A flying pest trap (8) includes an attraction section (16), an immobilisation section (12), a body section (10) adapted to retain the attraction section (16) and the immobilisation section (12), and a power section (20) adapted to provide power to the attraction section (16). The attraction section (16) includes at least one LED light source located behind the immobilisation section (12).

A flying pest trap (8) includes an attraction section (16), an immobilisation section (12), a body section (10) adapted to retain the attraction section (16) and the immobilisation section (12), and a power section (20) adapted to provide power to the attraction section (16). The attraction section (16) includes at least one LED light source located behind the immobilisation section (12).

A trap for catching or killing insects includes a back housing, an insect capture or killing mechanism, an insect attracting light source comprising light emitting diodes (LEDs) which emit ultra violet (UV) radiation through a lens, and a cover comprising one or more openings allowing insects to enter the trap, through which insect attracting light is dispersed, or a fascia and one or more independent openings allowing insects to enter the trap, through which insect attracting light is dispersed.

A trap for catching or killing insects includes a back housing, an insect capture or killing mechanism, an insect attracting light source comprising light emitting diodes (LEDs) which emit ultra violet (UV) radiation through a lens, and a cover comprising one or more openings allowing insects to enter the trap, through which insect attracting light is dispersed, or a fascia and one or more independent openings allowing insects to enter the trap, through which insect attracting light is dispersed.

An insecticide fumigator including a chemical cartridge mount on which a chemical cartridge is configured to be mounted, a heater disposed near the chemical cartridge mount and configured to heat the chemical cartridge such that an insecticide in the chemical cartridge is evaporated from a fumigation part of the chemical cartridge, a light source disposed near the fumigation part and configured to emit light having a first wavelength range to attract insects, and a housing provided with the chemical cartridge mount and receiving the heater and the light source, in which the light source includes a UV LED and a substrate on which the UV LED is mounted, and the housing has a light passage hole through which light emitted from the light source passes.

An insecticide fumigator including a chemical cartridge mount on which a chemical cartridge is configured to be mounted, a heater disposed near the chemical cartridge mount and configured to heat the chemical cartridge such that an insecticide in the chemical cartridge is evaporated from a fumigation part of the chemical cartridge, a light source disposed near the fumigation part and configured to emit light having a first wavelength range to attract insects, and a housing provided with the chemical cartridge mount and receiving the heater and the light source, in which the light source includes a UV LED and a substrate on which the UV LED is mounted, and the housing has a light passage hole through which light emitted from the light source passes.

A device for interfering with the optical navigation capability of an organism moving in air, comprising at least a detector, a projector and a control device connected to the detector and the projector, which is characterized in that using the detector a biological feature of an organism may be identified by way of at least a signal, wherein the control device then determines the trajectory of the organism and, in dependence on the species and trajectory of the organism, indicates a light pattern, which may be projected using the projector.

A device for interfering with the optical navigation capability of an organism moving in air, comprising at least a detector, a projector and a control device connected to the detector and the projector, which is characterized in that using the detector a biological feature of an organism may be identified by way of at least a signal, wherein the control device then determines the trajectory of the organism and, in dependence on the species and trajectory of the organism, indicates a light pattern, which may be projected using the projector.

The present invention discloses an automated mosquito host bio-mimicking device. The device is capable of being operated in multiple modes. The device includes a pheromone chamber (1) to enclose the mosquito attractants such as pheromones, a thermal chamber (2) to mimic the body temperature and facilitate the dissemination of the pheromones, an electronic chamber (3) for automatically regulating the functioning of the device, a photocatalysis chamber (4) to generate micro quantity of CO.sub.2, a suction chamber (4a) to suck the mosquitoes reaching the mouth of the photocatalysis chamber (4), and a dehydration chamber (5) to immobilize the trapped mosquitoes. The device traps various species of mosquitoes using a broad spectrum of attractants and controls their population by providing an eco-friendly and cost-effective approach. Further, the device is portable and is operable remotely through a mobile application.

An improved remote insect detector is disclosed. The detector includes a pitfall trap that is adapted to trap a target insect within the pitfall trap. An insect funnel passage is located below the pitfall trap and is dimensioned to retain the target insect in a detecting position. An optical beam detection circuit operates to detect the target insect in the detecting position and operates to generate a detection signal.