In certain embodiments, a system includes a front wall, a rear wall positioned substantially parallel to the front wall, and first and second side walls each extending between the front wall and the rear wall. The first side wall includes a gate, and the second side wall is spaced apart from the first side wall such that the front wall, the rear wall, the first side wall, and the second side wall define a milking box stall of a size sufficient to accommodate a dairy livestock. The system includes an equipment portion located adjacent to the rear wall. The equipment portion houses a robotic attacher configured to extend between the rear legs of a dairy livestock located within the milking box stall in order to attach milking equipment to the dairy livestock.

A method of operating a robotic attacher, includes suspending a robotic attacher from a rail and extending the robotic attacher between the legs of a dairy livestock. The method continues by 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 concludes by 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 robotic attacher retrieves cups from the left side of an equipment area located behind a dairy livestock and attaches the cups to the teats of the dairy livestock in sequence. The sequence comprises attaching a first cup to the left front teat, a second cup to the right front teat, a third cup to the left rear teat, and a fourth cup to the right rear teat.

A system includes a robotic arm on which at least one camera is attached. It further includes a memory and a controller communicatively coupled to the memory. The memory stores historical information associated with a dairy livestock. The historical information include a previously-determined location of a teat of the dairy livestock. The controller moves the camera on the robotic arm toward the previously-determined location of the teat. The camera generates an image of the teat of the dairy livestock from a position to which it is moved, and the controller determines a current location of the teat of the dairy livestock based at least in part on the image.

A system includes a milking stall to accommodate a dairy livestock and a robotic attacher. The robotic attacher extends under the dairy livestock and comprises a nozzle. The robotic attacher is operable to rotate such that, during a first operation, the nozzle is positioned generally on the bottom of the robotic attacher, and during a second operation, the nozzle is positioned generally on the top of the robotic attacher.

A robotic attacher comprises a gripping portion, a vision system positioned on a first surface of the gripping portion, and at least one nozzle positioned on a second surface of the gripping portion. The gripping portion is rotates about a longitudinal axis such that during a first time, the vision system is positioned generally on the top of the gripping portion, and during a second time, the nozzle is positioned generally on the top of the gripping portion.

A method comprises extending a robotic attacher under a dairy livestock positioned in a milking stall, wherein the robotic attacher comprises a nozzle that is positioned generally on the bottom of the robotic attacher during a first operation. The method further comprises rotating the robotic attacher during a second operation such that the nozzle is positioned generally on the top of the robotic attacher.

A system comprises a memory and a processor. The memory stores information about a milking stall where a dairy livestock is located at a first time, and a coordinate location of the dairy livestock at a second time. The processor is communicatively coupled to the memory and determines if the coordinate location of the dairy livestock at the second time is different than the milking stall where the dairy livestock is located at the first time. If the coordinate location where the dairy livestock is located at the second time is not the milking stall, the processor generates an error flag associated with the dairy livestock.

A system comprises a memory and a processor. The memory stores information about a milking stall where a dairy livestock is located at a first time, and a coordinate location of the dairy livestock at a second time. The processor is communicatively coupled to the memory and determines if the coordinate location of the dairy livestock at the second time is different than the milking stall where the dairy livestock is located at the first time. If the coordinate location where the dairy livestock is located at the second time is not the milking stall, the processor generates an error flag associated with the dairy livestock.

A milking robot comprises a robotic arm, a camera coupled to the robotic arm, a camera-facing nozzle coupled to the robotic arm, and a controller. The robotic arm extends in a longitudinal direction between the hind legs and from the rear of a dairy livestock located in a milking stall. The camera-facing nozzle sprays a protective layer of the camera with a cleanser. The controller communicates a signal instructing the camera-facing nozzle to spray the camera with cleanser.