Automatic detection and elimination of mites through laser exposure is provided. In various embodiments, light is emitted into a target area from at least one light source. Light reflected from a target within the target area is detected by at least one photodetector. A signal is produced proportional to an intensity of the reflected light. A laser pulse is emitted into the target area by a laser emitter when the signal exceeds a predetermined threshold.

A method for reducing a population size of a colony of magnetosensitive insects includes placing wire loop near a nest sheltering the colony, driving the wire loop with an electrical current sufficient to produce a transmitted magnetic field stronger than the earth's natural magnetic field, exposing eggs and pupae from the colony to the transmitted magnetic field, and maintaining exposure of the colony to the transmitted magnetic field until the population size of the colony decreases.

An insect trapping unit includes an adhesive sheet transparent to ultraviolet rays, and a reflective member configured to reflect the ultraviolet rays transmitted through the adhesive sheet in a direction for the reflected ultraviolet rays to transmit through the adhesive sheet again. The adhesive sheet includes a base body including a fluorescent whitening agent inside, and an adhesive arranged as a layer on a front surface of the base body. The reflective member includes a reflective surface opposed to a back surface of the base body.

A device for detecting a group of offending objects and determining that the number of offending objects is above a predetermined threshold of offending objects. The device uses an image capturing system to scan areas to detect flying objects such as flying insects to detect a presence of a swarm of such flying objects. An action head on the device is configured to automatically respond once a swarm of objects is identified. The action head may disperse the swarm by expelling a substance such as a mist, smoke, repellant or insecticide.

An induction heating system a base and an electromagnetic radiation source configured to generate an emission area in the base. The emission area comprises a portion of the base that receives electromagnetic radiation from the electromagnetic radiation source. The system also includes a ferromagnetic element and an element controller configured to move the ferromagnetic element into and out of the emission area.

A method for performing mold remediation includes placing a ferromagnetic material in or adjacent to a surface upon which mold is located. The method also includes emitting, by an electromagnetic radiation source, radiation to heat the ferromagnetic material that is adjacent to the surface upon which the mold is located. The method also includes detecting, by a temperature sensor, a temperature of the surface. The method further includes comparing, by a processor in communication with the electromagnetic radiation source and the temperature sensor, the temperature of the surface to a desired temperature to perform mold remediation.

A device for subjecting a flying insect to lethal radiation. The device has a measurement beam source for producing a measurement beam, a deflection unit for deflecting the measurement beam, a lethal radiation source for producing a lethal beam and a measurement beam detector. The measurement detector has a photodetector element, the deflection unit and the measurement beam detector are arranged and cooperate such that the measurement beam sweeps the detector surface of the measurement beam detector. The device includes an evaluation unit connected to the measurement detector and the lethal light source to determine an attenuation time period of an attenuation of the measurement beam between the deflection unit and the detector surface and to control the lethal light source depending on said attenuation time to emit a lethal beam impulse. A method for subjecting a flying insect to lethal radiation is also provided.

A system and method for the treatment of invasive pests includes an irradiation device that can generate an electron beam that is applicable to a tree infected by an invasive pest, wherein the electron beam provides an in-situ treatment for the tree infected by the invasive pest by killing the invasive pest via electron beam irradiation. One or more temperature sensors can be used to track the internal temperature of a tree surrogate. A differential temperature difference tracked by temperature sensor can be used to ensure that a reduction in temperature of the tree is attributable to the electron beam rather than increase in heat.

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 method of analyzing shipments of goods includes receiving, by a transceiver of a shipment analysis system, a heat map template, where the heat map template is an expected heat map for a plurality of packages in a shipment. The method also includes directing electromagnetic radiation from an electromagnetic radiation source to the package to heat any ferromagnetic material in or on a package. The method also includes generating, by a processor of the shipment analysis system, a heat map based on the heating of any ferromagnetic material in or on the package. The method further includes generating, by the processor, an alert responsive to a determination that the generated heat map does not match the heat map template. The alert indicates that the package is not one of the plurality of packages in the shipment.