A method and system for preparing a distribution program for insects comprises obtaining distribution data of a wild population of insects; obtaining distribution parameters including distribution resolution levels of at least one available distribution vehicle; generating a population density map at a resolution level consistent with the distribution resolution level of the vehicle; generating a release map by modifying the population density map in accordance with the distribution parameters; and generating a path using the release map, the path defining dosages of insects to be released at respective locations along the path.

An insect trapping light is shown having a visible light housing, a pair of electronic display screens, and an insect trapping housing. The display screen may be a television screen, picture display screen, movie display screen, computer monitor or display, or the like. The insect trapping housing has a bottom space configured to removably receive an insect bait tray that may be filled with an insect baiting substance to attract insects. The insect trapping housing and the visible light housing combine to form a UV light space or chamber therebetween. An adhesive board is slidably received and held in place upon the visible light housing surface facing the UV light chamber. The spacing between the insect trapping housing and the visible light housing defines the UV light chamber having open sides The UV light chamber also includes a matrix or array of UV lights or light sources.

An insect trap device and methods of using the device are described herein. In some embodiments, an insect trap includes a light source, a removable enclosure with at least one opening, an adhesive surface at least partially within the enclosure, and optics to redirect light from the light source onto an adhesive trapping surface. The light source may include at least one light emitting diode (LED). The optics may be attached to the removable enclosure, and may be located at least partially within the enclosure. The optics may include optical enhancers such as a reflector, a lens and/or a diffuser. The insect trap may further include an insect attractant that emits sound or scent.

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.

A trap for catching living insects, specifically fruit flies, is provided having a catch container, a base, and a funnel-shaped insert. The funnel shaped insert has a funnel wall, a plurality of slits in the funnel wall, and a funnel exit opening. The insects to be caught are able to slip through the funnel exit opening, but not through the slits. Furthermore, the trap includes an attractant container in the catch container and/or in the base having a liquid attractant and a wick. The insects are attracted by the scent of the liquid attractant evaporating from the attractant container and fly or crawl through the funnel exit opening into the catch container, where they become trapped. The user can then carry the trap outside, remove the funnel-shaped insert, and release the captured insects alive outside. In this way, the insects can be kept out of human living and working spaces without killing the insects.

The present disclosure provides an intelligent replacement device and method for a trap board in a tea garden based on image channel computation. The device includes a trap board supply module, a trap board sticker removal module and a machine vision control module fixed on a machine frame, where the machine vision control module is configured to acquire an image of a present trap board in the trap board supply module, determine whether the present trap board fails according to the image, control, in response to failure of the present trap board, the trap board supply module to replace the trap board, and control the trap board sticker removal module to remove a film of a replaced trap board. The present disclosure can replace the trap board in the tea garden automatically, timely and accurately instead of the manual operation.

Devices and methods for pest control, including devices useful to place pest control devices at locations of use such as at a crop (e.g., at a branch of a tree), certain embodiments of devices including a capsule and a tether that can become tangled or caught in a tree or other crop location.

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.

A mosquito monitoring and counting system, including a sensor, the sensor including a high-speed computer vision camera, a detector, an antenna, a central processing unit, a counting sensor, and a GSM or WIFI module. The high-speed computer vision camera is installed in a trap diffuser, the counting sensor detects all insects that enter an air stream, and the central processing unit, based on artificial intelligence through neural networks, is adapted to process a data array, count and classify insects into species and subspecies, transmit the processed data array via the GSM or WIFI module over the Internet to a server, and further processing the data array and submitting a result to be graphically integrated with a mapping service.