A pest monitoring system and associated method includes pest monitoring devices for placement at a site and generating a signal upon detection of a pest, and a pesticide dispensing unit including a reservoir housing a diluent and a pesticide module housing a pesticide. A computer device remotely disposed to the pest monitoring devices receives generated signals therefrom, analyzes environmental and historical factor data for the site to determine an amount and placement location of the pest monitoring devices for monitoring the site, and directs deployment of the pest control monitoring devices according to the analysis. The computer device also receives data from the pesticide dispensing unit including an amount or rate of the pesticide substance dispensed from the pesticide module, to form treatment having a concentration of the pesticide substance in the diluent, the treatment being dispensed from the pesticide dispensing unit to treat a detected pest at the site.

A sprinkler controller capable of repelling an animal is illustrated and has an image capturing unit and a processing unit. The image capturing unit is used to capture images of a space. The processing unit electrically connected to the image capturing unit is used to analyze the images to determine whether an animal invades a specific zone which is selected or defined by a user in advance, and control a sprinkler unit in the specific zone to sprinkle in response to a determined result.

This disclosure provides a method of detecting and deterring a target animal from a target area. A target area is positioned within the field of vision of a video camera connected to a computer processing system. An animal identification computer program using convolution neural networks and deep learning computer programs and camera images rapidly detects a target animal. The animal identification computer program is trained to identify target animals accurately using a learning algorithm and related machine learning technology. The time to deploy a deterrent against a target animal from the instant of detection is 2 seconds or less so that little or no time is available to the target animal to damage the target area.

A method of detecting the presence of insects, including larvae, in an indoor environment, which includes the steps of (a) obtaining a sample of volatile organic compounds (VOCs); (b) separating the sampled VOCs; (c) detecting the presence or absence of target VOCs from at least one category: category 1 VOCsVOCs emitted independently of the support on which the insects develop and emitted only in an insect infestation VOCs, category 2 VOCsVOCs emitted independently of the support but may have biological origins other than insects, and category 3 VOCsVOCs emitted depending on the support and emitted only in an insect infestation; (d) calculating both an insect infestation index (3I) and a limit value (VL) based on the presence or absence of the target VOCs; and (e) comparing the 3I and VL values. The environment is infested for a 3I value strictly greater than the VL value.

The invention relates to an apparatus 1 for holding a piece of bait 2, in particular a piece of bait 2 for pests 14, preferably for rodents, comprising: a housing part 3 which has a receiving space 6 for receiving a piece of bait 2 and can be inserted into a part of a sewer system, a detecting device 9, equipped to detect a first item of information, an output device 11, equipped to output a first item of information detected by the detecting device 9.

A bait station having an enclosed housing defining an internal volume is disclosed, wherein the internal volume is divided by a partition wall defining a main chamber and an electronics compartment. The electronics compartment has a wireless communication module including a computer processor and transceiver. The main chamber has a single access for a targeted type of pest and a bait access door. A bait platform is located within the main chamber, and a bait monitoring sensor is also located within the main chamber. The bait monitoring sensor is communicatively coupled with the wireless communication module.

A snake snare barrier comprising a first layer of netting and a second layer of netting, the first layer defining a first plurality of through holes of a first size, the second layer defining a second plurality of through holes of a second size, the netting being flexible under its own weight along substantially an entire length and width, the netting being capable of being unrolled along the length and draped across a top of a vertical support, and the netting substantially conforming to a shape of the vertical support under its own weight after being draped thereupon, the first layer having each edge substantially not connected to any edge of the second layer, and each layer has a width that measures between 9 inches and 24 inches.

A remote monitor for wild animal trap, including a receiving monitoring host, a transmitting apparatus and a magnetic-sensitive switch. The host includes a VHF/VHF receiving module, LED state indicator lamps for indicating trap states and a first single chip microcomputer for processing signals, which are electrically connected. Each host can be connected with more than one transmitting apparatus through a wireless communication technology. The transmitting apparatus includes a VHF/UHF transmitting module, electric quantity indicator lamps and a second single chip microcomputer for processing signals.

An enclosure for an outdoor smart camera includes an environmentally sealed main housing with a core formed by a hollow heatsink. The heatsink runs through the interior of the housing with openings on either end of the heatsink to allow airflow. Heat emitting electronics inside the sealed main housing are mounted directly to the heatsink to conduct the heat passively through the heatsink to the external environment. The heatsink and main housing can be cut to any desired length to adjust the size of the enclosure and accommodate variable size and quantity of internal components. Mounting slots are included for mounting the enclosure easily to poles and other structures.

A trap 1 has a frame 3, a striking bar 5 connected to the frame for killing a mouse or rat and a retaining bracket 7 attached to the striking bar, which is blocked in standby position by a blocking pawl 11 which can be released by an activating element 13. A spring 9 is present between the striking bar and the frame, which striking bar hits the frame after activation. The trap is provided with a first sensor 17 which determines whether the striking bar is present in the standby or activated position, and a second sensor 19 which determines whether a mouse is present between the frame and the striking bar or not. The trap can determine three situations with the two sensors: standby, tripped and tripped with a mouse in the trap. This allows the status of the trap to be properly monitored.