The present disclosure describes a system which is able to detect and recognize wildlife, and in particular birds, using camera images. The present solution is comprised of algorithms, software and integrated hardware devices. Properly equipped, the system can be made to be portable and can be set up at any location for different wildlife detection and repelling purposes.

The present invention relates to an intelligent rodent management system which provide efficient, reliable, and effective system which traps the rodents or animals and manages disposal process from a remote location. The intelligent rodent management system is water resistant, which can effectively catch water borne rodents as well. The bait is placed on top part of the main body and the bait station is closed with a bait cap, the smell of the bait lures the animals from the entrance of the main body. The animals enter through the main body of the device wherein the door is operated through spring loaded mechanism. The intelligent rodent management system of present invention provides a collecting, communicating and analyzing system for received information about entry of animals and the data is stored on a cloud server through electronics hardware which consist of a modem and a processor.

A precast dam structure includes at least two precast segments coupled together via linkages and a flow path structure. The flow path structure defines a flow path having an intake port and a draft port and is associated with at least one of the at least two precast segments. The flow path structure is configured to provide a change in flow direction, either internally or externally, from the at least one of the at least two precast segments.

A rodent trap having a remote arming capability and a method of deploying a rodent trap in an unarmed state and then arming the trap after a wait period without the user having to again physically access the trap. The trap, preferably embodied as an electronic rodent trap, may be configured with wireless remote arming capability, timed arming functionality, activity based arming and the like. When in the unarmed state, the trap operates in a monitoring mode in which the trap can monitor and evaluate activity and/or interactions with the trap and can send and receive wireless communication signals.

This disclosure describes devices, systems, and methods associated with pest (e.g., rodent) management. An example of a pest-management apparatus includes a detector device having a housing, a magnetic switch coupled to the housing, and circuitry disposed within a cavity of the housing. The detector device is configured to be coupled to a trap having a base and a capture element pivotally coupled to the base such a portion of the capture element is biased toward a capture portion of the base. The circuitry is configured to detect operation of the trap based on a change in state of the magnetic switch responsive to a magnet coupled to the trap. In a particular implementation, the detector device is coupled to the trap via a platform. In another particular implementation, the detector device includes multiple magnetic switches and is configured to concurrently be coupled to multiple traps.

An automated system for mitigating risk from a wind turbine includes a plurality of optical imaging sensors. A controller receives and analyzes images from the optical imaging sensors to automatically send a signal to curtail operation of the wind turbine to a predetermined risk mitigating level when the controller determines from images received from the optical imaging sensors that an airborne animal is at risk from the wind turbine.

Animal sensing systems and methods are described. An animal sensing system can include an input section with an entrance and an output section having at least two output paths each having its own exit. An animal can enter the animal sensing system through the entrance. A sensor within a sensing area of the input section can detect one or more characteristics of the animal, and can communicate the detected characteristic(s) to a central processing unit. The central processing unit can use the received data to classify the animal based on the detected characteristic(s), and then control a directional guide, such as a gate, in the animal sensing system on the basis of the classification, so as to direct the animal within the animal sensing system, such as to allow access to only one of the output paths at a time. The animal may thus be allowed to exit the animal sensing system through only one output path, directing the animal to a desired location based on the classification.

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.

In some examples, a trap to electrocute a pest may include a logic board. The logic board may create an open circuit using two electrical contacts in touch with two conductive plates in a container located in the trap. A pest entering the container may touch the two conductive plates, causing the circuit to close. Based on determining that the circuit was closed, the logic board may determine that a pest entered the trap. The logic board may cause a shutter inside the trap to move from an approximately horizontal position to an approximately vertical position, thereby causing a portion of a door of the container to close by causing two latch strikes of the door to engage with the two jaws of the container. The circuit may send a wireless notification message, indicating that the pest was captured in the container, over a wireless network to a computing device.

The disclosure relates to an apparatus and a system for testing the cognitive ability of a rodent, comprising a testing chamber, a retarding zone connected to the entrance chamber and including at least one obstacle configured to slow down the rodent's movement to the entrance chamber, and an optional transfer chamber connected to the entrance chamber via the retarding zone for transfer of the rodent to and from an area external to the apparatus. The testing chamber comprises an entrance chamber, a plurality of corridors each connected to the entrance chamber via a corridor's first end portion, and at least one odor diffuser for diffusing odors in the plurality of corridors.