Systems and methods for effectively repelling pest animals (e.g., birds), including drones that adopt complex deterrent strategies (e.g., cooperative strategies), establishing a fuzzy boundary for a geofenced area and altering pest deterrent device flight patterns based on the characteristics of the fuzzy boundaries. Deterrence strategies can be selected based on the type of pest animals, and new deterrence strategies can be generated based on outcome feedback from previous strategies (e.g., combining aspects of preexisting deterrence strategies by utilizing an AI system). Drones can be automatically maintained by comparing current drone operational status with a predetermined threshold level. A maintenance robot (e.g., a drone) can autonomously rescues a working robot (e.g., another drone) that is in trouble.

Systems and methods for effectively repelling pest animals (e.g., birds), including drones that adopt complex deterrent strategies (e.g., cooperative strategies), establishing a fuzzy boundary for a geofenced area and altering pest deterrent device flight patterns based on the characteristics of the fuzzy boundaries. Deterrence strategies can be selected based on the type of pest animals, and new deterrence strategies can be generated based on outcome feedback from previous strategies (e.g., combining aspects of preexisting deterrence strategies by utilizing an AI system). Drones can be automatically maintained by comparing current drone operational status with a predetermined threshold level. A maintenance robot (e.g., a drone) can autonomously rescues a working robot (e.g., another drone) that is in trouble.

A scarecrow including a scarecrow body corresponding generally in shape to a body of a live animal; and a scarecrow head corresponding in shape to a head of a live animal; and an unstable mount disposed between the scarecrow body and the scarecrow head onto which the scarecrow head is rotatably mounted for 360-degree movement of the scarecrow head to the scarecrow body without interfering with free movement of the scarecrow head. The unstable mount includes a lower pivot assembly rigidly connected to the scarecrow body and an upper pivot assembly rigidly connected to the scarecrow head and balanced onto the lower pivot assembly, the lower pivot assembly being of two-piece molded plastic construction and including a foot and an upper member that press-fit together, with the foot configured to press-fit install into the scarecrow body.

A scarecrow including a scarecrow body corresponding generally in shape to a body of a live animal; and a scarecrow head corresponding in shape to a head of a live animal; and an unstable mount disposed between the scarecrow body and the scarecrow head onto which the scarecrow head is rotatably mounted for 360-degree movement of the scarecrow head to the scarecrow body without interfering with free movement of the scarecrow head. The unstable mount includes a lower pivot assembly rigidly connected to the scarecrow body and an upper pivot assembly rigidly connected to the scarecrow head and balanced onto the lower pivot assembly, the lower pivot assembly being of two-piece molded plastic construction and including a foot and an upper member that press-fit together, with the foot configured to press-fit install into the scarecrow body.

A water animal deterrent is disclosed herein. The water animal deterrent includes an animatronic spider having moving legs, multiple lights, Bluetooth speakers, and motion detectors, where the device is powered by a rechargeable battery and solar panels. The water animal deterrent is placed near a swimming pool to protect the pool against various vermin that may come into contact and contaminate the pool. The motion detectors of the water animal deterrent detect the presence of any vermin that walks by a swimming pool. If vermin are detected, the legs of the animatronic body begin to move, and the lights begin to illuminate. As a result, the vermin in the vicinity of the swimming pool are scared away. The water animal deterrent further includes a Bluetooth speaker to facilitate a noise to scare the vermin away. The speaker may also be used for entertainment purposes.

Methods, systems and apparatuses are disclosed for attracting and/or repelling animals, more particularly methods systems and apparatuses for deploying and retrieving decoys, such as, for example, waterfowl decoy displays typically used in hunting, and particularly to attract overflying waterfowl.

Methods, systems and apparatuses are disclosed for attracting and/or repelling animals, more particularly methods systems and apparatuses for deploying and retrieving decoys, such as, for example, waterfowl decoy displays typically used in hunting, and particularly to attract overflying waterfowl.

An inflatable device, having an air flow path having a circumference and including an air diverter comprising a central motor receiver and a plurality of air deflectors extending radially from the motor receiver and located to define a plurality of air flow chambers surrounding the motor receiver; a motor mounted within the central motor receiver and having an output shaft rotatable by the motor and extending below the air diverter, the motor generating heat during use of the motor; a fan connected to the output shaft of the motor and located below the air diverter for rotating in response to rotation of the output shaft by the motor to generate a flow of air, the air diverter cooperating with the flow of air generated by the fan to create a turbulent air flow directed to flow through the air flow chambers and past the motor, the flow of air providing cooling to dissipate heat from the motor; and an inflatable body in flow communication with the air flow path and located above the air diverter for receiving the turbulent air flow. The inflatable body undulates in response to receiving the turbulent air flow.

An inflatable device, having an air flow path having a circumference and including an air diverter comprising a central motor receiver and a plurality of air deflectors extending radially from the motor receiver and located to define a plurality of air flow chambers surrounding the motor receiver; a motor mounted within the central motor receiver and having an output shaft rotatable by the motor and extending below the air diverter, the motor generating heat during use of the motor; a fan connected to the output shaft of the motor and located below the air diverter for rotating in response to rotation of the output shaft by the motor to generate a flow of air, the air diverter cooperating with the flow of air generated by the fan to create a turbulent air flow directed to flow through the air flow chambers and past the motor, the flow of air providing cooling to dissipate heat from the motor; and an inflatable body in flow communication with the air flow path and located above the air diverter for receiving the turbulent air flow. The inflatable body undulates in response to receiving the turbulent air flow.

Ultraviolet (UV) absorbing inks and films for surfaces such as glass and/or plastic are provided that include patterns visible to avian eyes, but invisible to a human at least ten feet away. Such invention is aimed at reducing the number of window strikes that result in bird deaths. A formulation may include a binder, a carrier. A formulation may include a base configured to dissolve and solubilize the binder such that it can be applied to the carrier. A formulation may include at least one of an ultraviolet (UV)/visible (VIS) absorbing (UAC) component and a UV/VIS reflective (URC) component.