A system includes a three-dimensional camera and a processor communicatively coupled to the three-dimensional camera. The processor is operable to determine a first and second edge of a dairy livestock. The first edge includes an inner portion of a first hind leg and a first portion of an udder of the dairy livestock. The second edge includes an inner portion of a second hind leg and a second portion of the udder of the dairy livestock. The processor calculates a reference point associated with the udder of the dairy livestock based at least in part upon the first edge and the second edge. A robotic attacher moves toward the udder of the dairy livestock based at least in part upon the calculated reference point.

A system includes a three-dimensional camera and a processor communicatively coupled to the three-dimensional camera. The processor is operable to determine a first and second edge of a dairy livestock. The first edge includes an inner portion of a first hind leg and a first portion of an udder of the dairy livestock. The second edge includes an inner portion of a second hind leg and a second portion of the udder of the dairy livestock. The processor calculates a reference point associated with the udder of the dairy livestock based at least in part upon the first edge and the second edge. A robotic attacher moves toward the udder of the dairy livestock based at least in part upon the calculated reference point.

A system for managing a group of dairy animals includes a dwelling space, such as an animal shed, in which the dairy animals can roam. A dairy animal-related device for performing a dairy animal-related operation is arranged in the dwelling space. The dairy animals in the dwelling space can walk to the dairy animal-related device through the dwelling space. A luring system includes luring devices, each of which is attached to in each case one of the dairy animals. The luring device of each dairy animal is activatable in order to give said dairy animal a luring signal so as to lure said dairy animal to the dairy animal-related device. A detection system is configured for detecting the position of each individual dairy animal in the dwelling space. The luring system is connected to the detection system for receiving the positions of the dairy animals in the dwelling space detected by the detection system. On the basis of the received detected positions of the dairy animals in the dwelling space, the number of dairy animals is determined which are situated in a predetermined area of the dwelling space adjacent to the dairy animal-related device. The luring system activates the luring device of one of the other dairy animals depending on said number of dairy animals situated in said area.

A system for managing a group of dairy animals includes a dwelling space, such as an animal shed, in which the dairy animals can roam. A dairy animal-related device for performing a dairy animal-related operation is arranged in the dwelling space. The dairy animals in the dwelling space can walk to the dairy animal-related device through the dwelling space. A luring system includes luring devices, each of which is attached to in each case one of the dairy animals. The luring device of each dairy animal is activatable in order to give said dairy animal a luring signal so as to lure said dairy animal to the dairy animal-related device. A detection system is configured for detecting the position of each individual dairy animal in the dwelling space. The luring system is connected to the detection system for receiving the positions of the dairy animals in the dwelling space detected by the detection system. On the basis of the received detected positions of the dairy animals in the dwelling space, the number of dairy animals is determined which are situated in a predetermined area of the dwelling space adjacent to the dairy animal-related device. The luring system activates the luring device of one of the other dairy animals depending on said number of dairy animals situated in said area.

A space divider (4) of a milking parlor arrangement for at least one milking parlor (3) for milking milk-producing animals (T), wherein the space divider (4) is arranged approximately parallel to a longitudinal axis of the animal (T) to be milked, has an arm device (6) having a milking cluster (5, 5′), which can be adjusted from a parking position to a working position and back. The arm device (6) is arranged with the milking cluster (5) in the parking position in the space divider (4), wherein the milking cluster (5, 5′) can be adjusted into the working position laterally to the animal (T) to be milked between the front and rear legs thereof. The milking cluster (5, 5′) comprises two halves, wherein each half has a specific set of at least one teatcup (5a). The space divider (4) is designed in such a way that no additional space is required between adjacent animals (T), so that many animals (T) can be milked in a milking parlor arrangement (1, 1′, 1″) while the smallest possible amount of space is required. A milking parlor arrangement (1, 1′, 1″) has at least one external robot (12).

A space divider (4) of a milking parlor arrangement for at least one milking parlor (3) for milking milk-producing animals (T), wherein the space divider (4) is arranged approximately parallel to a longitudinal axis of the animal (T) to be milked, has an arm device (6) having a milking cluster (5, 5′), which can be adjusted from a parking position to a working position and back. The arm device (6) is arranged with the milking cluster (5) in the parking position in the space divider (4), wherein the milking cluster (5, 5′) can be adjusted into the working position laterally to the animal (T) to be milked between the front and rear legs thereof. The milking cluster (5, 5′) comprises two halves, wherein each half has a specific set of at least one teatcup (5a). The space divider (4) is designed in such a way that no additional space is required between adjacent animals (T), so that many animals (T) can be milked in a milking parlor arrangement (1, 1′, 1″) while the smallest possible amount of space is required. A milking parlor arrangement (1, 1′, 1″) has at least one external robot (12).

A control and monitoring system for a rotating animal platform which includes multiple animal stalls arranged about its periphery, where the system includes an interactive display screen which displays output information relating to the current status of operations on the platform and which displays input channels for use by an operator, the platform itself is represented at said interactive display screen by an annular shape, each stall on the platform is graphically represented by a cell, the cells are displayed in a spatial arrangement corresponding to the arrangement of stalls on the platform, real-time status information relating to operations on the platform is represented at each cell, and the rotating movement of the platform is represented by the progression of each cell about the displayed representation of the platform.

A control and monitoring system for a rotating animal platform which includes multiple animal stalls arranged about its periphery, where the system includes an interactive display screen which displays output information relating to the current status of operations on the platform and which displays input channels for use by an operator, the platform itself is represented at said interactive display screen by an annular shape, each stall on the platform is graphically represented by a cell, the cells are displayed in a spatial arrangement corresponding to the arrangement of stalls on the platform, real-time status information relating to operations on the platform is represented at each cell, and the rotating movement of the platform is represented by the progression of each cell about the displayed representation of the platform.

A milking device for milking a dairy animal comprises a teat cup with a cup wall and a teat liner and a pulsation space situated in between, to which pulsation space a pulsation device is connected which is configured to apply a pressure that varies in pulsations to the pulsation space in order to open and close the teat liner, and which pulsation device comprises a supply line which is controllable by a first operable valve, in particular closable, for supplying a first pressure, a supply line which is controllable by a second operable valve, in particular closable, for supplying a second pressure, which is a lower pressure than the first pressure, and a control unit which is configured to generate control signals for operating the first valve and the second valve, wherein the first valve, and preferably also the second valve, is a controllable valve having a passage which is adjustable by means of the control signals, wherein the passage of the first valve, and preferably of the second valve, respectively, is adjustable during at least one pulsation phase by the control unit via the control signals.

A milking device for milking a dairy animal comprises a teat cup with a cup wall and a teat liner and a pulsation space situated in between, to which pulsation space a pulsation device is connected which is configured to apply a pressure that varies in pulsations to the pulsation space in order to open and close the teat liner, and which pulsation device comprises a supply line which is controllable by a first operable valve, in particular closable, for supplying a first pressure, a supply line which is controllable by a second operable valve, in particular closable, for supplying a second pressure, which is a lower pressure than the first pressure, and a control unit which is configured to generate control signals for operating the first valve and the second valve, wherein the first valve, and preferably also the second valve, is a controllable valve having a passage which is adjustable by means of the control signals, wherein the passage of the first valve, and preferably of the second valve, respectively, is adjustable during at least one pulsation phase by the control unit via the control signals.