned aerial vehicle (UAV) is provided where the airframe assembly includes a top airframe assembly, a bottom airframe assembly, and a planar support frame disposed between the top and bottom airframe assemblies. The top and bottom airframe assemblies may form one or more rotor ducts disposed about one or more UAV propulsion motor mounts, respectively, where the rotor ducts are configured to protect rotating rotors disposed therein from physical damage caused by impact with environmental flight hazards. The airframe assembly may further include a heat sink thermally coupled to electronics of the UAV and disposed within the airframe assembly such that rotating blades in the rotor ducts cause air to be drawn from outside of inlet orifices of the top airframe assembly, through an airflow channel in which dissipation surfaces of the heat sink are disposed, and into a rotor duct via an airflow outlet.

Abstract: An unmanned vehicle (UV) is provided. The UV comprises an aircraft component, an interposer component electrically and mechanically coupled to the aircraft component, and a payload component electrically and mechanically coupled to the interposer component. The interposer component comprising a processor and a memory storing instructions which when executed by the processor configured the processor to receive a communication from one of the aircraft component or the payload component, and sent the communication to the other of the aircraft component or the payload component.

Abstract: A main body of an unmanned vehicle is provided. The main body comprises a propulsion-receiving module having a mount point for removably mounting a propulsion source, a payload-receiving module having a mount point for removably mounting a payload, and a damper interposed between the payload-receiving module and the propulsion-receiving module to inhibit transmission of vibrations from the propulsion-receiving module to the payload-receiving module when the payload-receiving module and the propulsion-receiving module are in mechanical communication.

Abstract: A handheld electronic communication device including a body including an input device facing a first direction, and a display device coupled to the body. The display device has a first display screen and a second display screen. The second display screen faces an opposite direction as the first display screen. The display device is rotatable between a first position in which the first display screen faces the first direction, and a second position in which the second display screen faces the first direction.

Abstract: A handheld electronic communication device including a body including an input device facing a first direction, and a display device coupled to the body. The display device has a first display screen and a second display screen. The second display screen faces an opposite direction as the first display screen. The display device is rotatable between a first position in which the first display screen faces the first direction, and a second position in which the second display screen faces the first direction, and releasably lockable in a third position, intermediate the first position and the second position.

Abstract: Electronic device comprising frame and trim. Trim wrapped around at least three sides of the frame. Trim comprising an outer piece and an inner assembly. Outer piece of substantially continuous flexible tactile material comprising a substantially elongate first side portion, a substantially elongate second side portion substantially parallel to the first side portion, and at least one substantially elongate cross portion connecting the first and second side portions. The inner assembly comprising a substantially rigid first side inner piece substantially coextensive with the outer piece first side portion; a substantially rigid second side inner piece substantially coextensive with the outer piece second side portion; and at least one substantially rigid inner cross piece. Each cross piece substantially coextensive with the short dimension of the outer piece cross portion, and shorter than the long dimension of the outer piece cross portion, thereby creating at least one gap in the inner assembly.

Abstract: According to one aspect, a portable electronic device including a first portion having a first surface, a second portion having a second surface, and a slide portion slidably coupled to the first and second portions. The first portion, second portion and slide portion are adapted so that the first portion can slide along a first direction between a closed position wherein the first portion at least partially covers the second surface, and an extended position wherein the second surface is at least partially exposed, and when the first portion is in the extended position, the first portion and slide portion can slide relative to the second portion along a second direction into an open position in which the first surface and the second surface are aligned.

Abstract: An electronic mobile device comprises a base housing and a movable housing movably supported by the base housing. The movable housing includes a user interface device, and the user interface device defines an interface plane, a longitudinal plane substantially perpendicular to the interface plane and bisecting the user interface device, and a transverse plane substantially perpendicular to the interface plane and the longitudinal plane and bisecting the user interface device. The movable housing is operable in a first operating configuration, and the movable housing is translatable relative to the base housing along the longitudinal plane to move to and from a second operating configuration. The movable housing is also pivotable relative to the base housing about a pivot axis to move to and from a third operating configuration. The pivot axis is offset from and substantially parallel to both the longitudinal plane and the transverse plane.

Abstract: A handheld electronic communication device including a body including an input device facing a first direction, and a display device coupled to the body. The display device has a first display screen and a second display screen. The second display screen faces an opposite direction as the first display screen. The display device is rotatable between a first position in which the first display screen faces the first direction, and a second position in which the second display screen faces the first direction, and releasably lockable in a third position, intermediate the first position and the second position.

Abstract: A handheld electronic communication device including a body including an input device facing a first direction, and a display device coupled to the body. The display device has a first display screen and a second display screen. The second display screen faces an opposite direction as the first display screen. The display device is rotatable between a first position in which the first display screen faces the first direction, and a second position in which the second display screen faces the first direction.

Abstract: Electronic device comprising frame and trim. Trim wrapped around at least three sides of the frame. Trim comprising an outer piece and an inner assembly. Outer piece of substantially continuous flexible tactile material comprising a substantially elongate first side portion, a substantially elongate second side portion substantially parallel to the first side portion, and at least one substantially elongate cross portion connecting the first and second side portions. The inner assembly comprising a substantially rigid first side inner piece substantially coextensive with the outer piece first side portion; a substantially rigid second side inner piece substantially coextensive with the outer piece second side portion; and at least one substantially rigid inner cross piece. Each cross piece substantially coextensive with the short dimension of the outer piece cross portion, and shorter than the long dimension of the outer piece cross portion, thereby creating at least one gap in the inner assembly.