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.

A pest detection device including a capacitive sensor having a plurality of traces that can be capacitively sensed using self-capacitance or mutual capacitance measurements. The sensor including conductive shield traces to facilitate a number of sensing applications. The sensor including a coated portion to facilitate crawling of pests over the sensing area of the circuit board.

An improved remote insect detector is disclosed. The detector includes a pitfall trap that is adapted to trap a target insect within the pitfall trap. An insect funnel passage is located below the pitfall trap and is dimensioned to retain the target insect in a detecting position. An optical beam detection circuit operates to detect the target insect in the detecting position and operates to generate a detection signal.

The present invention provides a mosquito trapping device, which comprises a carbon dioxide generating module, a temperature control module, a humidity control module, and a mosquito-killing module. The carbon dioxide generating module comprises a container A and a container B, a solution in the container A reacts with a solution in the container B to generate carbon dioxide; the temperature control module controls a temperature of the mosquito trapping device to be between 38° C. and 45° C.; the humidity control module controls humidity of the mosquito trapping device to be between 50% and 80%; the mosquito-killing module generates a guiding wind having a wind speed of 0.7 m/s to 15 m/s. The present invention has a good mosquito-attracting effect and a desirable mosquito-killing ability.

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.

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.

An insect trapping device includes a base with a shroud and a cartridge. The cartridge includes an adhesive portion that is positioned adjacent the shroud, when the cartridge is attached to the base. The shroud includes an electric heating element, which heats the shroud and the adhesive portion of the cartridge.

A system for detecting the presence of pests, the system comprising: at least one remote camera system, each of the at least one remote camera system comprising an image capture device coupled to a processor and a wireless transmitter, each of the at least one remote camera system having a pest detection surface and being configured to: capture one or more image of the pest detection surface; process the captured one or more image to recognise the potential presence of a target pest on the pest detection surface; and transmit data from the captured one or more image in response to recognising the potential presence of one or more target pests; and a server configured to: receive the transmitted data; process the transmitted data to verify the potential presence of the target pest on the pest detection surface; and provide an output indicating the verification.

Device for detecting insects comprising as main elements an inner chamber that has a temperature higher than the temperature outside and a passive infrared sensor that emits an alarm signal when it detects a change in temperature in the inner chamber due to the presence of any animal, for example, an insect; which is very useful for the monitoring of insects in a determined area and the subsequent actuation for the eradication thereof.

A portable, heated scent, odor, and/or molecule dispense system is provided, as well as devices and methods for doing the same. The portable systems and methods to dispense molecules may contain a liquid, gel, solid, foam, or other material-based formulation so as to attract, repel, kill, mask, or otherwise use the molecules. The portable system and methods may include a housing; a molecule holding pad in the housing; a first chemical reaction heat source in the housing; and a second chemical reaction heat source in the housing, wherein the molecule holding pad is arranged between the first chemical reaction heat source and the second chemical reaction heat source, and wherein the first chemical reaction heat source and the second chemical reaction heat source are each reactive to oxygen.