The present disclosure describes a trap for catching or killing insects, and a method of attracting flying insects to an insect trap. The trap includes a back housing, an insect capture or killing mechanism, an insect attracting light source including light emitting diodes (LEDs) that emit ultra violet radiation, and a cover with openings that allow insects to enter the trap. The light source is directed immediately inwardly through plus or minor 45 degrees towards the insect capture or killing mechanism and is precluded from being directed immediately outwardly through the cover.

A mosquito control net includes an occupant chamber and a trap chamber disposed over the occupant chamber. The trap chamber has one or more openings disposed on an outer surface thereof, through which mosquitos enter the trap chamber, the openings having receptacles attached therein and extending within the trap chamber to inhibit egression of mosquitos from the trap chamber after entry. A method for preventing mosquito bites for a subject can include providing such a mosquito control net and having the subject occupy it. A kit of parts for converting a conventional mosquito control net into a trapping mosquito control net can comprise a funnel-shaped receptacle surrounded by a bag, the bag being substantially impermeable to mosquitos and the receptacle and/or the bag being attachable to a top surface of the conventional mosquito control net to form a trap compartment.

An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

A discrete and safe automated insect monitoring system includes a housing, an interior chamber within the housing, and a light source arranged within the housing to illuminate at least a portion of a floor surface of the interior chamber. A multi-pixel optical sensor is arranged within the housing so that a field of view of the sensor comprehends a substantial portion of the floor surface. A processing circuit arranged within the housing receives optical data from the multi-pixel optical sensor, analyzes the optical data to detect the intrusion of an insect or other object into the interior chamber by comparing most recently received optical data to previously received optical data, and generates an indication in response to detecting the intrusion of an insect or other object. Detection and/or classification results can be wirelessly forwarded to another device, to alert appropriate personnel.

A discrete and safe automated insect monitoring system includes a housing, an interior chamber within the housing, and a light source arranged within the housing to illuminate at least a portion of a floor surface of the interior chamber. A multi-pixel optical sensor is arranged within the housing so that a field of view of the sensor comprehends a substantial portion of the floor surface. A processing circuit arranged within the housing receives optical data from the multi-pixel optical sensor, analyzes the optical data to detect the intrusion of an insect or other object into the interior chamber by comparing most recently received optical data to previously received optical data, and generates an indication in response to detecting the intrusion of an insect or other object. Detection and/or classification results can be wirelessly forwarded to another device, to alert appropriate personnel.

An adhesive-type insect trap includes a body having a hole for insertion of an adhesive sheet; a light source mounting unit disposed on the body; and a cover which is detachably mounted on the body and has a through-hole in at least a part thereof. The body further includes a light source seating unit provided so as to correspond to the light source mounting unit, and a light source may have one side thereof mounted on the light source mounting unit and the other side thereof seated on the light source seating unit.

Problems associated with the use of fluorescent tubes in insect traps are resolved by providing a replacement lamp array employing multiple sets of light emitting diodes that each emit light at different specific wavelengths and are positioned within a one or more translucent sleeves having a surface coated with an environmentally safe light diffusion material creating a pattern comprising areas of more intense light dominated by the light cast by a single LED separated by areas of less intense light.

A trap for flying insects includes a housing having a plurality of housing apertures and a tank located interior of the housing. The tank has an insect killing agent within an interior of the tank and a plurality of tank apertures adjacent an upper portion of the tank in communication with the interior of the tank for access of flying insects into the interior of the tank. The tank apertures are located proximate the housing apertures to provide a path for flying insects to travel from locations exterior of the housing to the tank apertures and into the tank. The trap also includes an insect attractive illumination located proximate the tank apertures.

A trap for flying insects includes a housing having a plurality of housing apertures and a tank located interior of the housing. The tank has an insect killing agent within an interior of the tank and a plurality of tank apertures adjacent an upper portion of the tank in communication with the interior of the tank for access of flying insects into the interior of the tank. The tank apertures are located proximate the housing apertures to provide a path for flying insects to travel from locations exterior of the housing to the tank apertures and into the tank. The trap also includes an insect attractive illumination located proximate the tank apertures.