Systems and methods for improving the health and wellbeing of subjects in an industrial setting are disclosed. The systems may include a camera arranged so as to observe one or more features of a subject, and a processor, coupled to the camera, the processor configured to analyze one or more images obtained therefrom, to extract one or more features from the image(s) of the subject, and to analyze one or more of the features, or sub features nested therein to predict an outcome of a state of the subject. In particular the system may be configured to generate a diagnostic signal (e.g. an outcome, fever, mastitis, virus, bacterial infection, rut, etc.) based upon the analysis.

A system includes an equipment portion and a plurality of milking box stalls arranged adjacent to the equipment portion. Each of the milking box stalls is of a size sufficient to accommodate a dairy livestock. The system further includes a robotic attacher housed in the equipment portion and configured to service each of the plurality of milking box stalls at different times. The robotic attacher has a gripping portion with a spray nozzle. The gripping portion is operable to rotate around a longitudinal axis such that during a milking operation the spray nozzle is positioned on the bottom of the gripping portion, and after the milking operation the spray nozzle is positioned on the top of the gripping portion.

A system comprising a robotic arm, a plurality of grabbers, a sensor, and a preparation cup. The robotic arm has a first end and a recessed portion. The grabbers are coupled to the robotic arm at the first end. The sensor is positioned inside the recessed portion of the robotic arm at a first distance from the first end and at a first angle. The preparation cup is coupled to wings having a body portion, a first extended portion, and a second extended portion. The body portion is coupled to a portion of the preparation cup, the first extended portion extends in a first direction and the second extended portion extends in a second direction. The wings are operable to be magnetically coupled to the plurality of grabbers via the first and second extended portions.

A milking robot comprises a movable arm having a length in a longitudinal direction, and at least one gripper swivably mounted to the movable arm such that it moves between a first position parallel to the movable arm's longitudinal direction and a second position at which the gripper extends sideways in a horizontal plane away from the movable arm's longitudinal direction.

A method of operating a robotic attacher, comprises extending a robotic attacher between the legs of a dairy livestock. The method further comprises attaching milking equipment to the dairy livestock using a gripping portion of the robotic attacher during a milking operation, wherein the gripping portion has a nozzle that is positioned away from a teat of the dairy livestock during the milking operation. The method further comprises rotating the gripping portion of the robotic attacher so that the nozzle is positioned to face a teat of the dairy livestock during a spraying operation.

A system and method for treating livestock may include a ramp for containing dairy livestock and one or more mobile units configured to travel on the ramp, below the dairy livestock, and perform at least one action related to a treatment of the livestock. A mobile unit may be adapted to travel to a predefined location within a stall, and attach a milking equipment unit to a cow in the stall. A plurality of mobile units and a central management unit may be configured to dynamically cause at least some of the plurality of mobile units to each perform a portion of a treatment or task.

A system includes a robotic arm, a laser, and a processor. The processor is configured to determine whether a distance between a left and right teat of a dairy livestock is less than or equal to a predetermined distance, and if so, command the robotic arm to move to a scan location that is between the left and right teats. The processor is further configured to command the laser to perform a scan of the teats after the robotic arm is at the scan location and to determine whether the left and right teats are found in the scan. If both the left and right teats are found in the scan, the processor commands the robotic arm to attach a teat cup to either the left or right teat.

A system includes a robotic arm, a laser, and a processor. The processor is configured to command the robotic arm to move to a location of an expected teat position of a dairy livestock and to command the laser to perform two scans of the dairy livestock. The processor is further configured to determine whether a first teat is found in both of the scans, and if so, determine whether locations of the first teat in the two scans are within a predetermined distance of each other. The processor is further configured to, in response to determining that locations of the first teat in the two scans are within the predetermined distance of each other, command the robotic arm to move to a location corresponding to the location of the first teat and to command the robotic arm to attach a teat cup to the first teat.

A system includes a robotic arm, memory, and a processor. The processor is configured to access first and second success counters stored in the memory. The first success counter is associated with a first attach algorithm and the second success counter is associated with a second attach algorithm. The processor is further configured to determine whether the first success counter is greater than the second success counter. The processor is further configured to execute the first attach algorithm if the first success counter is greater than the second success counter, and to execute the second attach algorithm if the first success counter is not greater than the second success counter. The processor is further configured to increment the first success counter if the first attach algorithm is successful, and to increment the second success counter if the second attach algorithm is successful.

A system includes a robotic arm, a laser, and a processor. The processor is configured to command the robotic arm to move to a first location corresponding to an expected teat position of a first teat. The processor is further configured to determine whether the first teat is found in a first scan by the laser, and if so, command the robotic arm to move to a second location corresponding to the location in the scan. The processor is further configured to determine whether the first teat is found in a second scan by the laser, and if so, determine whether the first teat is within a predetermined distance from a current location of the robotic arm. If the first teat is within the predetermined distance from the current location of the robotic arm, the processor commands the robotic arm to attach a teat cup to the first teat.