A method at a Unmanned Aerial Vehicle (UAV), and a UAV, adapted therefore, is adapted for enabling assisting in a rescue mission, where the method comprise: initiating a first localization of at least one body or object; initiating an analysis, for determining, at least partly based on the first localization of the at least one body or object, a need for activities, and initiating the determined activities, comprising applying floatable foam to an area on or in close proximity to the at least one body or object, while applying, to the floatable foam, a recognizable means capable of assisting in a second localization of the at least one body or object.

A method at a Unmanned Aerial Vehicle (UAV), and a UAV, adapted therefore, is adapted for enabling assisting in a rescue mission, where the method comprise: initiating a first localization of at least one body or object; initiating an analysis, for determining, at least partly based on the first localization of the at least one body or object, a need for activities, and initiating the determined activities, comprising applying floatable foam to an area on or in close proximity to the at least one body or object, while applying, to the floatable foam, a recognizable means capable of assisting in a second localization of the at least one body or object.

A system for dropping a package from an aircraft, a related aircraft and a method are provided. The system includes a panel configured to form part of a skin of the aircraft, the panel defining a through opening emerging outside the aircraft; a removable hatch and a sleeve guiding the hatch through the panel. The guide sleeve defines the through opening. The hatch is configured to be maneuvered in the guide sleeve between a configuration closing the through opening and a configuration allowing the package to pass through the through opening.

A ship distress system that uses a location system associated with the ship and an unmanned aircraft in communication with the location system that continuously receives the location of the ship. The unmanned aircraft can be deployed from a launcher into the direction of potential rescuers so that the unmanned aircraft can provide the location of the ship in distress. The unmanned aircraft is launched in a collapsed position and then unfolds into an extended position after kinetic energy from the launch is lost to maximize the speed and distance that the unmanned aircraft can cover. The unmanned aircraft can includes a camera to search for and identify any third parties that can effect a rescue and is programmed to search for and communicate with a potential rescue vessels or bases after being deployed into the air.

A rescue package is disclosed which is sized for launching from a moving platform such as an aircraft. The platform having a chute adapted to launch a rescue package which in an embodiment uses a container the same size as a container used to house a convention sonobuoy. The rescue package arrangement includes a container body externally sized and shaped to be launched from a moving platform using a launch tube and contains a main parachute located within the container; a drogue chute associated with the container deployed after deployment from the moving platform and connected to the main parachute by a drogue chute tether; a decelerator chute connected to the container and arranged to deploy with or after the drogue chute is deployed, and a delay mechanism arranged to delay deployment of the main parachute for a period of time after the drogue chute is deployed from the container. The container is adapted to contain a payload including at least one of the group of items: inflatable life raft, potable water, long-life food, matches, handheld light sources, handheld beacons, handheld communication devices, cell batteries, rope, water proof sheet material, blankets, sunscreen, hats, insect repellent, containers, utensils, sea-sickness tablets, water bailer, sponges, and wherein the decelerator chute assists the stabilisation of the container during at least a portion of the flight of the container.

A rescue package is disclosed which is sized for launching from a moving platform such as an aircraft. The platform having a chute adapted to launch a rescue package which in an embodiment uses a container the same size as a container used to house a convention sonobuoy. The rescue package arrangement includes a container body externally sized and shaped to be launched from a moving platform using a launch tube and contains a main parachute located within the container; a drogue chute associated with the container deployed after deployment from the moving platform and connected to the main parachute by a drogue chute tether; a decelerator chute connected to the container and arranged to deploy with or after the drogue chute is deployed, and a delay mechanism arranged to delay deployment of the main parachute for a period of time after the drogue chute is deployed from the container. The container is adapted to contain a payload including at least one of the group of items: inflatable life raft, potable water, long-life food, matches, handheld light sources, handheld beacons, handheld communication devices, cell batteries, rope, water proof sheet material, blankets, sunscreen, hats, insect repellent, containers, utensils, sea-sickness tablets, water bailer, sponges, and wherein the decelerator chute assists the stabilisation of the container during at least a portion of the flight of the container.

A drone-type lifesaving equipment dropping device including: an unmanned aerial vehicle (2) having a propeller (4) and a rotor (3) configured to rotate the propeller; a holding member (10) which is installed to the unmanned aerial vehicle (2) and configured to be operated by wireless control; and a lifesaving equipment which is detachably engaged to the holding member (10) and is dropped from the holding member (10) after the lifesaving equipment is disengaged from the holding member.

A drone-type lifesaving equipment dropping device including: an unmanned aerial vehicle (2) having a propeller (4) and a rotor (3) configured to rotate the propeller; a holding member (10) which is installed to the unmanned aerial vehicle (2) and configured to be operated by wireless control; and a lifesaving equipment which is detachably engaged to the holding member (10) and is dropped from the holding member (10) after the lifesaving equipment is disengaged from the holding member.

A drone equipped with a camera, a wireless communication module, an acoustic sensor, a GPS receiver, software and collapsible floatation device patrols above swimmers. The camera and acoustic sensor capture the video and audio of the swimmers. The information is either streamed to a command center or processed by the onboard software. With audio and video analysis capabilities, software is used to detect a swimmer in distress (SID). Alternatively the information is streamed to lifeguard or volunteers all over the world to spot SID. Another detection method is to let swimmer wear a wearable emergency notification device, which sends wireless signals comprising GPS location data. A SID presses a button to indicate rescue request and the drones fly over by GPS signal guidance. Solar power is used as the optional power source of the drones, which would allow the to sustain operation for a prolonged period of time. Once a SID is identified, the drone or drones fly over the SID and drops the collapsible floatation device.

A drone equipped with a camera, a wireless communication module, an acoustic sensor, a GPS receiver, software and collapsible floatation device patrols above swimmers. The camera and acoustic sensor capture the video and audio of the swimmers. The information is either streamed to a command center or processed by the onboard software. With audio and video analysis capabilities, software is used to detect a swimmer in distress (SID). Alternatively the information is streamed to lifeguard or volunteers all over the world to spot SID. Another detection method is to let swimmer wear a wearable emergency notification device, which sends wireless signals comprising GPS location data. A SID presses a button to indicate rescue request and the drones fly over by GPS signal guidance. Solar power is used as the optional power source of the drones, which would allow the to sustain operation for a prolonged period of time. Once a SID is identified, the drone or drones fly over the SID and drops the collapsible floatation device.