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.

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 main body having an adhesive sheet insertion hole; a light source mounting unit disposed on the main body; a cover which is detachably mounted on the main body and has a through-hole in at least a part thereof; an adhesive sheet including a sticky substance and a sheet. The main body includes a guide unit by which the adhesive sheet is guided, and an adhesive sheet support unit for supporting the adhesive sheet.

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 trapping system having a natural plant disposed proximately to a mosquito capture chamber. The capture chamber is suspended above a well configured to retain standing water. Standing water provided in the well and the plant foliage are each independent attractants to mosquitoes. A soil retaining structure is configured to allow drainage water from the soil system to flow into the well containing standing water, thereby depositing biological matter into the water. Decaying biological matter provides additional bait to attract mosquitoes.

According to an aspect of the invention, a method for trapping indoor adult Phycitinae, which is an adult moth belonging to Phycitinae subfamily includes: emitting attracting light at a predetermined photon flux density for a predetermined period of time or longer; forming a guide path to guide the adult Phycitinae to a vicinity of an emission end of the attracting light in a region having a photon flux density lower than the predetermined photon flux density on a side lower than a height of the emission end; and trapping the adult Phycitinae attracted by the attracting light in the guide path.

A light source device for trapping indoor adult Phycitinae, which is an adult moth belonging to subfamily Phycitinae, is configured to: emit an attracting light at a predetermined photon flux density; and form a guide path by the attracting light to guide the adult Phycitinae to a vicinity of an emission end of the attracting light in a region having a photon flux density lower than the predetermined photon flux density on a side lower than a height of the emission end of the attracting light.

The present disclosure relates to a wasp catcher, and more particularly, to a wasp catcher that can isolate only wasps using a trap structure on a front surface of a hive without using an attractant and can easily separate and remove only caught and isolated wasps or killed wasps. The present disclosure provides a wasp catcher detachably attached to a hive and not using an attractant. The wasp catcher can guide wasps to move to a second catching portion through a first catching portion using flight straightness and phototaxis of the wasps and can allow bees moved to the second catching portion to exit the second catching portion, thereby catching and isolating only the wasps in the second catching portion.

Techniques for analyzing images of pests using a mobile device application are described. A mobile computing device may receive, via a graphical user interface (GUI), location information input corresponding to a location of a glueboard, an identification input of a pest type caught on the glueboard, and an image of the glueboard. The device may analyze white and dark areas of the image to determine at least one of: 1) total dark surface area of the glueboard and 2) number and size of multiple contiguous dark surface areas of the glueboard. The device may calculate a quantity of pests based on dark surface area and an average size of the pest. The device may output the quantity of pests to the GUI.

A flying insect light trap monitoring device and related methods and systems. The flying insect light trap monitoring device includes a housing, camera, controller, and communications module. The housing includes a mounting structure configured to couple with a flying insect light trap. The camera generally includes a wide angle lens. The camera and wide angle lens are secured to the housing and take a digital photograph image of a glue board in the flying insect light trap. The controller, including a processor and a memory, is secured within the housing and is communicatively coupled to the camera. The controller receives the digital photograph image. The communications module is operatively coupled with the controller and sends data packets, including the digital photograph image, to a remote server. Further, an image processing engine that processes the image and generates an insect count can be included.