Systems and methods for detecting udder disease based on machine learning methods and complementary supporting techniques are presented. Included are methods for assembling time sequences of images of each animal of a herd or set for subsequent use in per-animal image analysis for disease detection. Methods presented also include image pre-processing methods used prior to image analysis, resulting in contrast and resolution optimization such as appropriate image intensity level adjustment and resolution downsampling for more rapid and more accurate disease detection. Combinatorial techniques for compositing whole-udder images or udder-quarter images from partial images captures are described. Methods are provided for power usage optimization in regard to computing resources used in the computing-intensive AI analysis methods. Location-based and animal history-based detection refinements are incorporated into described systems. Further presented are methods for multi-modal and multi-factor detection of udder disease, as well as methods for infection type classification.

In a headlock system having a plurality of n headlock cells, each of the n cells being adapted to enclose at least one animal; n is an integer greater than 1; a system for locating the position of at least one animal, the system comprising: at least one identification means adapted to transmit at least one identification signal associated with said at least one animal; at least one locating means adapted to generate at least one location signal associated with said at least one animal; and, a data processing system in communication with said at least one identification means and said at least one locating means, adapted to analyze said signals, said analyzed signals comprising the position within a predetermined region in said headlock system of each of said at least one animals as a function of time.

In a headlock system having a plurality of n headlock cells, each of the n cells being adapted to enclose at least one animal; n is an integer greater than 1; a system for locating the position of at least one animal, the system comprising: at least one identification means adapted to transmit at least one identification signal associated with said at least one animal; at least one locating means adapted to generate at least one location signal associated with said at least one animal; and, a data processing system in communication with said at least one identification means and said at least one locating means, adapted to analyze said signals, said analyzed signals comprising the position within a predetermined region in said headlock system of each of said at least one animals as a function of time.

A milking system includes a milking device for milking a milking from a dairy animal. The system is provided with a control unit for the milking system, milking cups, a first milk jar for receiving the milking, a first pumping device for pumping the milking from the first milk jar to a first milk pipe, a second milk jar in flow communication with the first milk pipe for receiving the milking from the first milk jar, and a second pumping device for pumping the milking from the second milk jar into a second milk pipe. The first pumping device is configured to pump the milking at a first flow rate and the second pumping device is configured to pump the milking at a second flow rate, which is lower than the first flow rate. The milking system also includes a heat-exchanging system in flow communication with the second milk pipe.

A milking system includes one or more milking devices and a control unit. The system is provided with a plurality of milking cups, a first milk jar for receiving the milking, a first pumping device for pumping the milking, a second milk jar for receiving the milking from the first milk jar, a second pumping device for pumping at least a part of the milking, and at least one storage tank for storing at least a part of the milking. The second pumping device pumps the milking at a lower flow rate than that at which the first pumping device pumps the milking. As a result, the milk is for the most part moved with low mechanical load and little admixture with air which improves milk quality. In the case of a plurality of milking devices in the milking system, various milkings can be moved and treated separately.

An automatic milking installation controlled by a system including: a graphical user interface enabling user interaction with the automatic milking installation via at least one display view, an imaging unit recording image data representing at least one portion of a dairy animal, the imaging unit having a transparent cover surface configured to protect an optics section of the imaging unit and through which transparent cover surface the image data are recorded, and a control unit receiving the recorded image data, and based thereon, producing a control signal for controlling functions of the automatic milking installation. The control unit further processes the recorded image data to determine a parameter indicating an amount of dirt on the transparent cover surface, and generates graphics data for presentation to the user via the graphical user interface, which includes at least one graphical element reflecting the amount of dirt on the transparent cover surface.

An automatic milking installation controlled by a system including: a graphical user interface enabling user interaction with the automatic milking installation via at least one display view, an imaging unit recording image data representing at least one portion of a dairy animal, the imaging unit having a transparent cover surface configured to protect an optics section of the imaging unit and through which transparent cover surface the image data are recorded, and a control unit receiving the recorded image data, and based thereon, producing a control signal for controlling functions of the automatic milking installation. The control unit further processes the recorded image data to determine a parameter indicating an amount of dirt on the transparent cover surface, and generates graphics data for presentation to the user via the graphical user interface, which includes at least one graphical element reflecting the amount of dirt on the transparent cover surface.

A valve device that transitions between the pressure and vacuum phases for the purpose of milking animals. The improvement provides a pulsation output with a vacuum supply duration less than that of atmospheric air pressure supply duration.

A valve device that transitions between the pressure and vacuum phases for the purpose of milking animals. The improvement provides a pulsation output with a vacuum supply duration less than that of atmospheric air pressure supply duration.

A milk extracting system and computer-implemented method of adjusting the vacuum pressures applied respectively at different teat cups for milking the teats of an animal during a milk extraction procedure, where a teat-specific milk flow value is determined for each individual teat during the milk extraction, based on measurements received from respective milk flow meters, each determined teat specific milk flow value is compared with a first threshold limit, and when a determination is made that all of the teat specific milk flow values exceed the first threshold limit the vacuum pressure at each teat cup is adjusted to a high flow vacuum pressure level.