Approaches for synchronising electronic animal identification tag readers for reading electronic animal identification tags attached to animals Embodiments include using a pulse from a GNSS receiver, adjusting for an error between a reference cadence signal and a local cadence signal, and using a synchronisation signal.

The present disclosure discloses a pet retrieve device, including a housing subassembly which is a hollow cavity; a circuit board and a battery fixedly arranged in the housing subassembly; a positioning chip arranged on the circuit board; a button and a charging interface which are arranged on the circuit board and penetrates through the housing subassembly; a lamp strip arranged in the housing subassembly, light emitted by the lamp strip being transmitted through the housing subassembly; and a two-dimensional code arranged on a surface of the housing subassembly. A one-to-one correspondence webpage can be opened by scanning the two-dimensional code, and the webpage displays preset pet information. The present disclosure discloses a pet retrieve method. The present disclosure can increase the possibility of retrieving a pet to a certain extent.

An antenna module is described for configuring a mobile device, e.g., a smartphone, to locate an animal wearing a radiofrequency (RF) transmitter, the module having a directional antenna structure, the antenna structure including a plurality of antenna elements configured to generate a directional radiation field; at least one RF receiver connected to the directional antenna structure; and, a controller configured to control the RF transceiver and a mobile device interface for providing communication with the mobile device, the controller being configured to execute the steps of: receiving one or more time series of beacons signals broadcasted by the RF transmitter that is within the directional radiation field of the directional antenna structure; determining distance estimates for beacon signals in the one or more time series, a distance estimate being determined by the antenna module on the basis of a signal strength and/or a signal quality of a detected beacon signal.

A system that includes at least one processor and a non-transitory, tangible memory device having programming instructions. When the instructions are executed by the at least one processor, the at least one processor receives from a set of sensors at least one biological parameter of an animal in a walk-in analysis zone to create real-time biological. The at least one processor analyzes the real-time biological data from the walk-in analysis zone and recommends animal feed nutrients based on the analyzed real-time biological data. The at least one processor communicates the recommended animal feed nutrients to at least one of: a mobile communication device; and a display device in proximity to the walk-in analysis zone.

An agricultural data collection framework is provided in a system and method for tracking and managing livestock, and for analyzing animal conditions such as health, growth, nutrition, and behavior. The framework uses ultra-high frequency interrogation of RFID tags to collect individual animal data across multiple geographical locations, and incorporates artificial intelligence techniques to develop machine learning base models for statistical process controls around each animal for evaluating the animal condition. The framework provides a determination of normality at an individual animal basis or for a specific location, and generates alerts, predictions, and a targeted processing or application schedule for prioritizing and delivering resources when intervention is needed.

An animal tracking system comprising a first LoRa receiver configured as a gateway to receive transmissions on a first set of channels or a second set of channels and forward said transmissions to a first remote server, and a transmitting tag configured to be affixed to an animal. The transmitting tag includes a memory configured to store digital information, a passive RFID receiver configured to detect a close proximity to an RFID transmitter and store detection of the close proximity in comprising in the memory, a processor configured to determine an alarm status according to a frequency of detection of the close proximity, an internal energy source, and a LoRa transmitter configured to transmit signals for a distance greater than 100 meters via energy from the internal energy source.

Systems and methods for monitoring an animal include receiving a plurality of biological parameters of the animal from a plurality of biological sensors, receiving location parameters of the animal from at least one location sensor, receiving weather parameters corresponding to ambient weather conditions proximate the animal from at least one ambient weather sensor, and comparing at least one of the parameters generated by the sensors with data representing at least one signature corresponding to the animal to determine if there is an irregular parameter. In response to an irregular reading/parameter being identified, then determining if the identified irregular parameter is related to a health condition of the animal and if the identified irregular parameter is not related to the health condition of the animal, then determining if the identified irregular parameter is related to an illegal activity.

Systems and techniques are described for pet monitoring during unattended delivery. In some implementations, a monitoring system monitors a property includes sensors located throughout the property and generates sensor data. A monitor control unit receives a first indication that a resident of the property will be receiving a delivery during a delivery time. Based on the sensor data and during the delivery time, the monitor control unit determines that a pet, that resides at the property, has been restrained. The monitor control unit provides, to a delivery person, a second indication that the pet at the property has been restrained.

A method for controlling a stimulus apparatus configured to be worn by an animal, the stimulus apparatus comprising a controller interfaced with a location sensor and at least one stimulus output for providing a stimulus to the animal, the method comprising: receiving a boundary specification and monitoring the location of the stimulus apparatus with respect to the boundary defined by the boundary specification; determining an expanded boundary; identifying a transition condition including a transition zone, the transition zone comprising at least a portion of the expanded boundary; monitoring the location of the stimulus apparatus; determining that the location of the stimulus apparatus is within the transition zone; in response, reducing the size of the boundary such that the boundary includes the transition zone and excludes at least a portion of the boundary before expansion, and associated system and device.

The present invention relates to a navigational safety system for visually impaired quadrupeds. An onlay has a right side, a left side, a top side, a bottom side, and a chest side. The onlay is retrofittable to or manufactured into a harness worn by a quadruped. Distance sensors and vibrators are integrated into the onlay and configured to determine the distance between obstacles and provide localized vibration stimulation to the quadruped. The vibration causes the quadruped to change course avoiding the obstacle. In this regard, the localized vibrations are positioned on the right torso, the left torso, and the chest of the quadruped.