The present disclosure relates to a computer-implemented method for monitoring for specification conformity along a production sequence for the production of a plurality of container base bodies filled with an aqueous system with an aggregate-based production facility. Moreover, the present disclosure relates to a computer-readable storage medium which stores computer-executable commands, which, when executed by a computer device, cause the computer device to carry out a method according to the present disclosure. Finally, the present disclosure relates to quasi-continuous monitoring for specification conformity, along a production sequence for the production of a plurality of containers filled with an aqueous system, in some cases a beverage, in an aggregate-based production facility, in some cases a high-speed production facility.

A checkout terminal, and method of using, having a goods receiving area for receiving goods, a goods recording area for recording the data of the goods, and a goods dispensing area for dispensing the goods. The checkout terminal further has a control unit configured for controlling the operation of the checkout terminal. The goods dispensing area has a first packing trough which is configured for temporarily collecting the goods. A goods transport means is configured for transporting the goods along a direction of transport form the goods receiving area via the goods recording area toward the first packing trough of the goods dispensing area. The goods recording area having a goods recording device having a scanner, which is configured for scanning a respective scannable identifier of the goods, located within a goods recording volume of the goods recording area and for providing a scanning result signal.

A method of processing blood or a blood product using an automated system includes displaying on a display a listing of a plurality of blood processing procedures that may be performed using the system and receiving operator input selecting one of the blood processing procedures that is to be performed. The method includes displaying on the display a list of parameters that are associated with the selected blood processing procedure and receiving operator input selecting a plurality of the parameters that are to populate the display during performance of the procedure. The method includes receiving operator input indicating a format in which the selected parameters are to be presented on the display. The method includes displaying values for the selected plurality of parameters in the indicated format during performance of the specified procedure.

A drop perception system is disclosed that includes an open housing structure having an internal volume, an open top and an open bottom, and a plurality of perception units positioned to capture perception data within the internal volume at a plurality of locations between the open top and the open bottom of the open housing.

A drop perception system is disclosed that includes an open housing structure having an internal volume, an open top and an open bottom, and a plurality of perception units positioned to capture perception data within the internal volume at a plurality of locations between the open top and the open bottom of the open housing.

A method and automated system for processing blood in which the automated system includes a programmable controller, a database, and an interactive display screen for displaying information and receiving operator input. The programmable controller is configured to automatically control the system to perform the method. Upon activation of the system, the screen displays a listing of different blood processing procedures that may be performed using the system. The operator may then input into the controller an identification of a specified blood processing procedure that is to be performed, such that an initial list of parameters that are associated with the specified blood processing procedure are displayed on the screen. The operator may then input into the controller an identification of the parameters that are to populate the display screen during performance of the procedure and indicate a format in which the selected parameters are to be presented on the display screen. The controller then creates a display for the specified blood processing procedure. Current values of the selected parameters in the selected format are displayed on the screen during performance of the specified procedure. The controller automatically saves an image of the display screen periodically during performance of the specified blood processing procedure, and transfers information from the saved images of the display screens to a procedure record form.

A method for automated positioning of a toothed workpiece, having the following method steps:

providing a toothed workpiece, which has a machine-readable, workpiece-specific marking, such as a QR code, a barcode, an RFID tag, or the like; attaching the toothed workpiece on a spindle of a CNC-controlled multiaxis machine; automatically acquiring the marking of the workpiece; ascertaining an actual position of the workpiece in relation to the multiaxis machine on the basis of the marking; transferring the workpiece from the actual position into a setpoint position in relation to the multiaxis machine, before a machining and/or measuring method is carried out in the multiaxis machine.

Disclosed are a network configuration method and an intelligent robot, falling within the technical field of intelligent devices. The method comprises: step S1, forming replacement information in a pre-set format according to configuration information of a network configuration for the intelligent robot, and outputting the replacement information by using an external device; step S2, the intelligent robot receiving and parsing the replacement information so as to obtain and output a corresponding parsing result; step S3, the intelligent robot obtaining the configuration information by means of restoration according to the parsing result; and step S4, the intelligent robot conducting network configuration according to the configuration information, and subsequently loging out. The beneficial effects of the technical solution are: being able to simplify a network configuration process for an intelligent robot, being able to achieve the purpose of network configuration with only a relatively low cost, and ensuring the accuracy of network configuration information.

Techniques described herein relate to using reduced-dimensionality embeddings generated from robot sensor data to identify predetermined semantic labels that guide robot interaction with objects. In various implementations, obtaining, from one or more sensors of a robot, sensor data that includes data indicative of an object observed in an environment in which the robot operates. The sensor data may be processed utilizing a first trained machine learning model to generate a first embedded feature vector that maps the data indicative of the object to an embedding space. Nearest neighbor(s) of the first embedded feature vector may be identified in the embedding space. Semantic label(s) may be identified based on the nearest neighbor(s). A given grasp option may be selected from enumerated grasp options previously associated with the semantic label(s). The robot may be operated to interact with the object based on the pose and using the given grasp option.

The present invention is to provide a robotic arm processing system, comprising: at least one robotic arm, at least one three-dimensional (3D) environment scanning device, and a processing device coupled between the robotic arm and the 3D environment scanning device. The robotic arm performs a processing procedure on at least one workpiece in a working area. The three-dimensional (3D) environment scanning device scans the working area to obtain 3D environment information of the working area. The processing device configures for generating a 3D model of the workpiece and a 3D model of the working area according to 3D environment information of the workpiece and the 3D environment information of the working area. Wherein the processing device generates a working path according to the 3D model of the workpiece and the 3D model of the working area and drives the robotic arm along the working path to perform a corresponding working procedure on the workpiece.