A pest monitoring system generally includes a circuit, wherein the circuit is initially in a first impedance state that is configured to change to a second impedance state due to pest activity, wherein the second impedance state is lower than the first impedance state.

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.

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.

The present invention relates to the use of near-field communication for retrieving and/or transmitting information to and/or from a rechargeable rodent trap, with a spring driven and/or gas pressure driven killing means to a handheld computer, such as a smartphone or tablet, wherein said information comprises data about the number of activations of said killing means, preferably time stamped, and identification number of said trap.

A path finding system using a series of networked receiver beacons is disclosed. The system includes receiver beacons placed on a path. Each of the receiver beacons include a transceiver receiving and sending signals and a location indicator such as a LED, that when activated indicates the location of the receiver beacon. Each of the receiver beacons include a controller coupled to the indicator and the transceiver. The controller is operable to receive an activation signal to activate the indicator. A transmitter is paired with each of the receiver beacons. The transmitter includes a transceiver to send an activation signal to at least one of the receiver beacons. The receiver beacon receives the activation signal and activates the indicator. The receiver beacon also relays the activation signal to at least another receiver beacon.

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 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.

A smart micro-mouse trap is disclosed herein which can be used to trap and kill the mouse, rat, rodent, etc. instantly. The embodiment comprises an enclosure for the mouse, a beam to detect the mouse, a trap, a latch and a solenoid powered by an electrical circuit to activate the tripping mechanism as the mouse enters the trap and breaks the beam. The smart micro-mouse trap is advantageous and useful as it is inexpensive, easy to operate, durable and allows for sanitary disposal of the dead mice, rats, rodents without contact to human.

A smart micro-mouse trap is disclosed herein which can be used to trap and kill the mouse, rat, rodent, etc. instantly. The embodiment comprises an enclosure for the mouse, a beam to detect the mouse, a trap, a latch, and a solenoid powered by an electrical circuit to activate the tripping mechanism as the mouse enters the trap and breaks the beam. The smart micro-mouse trap is advantageous and useful as it is inexpensive, easy to operate, durable and allows for sanitary disposal of the dead mice, rats, rodents without contact to human.

A pest deterrent system is provided. The pest deterrent system includes a sensor module and an actuator module. The sensor module includes a first housing, a sensor, and a controller. The sensor is positioned within the first housing and proximate to the view window such that the sensor is in visual communication with the view window and configured to detect objects outside of the first housing. The controller is positioned within the first housing and is operatively coupled to the sensor. The controller is configured to receive a signal from the sensor, such as an alert that an object is near the sensor module. The actuator module includes a second housing separate from the first housing, an actuator, and a second controller. The second controller configured to receive a signal from the first controller to actuate the actuator in response to the sensor being triggered.