A remote insect monitor and associated method include a container configured to allow an insect attractant within the container to escape into ambient air proximate a landing area. At least one detection sensor generating sensor data of insects proximate the landing area, and a control module has a processor and a memory storing machine readable instructions executable by the processor to process the sensor data and count insects proximate the landing area. The remote insect monitor and associated method may also include an analyzer for analyzing an insect of interest to determine whether the insect carries a disease, wherein the control module sends an indication of whether the insect carries the disease to the remote server.

Disclosed herein is an insect trapping device comprising an inner passageway structure defining an inner passageway which, when in an upright orientation, extends from an insect entry zone to an insect delivery zone, the inner passageway structure bordered by at least a pair of opposed insect-facing traction-reducing boundary surface regions to cause an insect to progress toward the insect delivery zone under gravity, with each boundary surface region including at least one of at least a pair of electrode surface regions, wherein each electrode surface region is configured for operative coupling with an electrode power supply to deliver electrical power thereto, the electrode surface regions configured to form an electrocution zone therebetween, with a designated spacing which is configured to initiate electrocution of an instance of the insect descending through the electrocution zone.

A device, system, and method of controlling pests are disclosed. A pest control device includes a sensor having a sensor cell and a controller. A surface of the sensor cell is coated with an agent that reacts with a targeted biochemical analyte secreted by pests. The controller is coupled to the sensor and is configured to receive sensor data from the sensor cell indicative of a rate of change in sensor mass detected on the surface of the sensor cell, determine whether the rate of change in the sensor mass based on the received sensor data exceeds a predefined threshold rate, and transmit a pest detection alert notification to a server in response to a determination that the rate of change exceeds the predetermined threshold rate.

A monitoring trap and classification system may help pest control professionals, landlords, and homeowners identify, monitor, and manage insects. The trap may have an adhesive area that traps an insect, as well as several features that assist in identifying the insect. A classification system may use a picture or image of the trap to extract the trap's identifier, orient and adjust the image to standardize the image's color and scale, and have the insect identified. The trap and classification system may be used by individual homeowners, tenants, landlords, farmers, and pest professionals to capture, identify, and manage insects. The classification system may reduce the complexity of counting and classifying trapped insects, and it may generate a history through a series of reminders and keeping a database of previous observations.

It is important to trap and identify mosquitos to ensure the safety of the population where mosquitos gather. The classification of a type of mosquito is typically accomplished by a unique wingbeat signature that is characteristic of different types of mosquitos. One of the goals of the trap is to quickly identify the mosquito and then quickly release the mosquito. This application will allow the user to obtain an approximate population so that the appropriate type and amount of insecticide can be applied to control the population to insure the health of the human and animal population while at the same time minimizing danger to the environment or surrounding ecosystem.

A system may include a trap and a consumable. The trap may include a data capture mechanism configured to capture data and send the data to a system operator. The consumable may include a device having an associated electronic identification code. A status-determining mechanism may be configured to determine a status of the consumable, which status may be readable via the data capture mechanism. The consumable may include a sensor configured to detect flying insects via mutual capacitance sensing. The sensor may be configured to provide a directional fringe field responsive to a flying insect. The sensor may include a plurality of sensor triplets arranged in a grid array. Each sensor triplet may include a sensor conductor and two electrically conductive un-grounded conductors. The two un-grounded conductors may be disposed one on either side of the sensor conductor to form the sensor triplet.

An insect monitoring device and method of monitoring insects having a body with a slide out tray assembly. The tray assembly has a replaceable sheet assembly with an exposed adhesive surface. The tray assembly has an aperture through which insects may pass to encounter the adhesive surface. Spaced from the adhesive surface is a heating element to warm the interior of the monitoring device. A sheet assembly has a reflective side to reflect heat back onto the adhesive surface and an insulating side to increase efficiency. A sensor array images the adhesive surface and transmits images to a remote computer. Other sensors may also be present on the sensor array.

A pest control device comprising a capacitive sensor array including a plurality of sensor pads, the capacitive sensor array being configured to generate an electrical output signal indicating the state of each sensor pad, and an electronic controller electrically connected to the capacitive sensor array, the electronic controller including a processor and a memory including a plurality of instructions, which, when executed by the processor, causes the processor to: receive the electrical output signals from the capacitive sensor array, determine a measured capacitance value for each sensor pad based on each electrical output signal, calculate a baseline for each sensor pad based on the measured capacitance value of the sensor pad, determine whether a difference between the measured capacitance value of at least one sensor pad and its corresponding baseline exceeds a first predetermined threshold, update a counter when the first predetermined threshold is exceeded, and record an event indicative of a presence of a pest when the counter exceeds a predetermined limit.

The disclosure relates to the detection of arthropods (beneficial insects and/or pests) in a region in which plants grow via a camera.

A system for managing and monitoring a sensor network that senses pest activity. A plurality of sensor stations may be controlled by the system, such sensor station configured for detecting the presence of pests at a baiting station, or for alerting users to the presence of a pest in a trap, as well as a related system of data collection and data management of pest activity data.