Method of providing insects for sorting into classes or for quality control of sorted insects comprises providing the insects in a container having a closable opening, opening the closable opening, releasing the insects through the closable opening onto a funneled air flow, the air flow carrying the insects to a collection location, the collection location being conveyable, and applying immobilizing agent to the insects on the collection location, thereby to provide stationary insects for said sorting or quality control.

Systems and methods for generating and displaying heat maps are provided. A heat map generation computing device includes a memory and a processor. The processor is programmed to receive trap data for a plurality of pest traps in a geographic location, the trap data including current and historical pest pressure values at each of the plurality of pest traps, receive weather data for the geographic location, receive image data for the geographic location, apply a machine learning algorithm to generate predicted future pest pressure values at each of the plurality of pest traps, generate a first heat map for a first point in time and a second heat map for a second point in time, and transmit the first and second heat maps to a mobile computing device to cause a user interface on the mobile computing device to display a time lapse heat map.

The present invention relates to a pest identification and information monitoring system through image analysis and a monitoring method using the same, and more particularly, to a pest identification and information monitoring system through image analysis, which obtains pest images by photographing pests using image input means, compares the learning model built for each pest with the pest image to calculate the degree of similarity, and specifies the pest of the acquired image based on the calculated degree of similarity, and recommends information or control methods related to the pest, and a monitoring method using the same.

A device for subjecting a flying insect to lethal radiation. The device has a measurement beam source for producing a measurement beam, a deflection unit for deflecting the measurement beam, a lethal radiation source for producing a lethal beam and a measurement beam detector. The measurement detector has a photodetector element, the deflection unit and the measurement beam detector are arranged and cooperate such that the measurement beam sweeps the detector surface of the measurement beam detector. The device includes an evaluation unit connected to the measurement detector and the lethal light source to determine an attenuation time period of an attenuation of the measurement beam between the deflection unit and the detector surface and to control the lethal light source depending on said attenuation time to emit a lethal beam impulse. A method for subjecting a flying insect to lethal radiation is also provided.

Method and apparatus for a pest control device mounting system configured for mounting pest control devices in a building and using them to control pests. The pest control device mounting system including a mounting bracket, which may have a circumferential portion defining a portal. In some examples, the mounting bracket includes a flange portion suitable for attaching to the perimeter of a cavity in a building surface. The pest control device mounting system including a plug configured to be removably attached to the mounting bracket and to substantially close the portal when attached to the mounting bracket, wherein the plug is configured to accommodate a pest control device.

The present application describes a pollinator species detection and monitoring device and system that utilizes specifically positioned and spaced receptacles for determining and conveying the numbers, health and movements of pollinator species ranging from real-time to intermittent transmittance of detected information for an area, region, areas or regions, singularly and in the aggregate. The detected information is collected and recorded via a pair of closely related sensors, residing at 180 degrees from one another, wherein pollinator species' entrance, exit, number, gender and activity are sensed, analyzed algorithmically and stored locally for eventual transmittance from a transmitting device to an external computer or mobile device for data observance, collection, storage and analysis. Detected information may be species specific or across a plurality of species.

Due to their disease transmission, mosquitoes are the deadliest animal, killing over a million people each year. In addition, mosquitoes cause discomfort for adults and especially children who may suffer heavily from mosquito bites. Indeed, a study shows that most respondents considered mosquitoes to be a problem. Unfortunately, a combination of environmental change and urbanization help mosquitoes spread into new areas. Spraying mosquito repellent to eliminate mosquitoes was shown to be harmful for humans as well, and other devices fail to eliminate all mosquitoes. Therefore, we propose the development of an insect killer drone. The drone will include a tiny gun that, once the drone approaches the mosquito, will be able to eliminate it. The system also includes a docking station that detects the mosquitoes and controls the drone. The drone is intended to be autonomous but may allow manual control of the drone and tiny gun.

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.

Systems and methods for generating and displaying heat maps are provided. A heat map generation computing device includes a memory and a processor. The processor is programmed to receive trap data for a plurality of pest traps in a geographic location, the trap data including current and historical pest pressure values at each of the plurality of pest traps, receive weather data for the geographic location, receive image data for the geographic location, apply a machine learning algorithm to generate predicted future pest pressure values at each of the plurality of pest traps, generate a first heat map for a first point in time and a second heat map for a second point in time, and transmit the first and second heat maps to a mobile computing device to cause a user interface on the mobile computing device to display a time lapse heat map.