A handsfree autonomous umbrella assembly for shielding a user from the elements includes an umbrella and a drone module. The umbrella comprises a shaft and a frame, which has a canopy engaged thereto. The frame is engaged to a first end of the shaft and can be selectively positioned in a collapsed configuration and a deployed configuration, wherein the frame has a concave face and a convex face. The shaft extends from the concave face. The drone module is engaged to the shaft and receives commands to selectively provide directional thrust. A control unit transmits commands to the drone module, enabling the drone module to track the control unit. The control unit is positioned to command the drone module to maintain a relative position above a user who possesses the control unit. The canopy thus shields the user from the elements.

The formation of dynamic, micro-climate groups consisting of passive and active weather collecting devices is provided. Such devices may collect weather information in real-time. The collected information may be distributed weather information and or forecasts to individuals in a particular geographical area or to other subscribers.

An intelligent shading umbrella includes a processor, a base assembly, a stem assembly coupled to a base assembly and a central support assembly coupled to a stem assembly, the central support assembly including one or more arm support assemblies. The intelligent shading umbrella further comprises one or more blades, coupled to the arm support assemblies. The intelligent shading umbrella further comprises an infrared receiver, the infrared receiver receiving signals from a remote device and communicating signals to control movement of the intelligent shading umbrella.

An intelligent umbrella includes a wireless communication transceiver to receive commands or messages from a mobile computing device and an integrated computing device, the integrated computing device including one or more memory devices, one or more processors and computer-readable instructions stored in the one or more memory devices. The computer-readable instructions are executable by the one or more processors to receive the commands or messages, via the wireless communication transceiver from the mobile computing device and to generate instructions, signals, commands and/or messages, based, at least in part on the received commands or messages from the mobile computing device. The computer-readable instructions are executable by the one or more processors to communicate the generated instructions, signals, commands or messages to one or more assemblies of the intelligent umbrella to cause the one or more assemblies of the intelligent umbrella to move in a specified manner.

The formation of dynamic, micro-climate groups consisting of passive and active weather collecting devices is provided. Such devices may collect weather information in real-time. The collected information may be distributed weather information and or forecasts to individuals in a particular geographical area or to other subscribers.

An array of wirelessly controllable umbrellas includes at least two umbrellas with receivers and with motors operable to open and close the umbrellas. The receivers are operable to wirelessly receive a code and communicate with the motors to open or close the umbrellas based on an authentication of the code being an authorized code and to deny operation of the umbrella based on receipt of an unauthorized code.

An intelligent shading umbrella comprises a base assembly, an umbrella support assembly coupled to a base assembly, a first memory, a first processor coupled to the first memory, and a computing device, wherein the computing device has a non-volatile memory having computer-readable instructions stored thereon, a second memory, and a second processor. A first processor communicates commands and/or signals to the umbrella support assembly to cause movement of the umbrella support assembly. A second processor, of the computing device, is enclosed within the intelligent shading object fetches computer-readable instructions from the non-volatile memory, loads the computer-readable instructions from the non-volatile memory into the second memory, and executes the computer-readable instructions to communicate with external computing devices and/or to generate commands and/or signals to the first processor to request movements of the umbrella shading assembly.

An intelligent umbrella includes a base assembly, a center support assembly having one or more arm support assemblies, and one or more arms coupled to the one or more arm support assemblies. The center support assembly is a tubular structure to house electrical and mechanical components. The umbrella includes a computing device, the computing device integrated inside the center support assembly. The computing device includes one or more memory devices, one or more processors and computer-readable instructions stored in the one or more memory devices and executable by the one or more processors. The intelligent umbrella includes a shading fabric. The intelligent umbrella includes a camera, the camera to capture images of an area in proximity to the intelligent shading umbrella, the camera integrated inside the center support assembly.

Provided is an automatic umbrella. The middle rod structure comprises an outer sleeve; a movable sleeve; a first elastic element; a locating element; an adjustment element; and a long rod comprising a long rod upper end and a long rod lower end; wherein the long rod upper end is abutted against the adjustment element, and the long rod lower end is located inside the movable sleeve for limiting the first elastic element from moving along a direction perpendicular to the longitudinal direction.

Systems, methods, and computer-readable storage devices for providing directions haptically such that sight and hearing can continue unimpeded. In one exemplary embodiment, a wearable device (such as earphones, ear rings, gloves, glasses, or other wearable objects) configured as disclosed herein receives directions to an intended destination for a user, the directions comprising a movement action and a distance to the movement action. The wearable device has multiple haptic output units and generates, through one of those units, a haptic output based on the directions. This allows the user to receive the directions through touch rather than looking at their mobile device or from audio.