A paradrone includes a canopy having a parafoil, a transverse canopy frame coupled to the parafoil to support the parafoil, a longitudinal canopy frame that is coupled to the parafoil while having a bent structure such that the parafoil generates a lift, and at least one parafoil connecting portion for connecting at least one canopy frame among the transverse canopy frame and the longitudinal canopy frame to the parafoil. The paradrone also includes a servomotor portion having a servomotor body and a servomotor arm for coupling and fixing intersecting parts of the transverse canopy frame and the longitudinal canopy frame. The servomotor arm is connected to a servomotor body and rotated in a predetermined direction by driving of the servomotor body to change the angle between the travelling direction of the paradrone fuselage and the transverse and longitudinal canopy frames, thereby changing the angle of attack.

A paradrone includes a canopy having a parafoil, a transverse canopy frame coupled to the parafoil to support the parafoil, a longitudinal canopy frame that is coupled to the parafoil while having a bent structure such that the parafoil generates a lift, and at least one parafoil connecting portion for connecting at least one canopy frame among the transverse canopy frame and the longitudinal canopy frame to the parafoil. The paradrone also includes a servomotor portion having a servomotor body and a servomotor arm for coupling and fixing intersecting parts of the transverse canopy frame and the longitudinal canopy frame. The servomotor arm is connected to a servomotor body and rotated in a predetermined direction by driving of the servomotor body to change the angle between the travelling direction of the paradrone fuselage and the transverse and longitudinal canopy frames, thereby changing the angle of attack.

To improve safety during a fall of a flying apparatus, a flying apparatus (1) according to a representative embodiment of the present application includes a body unit (2), a lift-force generating part (3) that is connected to the body unit and generates a lift force, a flight control part (14) that controls the lift-force generating part, an abnormality detecting part (15) that detects an abnormality during flight, a parachute device (4) including a parachute (41, 41A) and a parachute accommodating part (42) that accommodates the parachute, and a fall control part (16) that ejects the parachute from the parachute accommodating part according to the detection of the abnormality by the abnormality detecting part.

To improve safety during a fall of a flying apparatus, a flying apparatus (1) according to a representative embodiment of the present application includes a body unit (2), a lift-force generating part (3) that is connected to the body unit and generates a lift force, a flight control part (14) that controls the lift-force generating part, an abnormality detecting part (15) that detects an abnormality during flight, a parachute device (4) including a parachute (41, 41A) and a parachute accommodating part (42) that accommodates the parachute, and a fall control part (16) that ejects the parachute from the parachute accommodating part according to the detection of the abnormality by the abnormality detecting part.

An apparatus, including a database which stores a travel itinerary or schedule of an individual; a processor; a global positioning system device; and a transmitter. The processor monitors a movement of the individual, compares information obtained by the global positioning system device with information contained in the travel itinerary or schedule, detects a deviation from an expected position, location, or travel route, and generates a message containing information regarding a date and time of the deviation and position or location information of the apparatus. The transmitter or apparatus transmits the message or information contained in the message to a drone. An operation of the drone is activated, the drone travels to the position or location of the apparatus, records video information of the apparatus or individual or of an area in a vicinity of the apparatus or individual, and transmits the video information to the user device or the computer.

An apparatus, including a database which stores a travel itinerary or schedule of an individual; a processor; a global positioning system device; and a transmitter. The processor monitors a movement of the individual, compares information obtained by the global positioning system device with information contained in the travel itinerary or schedule, detects a deviation from an expected position, location, or travel route, and generates a message containing information regarding a date and time of the deviation and position or location information of the apparatus. The transmitter or apparatus transmits the message or information contained in the message to a drone. An operation of the drone is activated, the drone travels to the position or location of the apparatus, records video information of the apparatus or individual or of an area in a vicinity of the apparatus or individual, and transmits the video information to the user device or the computer.

An electronic parachute deployment system includes an electronic actuator, a control module, a deployment actuator, and a release mechanism. A parachute is positioned on a payload device, such as a racecar, to slow or stop the payload upon receipt of an electronic deployment activation signal. The electronic deployment signal is verified, including determining proper voltage and source. The deployment system includes multiple redundancies including mechanical deployment redundancy, remote deployment redundancy, and power supply redundancy. The control module responsible for monitoring deployment includes indicators and sensors to indicate a status, operation, or mode relative to the operability of the payload device, relative to components of the release mechanism, and relative to the parachute deployment.

Systems and methods to cut a closing loop to deploy a parachute. The system includes a cutter with a body with a cutter opening that extends through the body and a blade that is movable across the cutter opening. Processing circuitry is configured to signal the cutter to move the blade across the cutter opening. A mount includes a base, a retainer with a channel sized to receive the cutter, and a mount opening that extends through the mount and across the channel. The cutter is configured to fit within the channel with the cutter opening aligned with the mount opening to form a through-opening such that the closing loop extends through the cutter and the mount.

Systems and methods to cut a closing loop to deploy a parachute. The system includes a cutter with a body with a cutter opening that extends through the body and a blade that is movable across the cutter opening. Processing circuitry is configured to signal the cutter to move the blade across the cutter opening. A mount includes a base, a retainer with a channel sized to receive the cutter, and a mount opening that extends through the mount and across the channel. The cutter is configured to fit within the channel with the cutter opening aligned with the mount opening to form a through-opening such that the closing loop extends through the cutter and the mount.

Systems, devices, and methods including: a latching mechanism comprising: a first latch configured to attach to a door of an unmanned aerial vehicle (UAV); a second latch configured to attach to a portion of the UAV distal from the first latch; a string connected between the first and second latch, where the string secures the door shut; at least two radio modules in communication with a ground control station; and at least two burn wires in contact with a portion of the string between the first latch and the second latch; where current from a backup battery passes to at least one burn wire when the burn signal is received, where the burn wire causes the connection between the first latch and the second latch to be broken and the door of the UAV is separated from the UAV, and where the parachute is deployed when the door of the UAV is separated from a rest of the UAV.