A method for converting a conventional manually monitored capture-and-release rodent trap of a type having a box-shaped container with opposed one-way entry corridors communicating with a capture chamber into a remotely-monitored rodent trap. In one aspect, the method includes attaching a smart-sensor to the lid of the trap and press-fitting a bracket having a rodent opening into the space between the one-way entry corridors such that the rodent opening in the bracket restricts movement of a rodent into the capture chamber to a pathway in sufficient proximity for detection by the smart-sensor and signaling to a remote monitoring location.

A mouse trap including a frame, a first trapping member, a second trapping member, and actuator means for causing the first and second trapping members to move from an open position to a closed position. The first and second trapping members are pivotable such that they each pivot horizontally in an arc towards each other from the open position to the closed position. The first and second trapping members are configured to trap a mouse when the first and second trapping members are in the closed position.

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 VOCs”—VOCs emitted independently of the support on which the insects develop and emitted only in an insect infestation VOCs, “category 2 VOCs”—VOCs emitted independently of the support but may have biological origins other than insects, and “category 3 VOCs”—VOCs 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.

An electronic apparatus and a method are provided for detection of animal intrusions and control of a repellent mechanism to prevent such intrusions. The electronic apparatus controls an image-capture device to acquire an image of a house yard and selects a set of zones in the acquired image based on a user-specified setting. The electronic apparatus detects an animal in the acquired image and controls the repellent mechanism based on a determination that the detected animal is in a zone which is among the selected set of zones, to target the detected animal.

An animal trap stabilizing system includes a body trap having a pair of jaws, a trigger engaging the jaws, and a torsion spring being attached to the jaws. The torsion spring is engaged with a plate. The plate has a top side, a bottom side, a first edge, a second edge, a third edge, and a fourth edge. The torsion spring includes a plurality of loops. The loops are attached to the plate such that arms of the torsion spring extend away from the fourth edge. The third edge is positioned on a ground surface such that an animal receiving orifice of the body trap is vertically orientated.

A mouse trap is disclosed comprising a jar that is attached to a housing and includes a plastic bag inside. The housing and jar include a mouse entrance that leads inside the plastic bag, which is intended to include some bait at a distal end to lure the mouse into the jar. The trap includes a pressure or motion detector that senses when a mouse has entered the jar. The trap includes a solenoid that triggers a spring loaded hollow rod to close the jar when the mouse enters, and actuates a vacuum that removes the air from the plastic bag with the mouse inside. The removal of oxygen from the bag causes the mouse to lose consciousness, and eventually suffocate in its sleep. Once the mouse is dead, the bag can be removed and replaced.

A system for detecting the presence of pests. In one aspect the system comprises an imaging system including: a housing including one or more pest entrances; a pest attractant arranged within the housing; a pest detection surface; an image capture device, said image capture device being configured to capture one or more images of the pest detection surface; and a triggering sensor arrangement for detecting a target pest that is on or about to enter the pest detection surface, said triggering sensor arrangement being configured to provide a trigger-signal if the presence of an object is detected, the image capture device being configured to take an image of the pest detection surface in response to the trigger-signal.

A rodent trap including a housing, an inner channel, a spring-loaded killing mechanism including at least one spring and at least one striker plate, a reloader, a trigger mechanism, and a bait. The housing includes an opening into the inner channel and one or more sensors arranged at/in the inner channel and/or the opening for triggering the trigger mechanism if a rodent is detected. The striker plate is configured to move between two positions by means of the spring, a first position in which at least a part of the striker plate is arranged at a first side of the inner channel and/or opening leaving the inner channel and/or opening open for passage.

A sound detector system has one or more microphone positioned with a field of regard of 360°. The system further has a processor to translate a sound into data indicative of a direction and transmit the data indicative of direction. Additionally, the system has a handheld device configured to wirelessly receive the data indicative of the direction and display data identifying the field of direction to a user.

An animal trap system includes a glue board, an animal trap accelerometer sensor, and a signal unit in close proximity to and in communications with the animal trap accelerometer sensor, wherein the signal unit also contains an accelerometer sensor. The animal trap system is capable of detecting capture events, non-capture events, false positives, and/or the type of animal captured by using differential signal analysis and machine learning techniques. When an acceleration is received by the animal trap accelerometer sensor above a pre-set acceleration threshold value, it sends a capture signal to the signal unit and if the signal unit does not receive such acceleration event, the signal unit transmits a capture signal to an off-site receiver. A method of trapping one or more animals using this system is also provided.