The present disclosure relates to a detection method and system for an underground space by joint use of fixed sensors and unmanned aerial vehicle (UAV) movement detection. The detection system includes underground space sensor nodes and an underground space UAV. The underground space sensor nodes are configured to perform fixed monitoring based on an adaptive optimal layout strategy for an underground structural space. The underground space UAV is configured to calculate a first virtual force, and realize movement detection by means of a virtual force-guided path planning algorithm. The underground space UAV is configured to calculate the first virtual force based on the electronic telescopic anti-collision bars, a second virtual force based on a static perception probability and a third virtual force based on structural evolution knowledge, and realize a fixed node-guided UAV flight detection mode by means of the virtual force-guided path planning algorithm.

A rover device for sanitizing spacecraft that emits germicidal ultraviolet light with means for sensing and directing rover location, orientation, velocity, trajectory and path is disclosed. Rather, the disclosed embodiment is a rover that uses propellers more in the fashion of a thruster on a satellite which uses short bursts to control satellite position in three translational planes and three rotational axes. Unlike a thruster, the propeller can be reversed, allowing motion in either direction.

A rotorcraft including a fuselage, one or more motor-driven rotors for vertical flight, and a control system. The motors drive the one or more rotors in either of two directions of rotation to provide for flight in either an upright or an inverted orientation. An orientation sensor is used to control the primary direction of thrust, and operational instructions and gathered information are automatically adapted based on the orientation of the fuselage with respect to gravity. The rotors are configured with blades that invert to conform to the direction of rotation.

Systems and methods for deterring avian species from approaching a sensitive area. A determination is made that a bird is approaching a sensitive area. A predefined flight path is selected from a plurality of predefined flight paths based on the determination that the bird is approaching the sensitive area. Each of the predefined flight paths of the plurality of predefined flight paths is configured to avoid objects within the sensitive area. An unmanned aerial vehicle is instructed to traverse the predefined flight path that has been selected.

The invention relates to a drone, having at least one central body, at least one thrust element, at least one jointed leg, wherein the at least one jointed leg has leg parts which are connected via joints, wherein the at least one jointed leg is connected in an articulated manner via a proximal end to the central body. It is provided according to the invention that a distal end of at least one jointed leg has an exchangeable chuck, via which the distal end of the jointed leg can be connected to a selection of sensor devices and/or gripping devices and/or tools.

An inactivation device inactivates microorganisms and/or viruses present in a space where a person is present by irradiating the space with ultraviolet light. The inactivation device includes a mobile body movable in the space, a drive section that drives the mobile body, an ultraviolet light irradiation unit provided with an ultraviolet light source emitting light including ultraviolet light having a wavelength that inactivates microorganisms and/or viruses, and a controller that controls the irradiation of the light from the ultraviolet light source. The ultraviolet light source is either an excimer lamp or an LED, and the ultraviolet light included in the light emitted from the ultraviolet light source includes ultraviolet light having a wavelength range from 200 nm to 240 nm. The ultraviolet light irradiation unit is fixed to the mobile body.

A speaker system includes a first speaker and a second speaker. The first speaker includes a first sound signal input interface configured to acquire a first sound signal, and a first sound emitter configured to output a first sound based on the first sound signal in a state in which a position of a host device is fixed. The second speaker includes a second sound signal input interface configured to acquire a second sound signal, a moving body that includes a position information acquisition interface configured to acquire information relating to position and that is configured to move based on the information relating to position, and a second sound emitter configured to output a second sound based on the second sound signal.

In one general aspect, a drone control device includes a body, a motor that is configured to move the body, a network module, an input module, and a processor. The network module is configured to communicate with a security system that monitors a property and receive data associated with a location within the property. The input module is configured to receive user input. The processor is configured to perform operations that include: determine, from among the location within the property and other locations within the property, a target location within the property; move the body to the target location within the property by providing a signal to the motor; receive, from the input module, input data that is associated with an operation of the security system; and in response to receiving the input data, perform the operation of the security system.

An unmanned aerial vehicle (UAV) system is disclosed. The UAV system includes a chassis, a plurality of propeller assemblies configured to provide vertical take-off and landing (VTOL) for the chassis with propulsion in 6 degrees of freedom including along a cartesian coordinate system (X, Y, Z) and provide yaw, pitch, and roll, the plurality of propeller assemblies are selected from the group consisting of (i) two fixed propeller assemblies and a tiltable propeller assembly, and (ii) four fixed propeller assemblies, a boom having a boom propeller assembly, configured to selectively provide positive and negative rectilinear thrust vectors, and an end-effector coupled to a distal end of the boom, the end-effector having a force sensor configured to provide contact force between the end-effector and an object.

The delivery of goods to a customer comprises a substantial portion of human activity. To correct address errors and/or to more precisely locate delivery locations, systems are provided to assist human, human operated vehicle, or autonomous vehicles to locate a delivery point. Often the location of a delivery point is inaccurate or imprecise. GPS and other coordinate systems often fail or are imprecise without an unobstructed view of the sky. Even with coordinates available, the delivery point may be different from the coordinates or, more commonly, coordinates that are different from some standard point within a postal address associated with the coordinates. Providing a delivery system that utilizes a broadcasted identifier, such as an identifier associated with the order of the item, the delivery of the item may be made proximate to the source of the broadcasted identifier or further refined using the broadcasted identifier as a reference.