An assistive apparatus for sensing the environment in the vicinity of a user, and provide feedback signals generated based on the sensing data to the user. The assistive apparatus includes a sensing device configured to collect data characterizing the environment, a processing device, including one or more processors, configured to process an input including the collected data into presentation data specifying an audio signal and/or a haptic signal, and a presentation device configured to deliver the audio signal or the haptic signal to the user.

An assistive apparatus for sensing the environment in the vicinity of a user, and provide feedback signals generated based on the sensing data to the user. The assistive apparatus includes a sensing device configured to collect data characterizing the environment, a processing device, including one or more processors, configured to process an input including the collected data into presentation data specifying an audio signal and/or a haptic signal, and a presentation device configured to deliver the audio signal or the haptic signal to the user.

A system for interacting with a remote object comprising a wearable jacket for a user, two actuators for supporting arms of the user, motors for causing movements to at least one of a torso and the arms of the user, and sensors for measuring at least one of a force applied to the user and a position of the user, and a controller and data transmission device for communicating with the remote object.

A method for destroying enemy's targets is disclosed which comprises the following steps: (a) carrying a multicopter drone in a backpack of a first soldier; (b) removing the multicopter drone from the backpack, unfolding, and coupling a missile to the multicopter drone; (c) remote controlling the multicopter drone to search for the enemy' targets using a remote control; and (d) launching the missile from the multicopter drone when the enemy' targets are detected.

A method for destroying enemy's targets is disclosed which comprises the following steps: (a) carrying a multicopter drone in a backpack of a first soldier; (b) removing the multicopter drone from the backpack, unfolding, and coupling a missile to the multicopter drone; (c) remote controlling the multicopter drone to search for the enemy' targets using a remote control; and (d) launching the missile from the multicopter drone when the enemy' targets are detected.

An unmanned air vehicle (UAV) having a fuselage, a foldable propulsion means to generate thrust leading to the UAV movement, a driving means to drive the propulsion means and a plurality of flight control surfaces actuators are further included. The UAV further includes at least one pair of foldable wings where the rear portion of the wings is pivotally attached to the fuselage. The wings having at least one roll control surface hinged to at least one of the foldable wings. At least a pair of tail stabilizers having ruddervators flight control surfaces hinged to the tail stabilizers. In a fully extended position or in ready to fly state position, each of the foldable wings are deployed perpendicular to one another and perpendicular to the fuselage to form an offset-x shaped wings, and in a stowed position, each of the wings are positioned parallel to one another and positioned parallel to the fuselage.

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, footwear, clothing, 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 UAVs, and for providing data communications between said UAVs and other electronic devices. 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 battery(s) integrated in said docking port or may be provided directly from the docking station or other connected power source.

An aerial vehicle, preferably including: a rotary wing and a protection housing enclosing the rotary wing. An aerial vehicle, preferably including: a first rotary wing module including a first rotary wing and a second rotary wing module including a second rotary wing, wherein the first rotary wing module and the second rotary wing module are preferably operable between a folded configuration and an unfolded configuration. A method of aerial vehicle operation.

Strapping system to enable any ordinary backpack to become a drone carrier.

In some embodiments, an apparatus includes a fuselage of an unmanned aircraft that includes a first section removably coupled to a second section, and a third section removably coupled to the second section such that the second section is disposed between the first section and the third section in a vertical direction. The first section includes a first rotor and a second rotor disposed at a non-zero spaced distance in the vertical direction from each other. The first rotor and the second rotor share a common and aligned rotational axis defined along a longitudinal centerline of the fuselage defined in the vertical direction. The second section is configured to contain a selected payload, and the third section includes a control system. A plurality of legs are coupled to the third section and serve as landing gear for the unmanned aircraft.