A mobile culture assembly for feeding larvae of black soldier fly includes a mobile vehicle, a breeding device disposed in the mobile vehicle, and a turning device disposed on the breeding device. The breeding device includes spaced-apart breeding bodies, each of which defines a breeding space for accommodating feed materials and larvae. The turning device includes a base movably disposed on the breeding body, a feeding unit adapted to introduce the feed materials to the breeding space, a turning unit disposed under the base, a scrapping unit disposed at one end of the base, and a heat dissipating unit disposed on the base. The turning device serves to stir the feed materials and the larvae and also dissipate heat accumulated in the breeding space to thereby provide a preferable growing environment for the larvae, reduce feeding costs, and increase a reproductive rate and quality of the larvae effectively.

A lighting device is disclosed for use in connection with the extermination of insects. The device has a housing, a power source, and first and second light sources disposed about trap that facilitates extermination of the insect when it encounters the trap. A first light source propagates a wavelength of light ranging from about 370 nm to about 410 nm at a first duty cycle. The second light source propagates a wavelength of light ranging from about 340 nm to about 380 nm at a second duty cycle.

An arthropod trapping device comprising a suspension element, an engagement section including an extension that extends from the suspension element, the engagement section including an engagement element with a pest immobilization surface, wherein externally facing surfaces of the engagement element have a sticky contact substance to form the pest immobilization surface, wherein all corners, faces, and edges of the externally facing surfaces of the engagement element have the sticky contact substance, a contact lead segment formed from fibers and extending from the extension near an end of the pest immobilization surface, the contact lead segment comprising a first end and a second end, where only the first end of the contact lead segment is adjacent the pest immobilization surface, where the contact lead segment is devoid of the sticky contact substance, and where the contact lead segment forms a pest pathway to the pest immobilization surface.

A flying pest trap (8) includes an attraction section (16), an immobilisation section (12), a body section (10) adapted to retain the attraction section (16) and the immobilisation section (12), and a power section (20) adapted to provide power to the attraction section (16). The attraction section (16) includes at least one LED light source located behind the immobilisation section (12).

A system for tracking airborne organisms includes an imager, a backlight source (such as a retroreflective surface) in view of the imager, and a processor configured to analyze one or more images captured by the processor to identify a biological property of an organism.

A method of controlling mosquito populations is disclosed. The method includes: placing a plurality of ovitraps into an area where it is desired to reduce a mosquito population; filling the ovitraps with water; introducing a defined larvicidal amount of a water conditioning agent comprising cow urine into a given volume of water into the ovitraps to condition the water absent of a separate or additional pesticide; leaving the conditioned water for at least 7 weeks; and monitoring at least one of the ovitrap and the area to determine effectiveness.

A sensor system for detecting objects includes a plurality of devices and a network assembly. The plurality of device assemblies includes an object detector assembly, a termite trap assembly, and a pest trap assembly. The object detector assembly includes a device implemented along the outer perimeter of a house in order to detect various objects. Additionally, the termite trap assembly includes a cardboard cutout with a high cellulose content having conductive ink. Furthermore, the pest trap assembly includes a housing having a trap door that is used to capture pests such as rodents and mice. Each of the devices are in communication with the network assembly via a low power wide area network. Each of the devices may also act as a repeater thereby further extending the range of communication for each of the devices.

A German cockroach trap provides bait, humidity, and temperature to attract German cockroaches into entries, electrocutes the German cockroaches upon entry into the trap, and stores dead cockroaches below the entries. Electrode bands form a closed ring on an interior surface and contact with two of the rings immediately kills the German cockroach which drops into a receiving dock below. A center electrode band may include holes for entry into the trap. A water reservoir in the bottom of the trap is heated to generate humid vapor. Heaters in the top of the trap are controlled to maintain temperature and a fan in the top of the trap draws ambient air into the trap to create a humid vapor flow out through the entries. Bait trays contain material further attracting the German cockroaches.

The present invention discloses an automated mosquito host bio-mimicking device. The device is capable of being operated in multiple modes. The device includes a pheromone chamber (1) to enclose the mosquito attractants such as pheromones, a thermal chamber (2) to mimic the body temperature and facilitate the dissemination of the pheromones, an electronic chamber (3) for automatically regulating the functioning of the device, a photocatalysis chamber (4) to generate micro quantity of CO.sub.2, a suction chamber (4a) to suck the mosquitoes reaching the mouth of the photocatalysis chamber (4), and a dehydration chamber (5) to immobilize the trapped mosquitoes. The device traps various species of mosquitoes using a broad spectrum of attractants and controls their population by providing an eco-friendly and cost-effective approach. Further, the device is portable and is operable remotely through a mobile application.

The present invention discloses an automated mosquito host bio-mimicking device. The device is capable of being operated in multiple modes. The device includes a pheromone chamber (1) to enclose the mosquito attractants such as pheromones, a thermal chamber (2) to mimic the body temperature and facilitate the dissemination of the pheromones, an electronic chamber (3) for automatically regulating the functioning of the device, a photocatalysis chamber (4) to generate micro quantity of CO.sub.2, a suction chamber (4a) to suck the mosquitoes reaching the mouth of the photocatalysis chamber (4), and a dehydration chamber (5) to immobilize the trapped mosquitoes. The device traps various species of mosquitoes using a broad spectrum of attractants and controls their population by providing an eco-friendly and cost-effective approach. Further, the device is portable and is operable remotely through a mobile application.