Due to their disease transmission, mosquitoes are the deadliest animal, killing over a million people each year. In addition, mosquitoes cause discomfort for adults and especially children who may suffer heavily from mosquito bites. Indeed, a study shows that most respondents considered mosquitoes to be a problem. Unfortunately, a combination of environmental change and urbanization help mosquitoes spread into new areas. Spraying mosquito repellent to eliminate mosquitoes was shown to be harmful for humans as well, and other devices fail to eliminate all mosquitoes. Therefore, we propose the development of an insect killer drone. The drone will include a tiny gun that, once the drone approaches the mosquito, will be able to eliminate it. The system also includes a docking station that detects the mosquitoes and controls the drone. The drone is intended to be autonomous but may allow manual control of the drone and tiny gun.

Provided herein is an efficient rodent trap device, where the rodent, such as a mouse or a rat, is killed, when the rodent is moving through the rodent trap. The rodent trap includes at least one rodent passage, a trigger mechanism and a killing mechanism. The rodent passage includes a first outer opening and a second outer opening arranged at opposite ends of the rodent passage. The openings provide entries from ambient surroundings. In use, the rodent is led into the trap through the one or the other opening. The trigger mechanism includes one sensor and another sensor, the one sensor arranged between the killing mechanism and the first outer opening and the other sensor is arranged between the killing mechanism and the second outer opening. The killing mechanism includes at least one killing element, which in use enters said rodent passage between the sensors and when actuated by the killing mechanism.

Provided herein is an efficient rodent trap device, where the rodent, such as a mouse or a rat, is killed, when the rodent is moving through the rodent trap. The rodent trap includes at least one rodent passage, a trigger mechanism and a killing mechanism. The rodent passage includes a first outer opening and a second outer opening arranged at opposite ends of the rodent passage. The openings provide entries from ambient surroundings. In use, the rodent is led into the trap through the one or the other opening. The trigger mechanism includes one sensor and another sensor, the one sensor arranged between the killing mechanism and the first outer opening and the other sensor is arranged between the killing mechanism and the second outer opening. The killing mechanism includes at least one killing element, which in use enters said rodent passage between the sensors and when actuated by the killing mechanism.

Rat attractant compositions attractive to the rat species Rattus norvegicus are disclosed, which compositions are constituted of compounds found in the headspace volatiles of male urine odor or female urine odor. Said compositions are respectively termed male pheromone blend (MPB) and comprises 2-heptanone, 4-heptanone, 3-ethyl-2-heptanone, 2-octanone, 2-nonanone, and 4-nonanone in a ratio of 10:100:10:1:1:10 respectively, or female pheromone blend (FPB) and comprises 2-methyl-butyric acid, 3-methyl-butyric acid, heptanal, hexanoic acid, 2-phenylacetaldehyde, nonanal, and decanal in a ratio of 20:20:10:30:5:20:10. Devices including the rat attractant compositions, and methods of using said rat attractant compositions, are also disclosed.

Rat attractant compositions attractive to the rat species Rattus norvegicus are disclosed, which compositions are constituted of compounds found in the headspace volatiles of male urine odor or female urine odor. Said compositions are respectively termed male pheromone blend (MPB) and comprises 2-heptanone, 4-heptanone, 3-ethyl-2-heptanone, 2-octanone, 2-nonanone, and 4-nonanone in a ratio of 10:100:10:1:1:10 respectively, or female pheromone blend (FPB) and comprises 2-methyl-butyric acid, 3-methyl-butyric acid, heptanal, hexanoic acid, 2-phenylacetaldehyde, nonanal, and decanal in a ratio of 20:20:10:30:5:20:10. Devices including the rat attractant compositions, and methods of using said rat attractant compositions, are also disclosed.

The element of the invention is to provide an efficient rodent trap device, where the rodent, such as a mouse or a rat, is killed, when the rodent is moving through the rodent trap. The rodent trap comprises at least one rodent passage, a trigger mechanism and a killing mechanism. The rodent passage comprises a first outer opening and a second outer opening arranged at opposite ends of said rodent passage. The openings provide entries from ambient surroundings. In use, the rodent is led into the trap through the one or the other opening. The trigger mechanism comprises one sensor and another sensor, the one sensor arranged between the killing mechanism and said first outer opening and the other sensor is arranged between the killing mechanism and said second outer opening. The killing mechanism comprises at least one killing element, which in use enters said rodent passage between the sensors and when actuated by said killing mechanism.

The element of the invention is to provide an efficient rodent trap device, where the rodent, such as a mouse or a rat, is killed, when the rodent is moving through the rodent trap. The rodent trap comprises at least one rodent passage, a trigger mechanism and a killing mechanism. The rodent passage comprises a first outer opening and a second outer opening arranged at opposite ends of said rodent passage. The openings provide entries from ambient surroundings. In use, the rodent is led into the trap through the one or the other opening. The trigger mechanism comprises one sensor and another sensor, the one sensor arranged between the killing mechanism and said first outer opening and the other sensor is arranged between the killing mechanism and said second outer opening. The killing mechanism comprises at least one killing element, which in use enters said rodent passage between the sensors and when actuated by said killing mechanism.

Disclosed is a method of incapacitating a target pest species. The method having the steps of providing a trap enclosure, the trap enclosure having an entry point for the target pest species into an interior of the trap enclosure, and a bait station to attract the target pest species. Provided also is a kill engine, at least in part mounted from the trap enclosure, to at least in part deliver incapacitating energy to the target species, whereby the kill engine does not require electricity, the kill engine using an inflammable gas charge, the kill engine when triggered actuates and then resets itself. A source of compressed inflammable gas is connected to and supplies the kill engine. Present is a species adapter connected at least in part to the trap enclosure to adapt the trap enclosure to the target pest species, the species adapter based on the size, habits or travel, nature of the target pest species. A kill zone is defined within an interior of the trap enclosure and or the species adapter. A trigger mechanism actuates the kill engine when triggered by the target pest species when in the kill zone. A force delivery hammer, driven by the kill engine, delivers the incapacitating energy, such that when the target pest species enters the apparatus and the kill zone it triggers the trigger mechanism to in turn actuate the kill engine to deliver the incapacitating energy by impacting the pest.

There is provided an unmanned aerial vehicle including: a detection unit configured to detect a living body; an aiming unit configured to aim at a specific part of the living body based on a detection result of the living body; and a shooting unit configured to shoot a content, which is stored in a container, to the specific part. There is provided a shooting method for shooting a content by using an unmanned aerial vehicle, the method including: detecting a living body; aiming at a specific part of the living body based on a detection result of the living body; and shooting a content, which is stored in a container, to the specific part.

There is provided an unmanned aerial vehicle including: a detection unit configured to detect a living body; an aiming unit configured to aim at a specific part of the living body based on a detection result of the living body; and a shooting unit configured to shoot a content, which is stored in a container, to the specific part. There is provided a shooting method for shooting a content by using an unmanned aerial vehicle, the method including: detecting a living body; aiming at a specific part of the living body based on a detection result of the living body; and shooting a content, which is stored in a container, to the specific part.