A bug zapper coil cleaner including a brush element that is non-conductive. At least one handle is attached to the brush element. The at least one handle member is configured to move the brush from the outside of the housing on a bug zapper. The at least one handle has an elongated attachment member protruding from one end. Further, there is a clasp member connected to the brush element. The clasp member is a magnetic clasp. The clasp will hold the bug zapper coil cleaner at the top of the bug zapper between uses.

A bed bug attracting assembly is positioned at an upper location. A bed bug killing assembly is positioned at an intermediate location beneath the attracting assembly. A base assembly is positioned at a lower location beneath the killing assembly for maximizing the number of bed bugs attracted and killed. A control assembly has a user visible digital UPC code, a battery power percentage indicator with an ON/OFF button and a sound activated switch, a cell phone with a macro-lens, and two light emitting diode positioned adjacent thereto to illuminate bed bugs. An electric grid triggers a camera detector. A CO2 self-emitting device includes graphite and an electrical charge. A platform with pores holds a lure over a miniature fan. A programmable computer is preprogrammed to modulate attraction modalities. A GPS transmitter is activated to sent to receives to secure the area of infestation.

A combination lighting apparatus and insect extermination device is disclosed having a housing with an upper section and a lower section separated by a first aperture. A light source is disposed in the upper section. An electrical grid and negative pressure source are disposed in the lower section. A power source is coupled to the light source, the electric grid, and the pressure source. A second aperture is located in the lower section after the electric grid, wherein air is propagated inward through the first aperture, through the electrical grid and out the second aperture.

Systems, apparatuses, and methods of classifying flying insects. The methods utilize recording the wingbeat frequency and amplitude spectrum of flying insects and comparing them to known or created insect models to properly classify the flying insect. The error rate of the classification is reduced by utilizing multiple inputs to the classification system, which may include a precise circadian rhythm for the time of year, current environmental conditions, and flight velocity or direction.

A mosquito agitator system and method to disrupt the development of mosquito larvae in bodies of water are disclosed. The mosquito agitator, in one embodiment, includes a motor coupled to a rotating shaft that is coupled to a non-symmetric mass; a hull coupled to the motor; one or more solar panels coupled to the hull for capturing solar energy into electricity; a plurality of sensors; and a controller coupled to at least the motor, wherein the controller is configured to receive sensor data from the plurality of sensors; select a first mosquito agitator algorithm for execution; and execute the first mosquito agitator algorithm to control activate the motor in accordance with the first mosquito agitator algorithm, wherein the activation causes the hull to create a plurality of water ripples in the body of water to disrupt the development of mosquito larvae.

A computer-implemented method for monitoring disease vectors is disclosed. A vector sensor obtains vector data relating to disease vectors in a monitored area. An environmental data obtaining component obtains environmental data relating to the monitored area. Based on at least one of the vector data and the environmental data, a population characteristic component may estimate or determine a vector population characteristic associated with the monitored area. A structural data obtaining component may obtain structural data relating to the monitored area. A vector travel estimation component may estimate or determine a vector travel characteristic. The vector characteristic may be indicative of predicted disease vector movement from outdoors to indoors in the monitored area and may allow for or facilitate a vector control action based at least partially on the vector travel characteristic. A device and a system for monitoring disease vectors are also disclosed.

A computer-implemented method for monitoring disease vectors is disclosed. A vector sensor obtains vector data relating to disease vectors in a monitored area. An environmental data obtaining component obtains environmental data relating to the monitored area. Based on at least one of the vector data and the environmental data, a population characteristic component may estimate or determine a vector population characteristic associated with the monitored area. A structural data obtaining component may obtain structural data relating to the monitored area. A vector travel estimation component may estimate or determine a vector travel characteristic. The vector characteristic may be indicative of predicted disease vector movement from outdoors to indoors in the monitored area and may allow for or facilitate a vector control action based at least partially on the vector travel characteristic. A device and a system for monitoring disease vectors are also disclosed.

Aspects of the present invention determine a presence of insects at a location of a first device that comprises a computer processor, and in response to determining the presence of the insects at the location of the first device, apply a screen overlay that changes colors displayed by a display of the first device.

Method and apparatus for mechanical sex-sorting of mosquitoes by extracting a class of mosquitoes from unsorted mosquitoes comprises obtaining unsorted mosquitoes, obtaining images of individual mosquitoes in a stationary phase, electronically classifying the individuals from the images into male mosquitoes and/or female mosquitoes, and possibly also unclassified objects; obtaining co-ordinates of individuals of at least one of the male mosquito and female mosquito classifications, and using a robot arm to reach an individual identified by the obtained coordinates to store or remove the individuals, thereby to provide sex-sorted mosquitoes.

A pest detection and notification system includes one or more pest monitors and notification badges or cards. Both the pest monitors and the notification badges are capable of short-range wireless communication. Upon detection of presence of a pest, a pest monitor generates and transmits a wireless pest event message. Any notification badge present within the transmission area of the pest monitor will receive the pest event message. Each notification badge includes one or more pest event indicators, such as an audible indicator, a visible indicator, and/or a vibration motor. Upon receipt of the pest event message, the notification badge activates one or more of the pest event indicators, thus notifying the wearer that a pest presence within the transmission area has been detected.