A system comprising a first transmitter for transmitting a first signal at a first frequency and a second transmitter for transmitting a second signal at a second frequency. The system includes a collar unit comprising a filter for receiving a combined signal, wherein the combined signal comprises the first signal and the second signal, wherein the filter includes a first antenna for detecting the first signal and a second antenna for detecting the second signal. The collar unit includes at least one signal analysis component configured to analyze the first signal and the second signal. The collar unit is configured to instruct a stimulus delivery unit to deliver a stimulus to the animal when the first signal voltage falls below a first value and the second signal voltage exceeds a second value.

An interactive system for monitoring health and movement of an animal has an elongated band adapted to encircle on a body part of an animal, a tracking chip to monitor movement of the animal within and outside of a geofence, a lock to provide an opening and closing of the elongated band, a means for health monitoring to collect a data set for a plurality of vital signs of the animal, and a user interface to notify a pet owner about the outside movement of the animal from the geofence. Further, the system enables the authorized users to log into the communicating device such as a computer or any other computing device and track the movement and view health information of the animal while it needed.

Embodiments of the disclosure provide an intelligent dog training apparatus and a control method thereof. The intelligent dot training apparatus includes a transmitter and receivers. In the disclosure, a single transmitter is adopted to collectively control one or multiple receivers, achieving effective control on multiple pets at the same time. Function buttons are locked through a lock button set in the transmitter to prevent incorrect operations. The vibration frequency and electric shock strength can be optionally adjusted, thereby facilitating use. Control states and power can be observed through a display screen, achieving high practicality.

The automatically detachable collar pendant system is structured so that when the system receives a signal, one end of the collar is released from the rest of the collar body, thereby unfastening the collar and allowing the collar to fall off of a target animal. The “signal” may comprise a magnetic or induction heat signal. In the preferred embodiment, the signal is received (and the collar is unfastened) when the target animal feeds at a specially-equipped bait station.

An obedience training pet leash and harness system includes a housing. A primary leash is coiled within the housing. The primary leash extends from an opening in the housing with a primary lead that is disposed on a distal end of the primary leash, outside of the housing. A handle is formed on the housing, as well as a clutch trigger. The clutch trigger is configured to restrain the primary leash when the clutch trigger is engaged by the user. The handle has a control center. The control center is designed to control a number of obedience modules. The obedience modules are installed on a harness. The harness is designed to be worn by a pet and is designed to be secured to the primary lead.

A dog training system is disclosed herein. The dog training system generally comprises a mobile device, a collar, and a treat dispenser. The mobile device has software installed on it that is capable of wirelessly operating the various functions of the collar and the treat dispenser. In many embodiments, the software, which is usually a dog training application installed on the mobile device, is capable of operating the functions of the collar and the treat dispenser automatically when certain pre-set parameters are met. This system may allow for simple, efficient, and effective dog training without much effort on the part of a dog owner or trainer.

A system for monitoring ruminant animal foraging that utilizes a piezoelectric film sensor in communication with a computer processor to record and characterize jaw movement data for the foraging ruminant animal. The processor applies pattern algorithms to categorize the jaw movement data so that the jaw movements are categorized as at least chewing, biting, ruminating, and/or idling.

A system, apparatus, and/or method of determining a health condition of an animal is provided. First data may be received from a first sensor device. The first data may be indicative of an animal event of an animal. Second data may be received from a second sensor device. The second sensor may be separate and/or distinct from the first sensor device. The second data may confirm an occurrence of the animal event. The animal event may be a discharge event and/or a feeding event. The occurrence of the animal event may be identified based on the first data and the second data. The occurrence of the animal event may be displayed via a display device. A health condition of the animal may be determined based on the animal event. The determination of the health condition may be based on a quantity and/or a duration of the animal event.

An animal training system includes a shock collar that may be worn around a neck of an animal. Thus, the shock collar is in electrical communication with the animal. The shock collar has a first transceiver. A control unit is provided and the control unit may be carried. The control unit is in communication with the shock collar. Thus, the control unit may determine a distance between the shock collar and the control unit. The control unit selectively actuates the shock collar when the shock collar moves beyond a pre-determined trigger distance from the control unit. Thus, the shock collar delivers an electric shock to the animal. The shock collar thusly informs the animal that the animal has moved beyond the pre-determined trigger distance from the control unit.

A system and method for monitoring the health of an animal using multiple sensors is described. The wearable device may include one or more sensors whose resultant signal levels may be analyzed in the wearable device or uploaded to a data management server for additional analysis. One or more embodiments include variations of the UWB system to accommodate differences in animals, such as scheduling or attempting transmissions between the wearable device and the data management server in such a way as to increase the likelihood of a successful transmission.