A system and method are provided to control the amplification of natural frequencies emanating from molecules, specifically insect sex pheromones. The pheromone molecules are deposited in a resonant cavity that allows the generation of coherent and/or semi-coherent radiation. The molecular emissions are amplified in the resonant cavity and allowed to escape through a small circular opening on top of the resonant cavity. The molecules and/or their emissions dissipate into the surroundings to attract insects towards the cavity. When the insect enters the resonant cavity, a trap door prevents the insect from exiting. The molecular emissions are produced by passive diffusion and passive amplification because no pumping radiation source is required. However pumping radiation can be integrated to assist the passive amplification or serve as a second attractant.

A remote insect monitor and associated method include a container configured to allow an insect attractant within the container to escape into ambient air proximate a landing area. At least one detection sensor generating sensor data of insects proximate the landing area, and a control module has a processor and a memory storing machine readable instructions executable by the processor to process the sensor data and count insects proximate the landing area. The remote insect monitor and associated method may also include an analyzer for analyzing an insect of interest to determine whether the insect carries a disease, wherein the control module sends an indication of whether the insect carries the disease to the remote server.

An apparatus for trapping flying insect pests, including:

a device for diffusing in the surrounding ambient air a gaseous lure the composition of which is suitable for attracting the insects; a device for sucking a flow of surrounding ambient air containing the insects attracted by the diffused gaseous lure, an insect trap arranged with the suction device so the insects sucked by said device are retained in said trap.

A device for controlling at least one insect bait station (100), in particular for insects harmful to humans, animals and plants, in which the bait station is provided with: at least one container (3, 5) provided with an insect entrance opening, the container containing bait and being at least partially transparent or translucent, a lighting device (10) lighting the inside of the container but located outside same, a telecommunication module (23, 25) and a printed circuit comprising, inter alia, a memory and a processor connected to said telecommunication means. The device comprises an optical sensor essentially opposite the lighting device, and connected to the printed circuit (12), which measures the general opacity caused by the insect(s) in the container, the corresponding value being transmitted for processing and analysis of the status of the bait station.

The invention relates to methods of trapping a pest, said method comprising providing ferromagnetic particles for ingestion by the pest, and trapping the pest using one or more magnets, wherein a trapped pest has ingested and internally accumulated an amount of the ferromagnetic particles sufficient to permit immobilization of the pest using said one or more magnets. Devices for use with the methods of the instant invention are also disclosed.

A remote insect monitor and associated method include a container configured to allow an insect attractant within the container to escape into ambient air proximate a landing area. At least one detection sensor generating sensor data of insects proximate the landing area, and a control module has a processor and a memory storing machine readable instructions executable by the processor to process the sensor data and count insects proximate the landing area. The remote insect monitor and associated method may also include an analyzer for analyzing an insect of interest to determine whether the insect carries a disease, wherein the control module sends an indication of whether the insect carries the disease to the remote server.

A harborage for growing and harvesting insects includes a substrate and a mesh material. The substrate has first and second edges extending along the length of the substrate and separated by a shorter width. The substrate includes an absorbent material and is formed into at least one channel extending in a direction along the length of the substrate, in some cases such that the channel is perpendicular to the width and has a depth that is less than the width of the substrate. The mesh material is disposed on the substrate, extends along substantially all of the length of the substrate and includes openings that are smaller than juveniles of a target insect, but sufficiently large to permit liquid feeding of the target insect through the mesh material, which is affixed along the substrate so as to prevent insect egress.

Disclosed herein is an insect trapping device comprising an inner passageway structure defining an inner passageway which, when in an upright orientation, extends from an insect entry zone to an insect delivery zone, the inner passageway structure bordered by at least a pair of opposed insect-facing traction-reducing boundary surface regions to cause an insect to progress toward the insect delivery zone under gravity, with each boundary surface region including at least one of at least a pair of electrode surface regions, wherein each electrode surface region is configured for operative coupling with an electrode power supply to deliver electrical power thereto, the electrode surface regions configured to form an electrocution zone therebetween, with a designated spacing which is configured to initiate electrocution of an instance of the insect descending through the electrocution zone.

It is important to trap and identify mosquitos to ensure the safety of the population where mosquitos gather. The classification of a type of mosquito is typically accomplished by a unique wingbeat signature that is characteristic of different types of mosquitos. One of the goals of the trap is to quickly identify the mosquito and then quickly release the mosquito. This application will allow the user to obtain an approximate population so that the appropriate type and amount of insecticide can be applied to control the population to insure the health of the human and animal population while at the same time minimizing danger to the environment or surrounding ecosystem.

An insect monitoring device and method of monitoring insects having a body with a slide out tray assembly. The tray assembly has a replaceable sheet assembly with an exposed adhesive surface. The tray assembly has an aperture through which insects may pass to encounter the adhesive surface. Spaced from the adhesive surface is a heating element to warm the interior of the monitoring device. A sheet assembly has a reflective side to reflect heat back onto the adhesive surface and an insulating side to increase efficiency. A sensor array images the adhesive surface and transmits images to a remote computer. Other sensors may also be present on the sensor array.