A service providing system includes a request receiving robot and a service providing robot. The request receiving robot includes a floating unit configured to float in air, a recognition unit configured to recognize a service providing request by a user, and a transmitter configured to transmit the recognized service providing request. The service providing robot includes a receiver configured to receive the service providing request transmitted by the request receiving robot, a moving unit configured to move the service providing robot to the user who makes the service providing request as a destination according to the received service providing request, and a service providing unit configured to provide a service to the user.

Systems and methods for providing UAV-based digital escort drones in visitor management and access control systems are provided. A visitor management and access control system can identify a need for escorting a visitor through a region and transmit a signal to a drone that identifies a starting location and a destination location in the region. Responsive to receiving the signal, the drone can escort the visitor along a path from the starting location to the destination location, and an access privilege device carried by the drone can open a secured door or access a secured area along the path.

An unmanned autonomous vehicle (aerial or ground) assessment and reporting system may conduct micro scans of interior portions of a structure, such as walls, windows, doorways, stairs, and the like. Scan data from one or more sensor types may be compared with stored profile data from a library of profiles using computer vision or other matching techniques to identify characteristics, defects, damage, construction materials, etc. An adaptive response system may modify the types of sensors used for scanning and/or the scanning pattern itself based on matched profile data. Modifications to the scanning process are implemented in real-time based on identified characteristics of the interior portions of the structure.

Indoor mapping and modular control for UAVs and other autonomous vehicles, and associated systems and methods. A representative unmanned aerial vehicle system includes a body, a propulsion system carried by the body, a sensor system carried by the body, and a controller carried at least in part by the body and operatively coupled to the propulsion system and the sensor system. The controller is programmed with instructions that, when executed, operate in a first autonomous mode and a second autonomous mode. In the first autonomous mode, the instructions autonomously direct the propulsion system to convey the body along a first route within an indoor environment. While the body travels along the first route, the instructions receive inputs from the sensor system corresponding to features of the indoor environment. The features are stored as part of a 3-D map. In the second autonomous mode, the instructions direct the propulsion system to convey the body along a second route within the indoor environment, based at least in part on the 3-D map, and direct performance of an operation on the second route.

A drone docking station for an aerial drone is provided. The drone docking station includes a platform and a drone positioning device. The platform includes a drone landing area. The drone positioning device is disposed on the platform. The drone positioning device includes a sidewall disposed around the drone landing area and a flange extending from the sidewall. The flange includes a first end coupled to the sidewall and a second end distal thereto. The flange extends from the sidewall at a first angle. Methods for securing the drone docking station to a warehouse rack are also provided.

This disclosure is generally directed to an Unmanned Aerial Device (UAV) that uses a removable computing device for command and control. The UAV may include an airframe with rotors and an adjustable cradle to attach a computing device. The computing device, such as a smart phone, tablet, MP3 player, or the like, may provide the necessary avionics and computing equipment to control the UAV autonomously. For example, the adjustable cradle may be extended to fit a tablet or other large computing device, or retracted to fit a smart phone or other small computing device. Thus, the adjustable cradle may provide for the attachment and use of a plurality of different computing devices in conjunction with a single airframe. Additionally the UAV may comprise adjustable arms to assist in balancing the load of the different computing devices and/or additional equipment attached to the airframe.

An unmanned aerial vehicle (UAV) assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine tune each subsequent scan. The system may include shadow elimination, annotation, and/or reduction for the UAV itself and/or other objects. A UAV may be used to determine a pitch of roof of a structure. The pitch of the roof may be used to fine tune subsequent scanning and data capture to capture perpendicular images of target field of views and/or target distances.

An unmanned aerial vehicle (UAV) assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine tune each subsequent scan. The system may include shadow elimination, annotation, and/or reduction for the UAV itself and/or other objects. A UAV may be used to determine a pitch of roof of a structure. The pitch of the roof may be used to fine tune subsequent scanning and data capture to capture perpendicular images of target field of views and/or target distances.

Aspects of the subject disclosure may include, for example, wirelessly receiving first control signals that are received directly from a remote control device according to user input at the remote control device, adjusting a flight of the unmanned aircraft according to the first control signals, wirelessly receiving second control signals that are received from a network device where the second control signals are not sourced by the remote control device, and adjusting the flight of the unmanned aircraft according to the second control signals. Other embodiments are disclosed.

An unmanned aerial vehicle (UAV) assessment and reporting system may utilize one or more scanning techniques to provide useful assessments and/or reports for structures and other objects. The scanning techniques may be performed in sequence and optionally used to further fine tune each subsequent scan. The system may include shadow elimination, annotation, and/or reduction for the UAV itself and/or other objects. A UAV may be used to determine a pitch of roof of a structure. The pitch of the roof may be used to fine tune subsequent scanning and data capture.