This document relates to a method for determining in a young animal a phase transition from a first development phase to a second development phase. The method comprises measuring, with a measuring instrument, one or more body or behavior parameters of the animal during a period of time and producing one or more measuring values for the or each measured body or behavior parameter. The one or more measuring values are received by a controller with which the phase transition is detected on the basis of the measuring values. The step of detecting the phase transition comprises processing the measuring values and, depending thereon, determining an extent of the animal's attention to solid food. Further, the document relates to the training of a self-learning data processing model, and to a livestock management system.

Computer-implemented methods, systems and computer program products leveraging cognitive learning, and machine learning algorithms to predictively identify and monitor animals within a monitoring zone in real-time and identify an occurrence of unwanted or unsafe behaviors being performed by the animals. Surveillance systems and sensors within a monitoring zone or affixed to the animals provide audio/visual data and sensor data describing activity and animals within the monitoring zone. Machine learning models are trained using audio-visual, sensor and historical data to learn to predict the identities of registered animals based on the sight or sound of the animals. Behaviors of animals that are unsafe and should be corrected can be remediated, minimized or altered using IoT devices positioned within the monitoring zone perform pre-determined actions initiated automatically in response to identification of unsafe behaviors or upon verification by users of the occurrence of the unsafe events or conditions within the monitoring zone.

Tools for smart farming, including devices, management systems and methods of livestock management are provided.

A method and system for the continuous monitoring of animal physiology and behavior through the use of a smart body worn animal harness, smart collar or restraint system which captures, pre-processes, monitors, and transmits data captured from a plurality of externally-based, skin contact-based, and internally located RFID implants to a cloud-based infrastructure for further processing and augmentation to support real time alerting and animal health analytical systems.

Disclosed herein is an RFID tag insertion cartridge comprising a hollow needle in which an RFID tag is disposed. The cartridge comprises an optional housing in the form of a shell that is shown transparently. The cartridge comprises a carriage that is movably mounted and to which the hollow needle is attached for withdrawing the needle. Also disclosed herein is a RFID tag insertion tool.

A system and method for automatically matching a sensor device attached to an animal with an ID tag attached to the animal, wherein a handheld reader device triggers transmission of sensor device information from the sensor device and triggers transmission of ID information from the ID tag, and a monitoring device, in communication with the handheld reader device, is configured to determine and record that the ID tag and the sensor device are attached to a same animal based on time information associated with both the ID information transmitted from the ID tag and the sensor device information transmitted from the sensor device.

The invention relates to a detection label provided with a passive resonant circuit which is configured to emit an identification code when the passive resonant circuit is introduced into a first electromagnetic interrogation field, wherein the label is further provided with a memory and an active circuit comprising a transmitter and a receiver, wherein the active circuit is configured to emit information which is stored in the memory with the transmitter when the active circuit is introduced into a second electromagnetic interrogation field comprising a first predetermined code, which second electromagnetic interrogation field is received with the receiver, characterized in that the label is configured, in response to the receiving of the second interrogation field, when the second interrogation field comprises a second predetermined code, to adjust a status of the label such that the passive resonant circuit does not emit the identification code when the passive resonant circuit is introduced into the first electromagnetic interrogation field.

An improved passive RFID tag configured for needle implantation in a tail of a rodent using a small diameter needle provides for increased read distances and effectiveness. In various embodiments, the RFID tag is comprised of an elongated flexible substrate having a pair of opposed surfaces with a UHF RFID chip positioned on a first of the opposed surfaces and is directly electrically connected to a closed-loop multi-layer folded dipole antenna disposed on both of the opposed surfaces of the substrate. An antenna is electrically connected to the RFID chip and includes at least an inductor as part of the closed-loop antenna. In embodiments, the RFID tag can be read with at least 90 percent effectiveness by a 30 dB RFID tag reader at least 5 cm from a tail of the rodent.

In a configuration, a protective enclosure for an animal and method of making is disclosed. The protective enclosure may include a floor system and a plurality of wall systems that may define an internal portion of the protective enclosure. A first electrical heating element may be disposed within the floor system or one of the wall systems. At least one wall electrical heating element may be disposed within the at least one wall system of the plurality of wall systems. The first electrical heating element and the at least one wall electrical heating element may be powered by electricity and may be configured to direct heat inwardly from the floor system or the at least one wall system to increase temperature inside the internal portion of the protective enclosure.

A mobile and modular device with movable walls for the dynamic weighing of a bovine animal includes an identification module having a support structure, a processing module, a solar panel, an antenna and an identifier; and a weighing module including a base, a pair of side walls, a weighing platform, a pair of load cells and an amplifier and transmission box. The processing module, the identifier, the solar panel and the antenna are associated on the support structure. The weighing platform, the pair of load cells and the amplifier and transmission box are associated on the base in a fixed way. Each one of the pair of side walls contains a fixed portion and a mobile portion; and each one of the lower ends of the fixed portion contains a mechanism, which is associated to the base in a mobile way, through a first distal end and a second distal end.