A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

The disclosed inventions include personal Unmanned Aerial Vehicles (UAV's) and UAV universal docking ports docking ports to be incorporated into and/or attached to headwear, including helmets, hard hats and hats and face masks, as well as footwear including boots and shoes, clothing and outerwear, devices, gear and equipment, land, air, water and space vehicles, buildings, wireless towers and other mobile or stationary objects and surfaces referred to collectively as docking stations. A docking station may have one or more docking ports for docking, networking and charging or refueling compact personal UAVs, and for providing data communications between said UAVs and other electronic devices that remain with the person while the UAV is in flight or driving or landed on terrain. Said docking ports may also incorporate wireless power transmission for remote wireless charging of one or more UAV's. Supplemental power for recharging said UAVs when docked may be supplied by integrated battery(s) in said docking port or me be provided directly from the docking station or other connected power source.

A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

The present disclosure relates to a method for fixing a flight vehicle during transportation and a MaaS providing method. A method for fixing a battery-driven flight vehicle during transportation that includes fixing the flight vehicle by connecting a predetermined portion of the flight vehicle and a moving body by a wire.

The present disclosure relates to a method for fixing a flight vehicle during transportation and a MaaS providing method. A method for fixing a battery-driven flight vehicle during transportation that includes fixing the flight vehicle by connecting a predetermined portion of the flight vehicle and a moving body by a wire.

Methods, apparatus, systems, and articles of manufacture for unmanned vehicle assistance for submerged host vehicles are disclosed. An example apparatus includes at least one memory, machine readable instructions, and processor circuitry to at least one of instantiate or execute the machine readable instructions to determine an occurrence of a reduced operational capability of a vehicle, the vehicle at least partially submerged in a body of water, cause an unmanned vehicle (UV) to separate from the vehicle in response to the occurrence of the reduced operational capability, and determine positional information corresponding to the UV based on the UV reaching or departing a surface of the body of the water.

Methods, apparatus, systems, and articles of manufacture for unmanned vehicle assistance for submerged host vehicles are disclosed. An example apparatus includes at least one memory, machine readable instructions, and processor circuitry to at least one of instantiate or execute the machine readable instructions to determine an occurrence of a reduced operational capability of a vehicle, the vehicle at least partially submerged in a body of water, cause an unmanned vehicle (UV) to separate from the vehicle in response to the occurrence of the reduced operational capability, and determine positional information corresponding to the UV based on the UV reaching or departing a surface of the body of the water.

A remote modular data collection system and method are disclosed, which in one or more embodiments, employs a plurality of data collection pods, which are interspersed within a geographical region and in communication with a remote control station. The pods include a variety of sensors adapted for particular purposes and may be arranged to preprocess data using artificial intelligence prior to transfer to the remote station and for autonomous operation. The pods are mountable on poles and other structures. In some embodiments, the pods are modular in design and construction, allowing quick installation and replacement of optional modules to satisfy particular data collection purposes. The pods may include integrated solar panels for flexible or redundant power purposes. In some embodiments, one or more pods each house an unmanned aerial vehicle, the sensors of which are integrated into the system and which allow for comprehensive on-demand data collection throughout the entirety of the geographical area. These pods include a hangar bay with a selectively retractable opening and charging pad for launching, recovery, storage, and charging of the unmanned aerial vehicle. The system may be used for terrestrial and/or extraterrestrial purposes, and it has particular application in security, military, environmental, law enforcement, and search and rescue operations, as well as an early detection and warning system.