A holding arm for holding a surgical mechatronic assistance system or a surgical instrument is described. The holding arm includes a proximal end for attaching the holding arm to a base and a distal end for receiving the surgical mechatronic assistance system or the surgical instrument. The holding arm also includes a first arm segment connected to a first joint and a second arm segment connected to a second joint. The first joint and the second joint are releasable and lockable. The holding arm also includes a switch adapted to release both the first and second joints. The holding arm also includes a first contacting device with two contact elements arranged substantially opposite one another on the first arm segment. The first contacting device is adapted to release the first joint only when both of the two contact elements of the first contacting device are contacted.

The arrangement is provided for monitoring state and sequence of movement in an aseptic work chamber of a containment standing in an installation room. At least one work glove projects into the work chamber, wherein the respective work glove is able to stretch up to a maximum grasping range in the three spatial axes in the work chamber. The arrangement comprises a tracking system, the recordings of which serve to continuously localize the at least one work glove in three dimensions and are stored in a computer unit. At least one three-dimensional or two-dimensional prohibited region, which may be adjoined by a warning region, is defined in the work chamber. Individual surface sections or the entire floor of the containment can be defined as a prohibited region. A prohibited region and possibly a warning region in front of this can be set up around machines which are installed in the work chamber and which constitute a danger for the operator. The coordinates of prohibited region and warning region are stored in the computer unit. The at least one work glove must not be used to intervene in the prohibited region and should not be used to intervene in the warning region.

Systems and methods are directed to automated delivery systems. In one example, a vehicle is provided including a drive system, a passenger cabin; and a delivery service pod provided relative to the passenger cabin. The delivery service pod includes an access unit configured to allow for loading and unloading of a plurality of delivery crates into the delivery service pod. The delivery service pod further includes a conveyor unit comprising multiple delivery crate holding positions, the delivery crate holding positions being defined by neighboring sidewalls spaced apart within the delivery service pod such that a respective delivery crate of the plurality of delivery crates can be positioned between neighboring sidewalls, wherein the conveyor unit is configured to be rotated to align each of the delivery crate holding positions with the access unit.

A robot and a method of capturing an image applied to the robot, an electronic device for implementing the method of capturing the image, and a computer-readable storage medium are provided. The robot includes: a robot body; a workbench; a telescopic structure having one end pivotally connected to the robot body and the other end connected to the workbench; a driving mechanism arranged on the robot body and configured to drive the telescopic structure to extend, retract and/or move relative to the robot body; and an image capture device arranged on the workbench. The telescopic structure is configured to allow the image capture device to capture an image of a target object from different angles with the extension, retraction and/or movement of the telescopic structure.

A fenceless system and method for automatically moving one or more items between a structure at a source location and a destination using a robot is provided. The system comprises a robot having an end effector to selectively grasp an item. A trajectory planning controller directs the robot to move the item between a source location and a destination. A touch sensor detects a contact between an external object and a surface of the robot or a surface surrounding the end effector; and a proximity sensor detects a person in proximity to the robot. A vision sensor detects a location and orientation of items to be moved. The robot moves in proximity to a person without a safety fence preventing the person from contacting the robot. The system adjusts a speed of the robot in response to detecting a person in one of a plurality of zones around the robot.

Systems and methods are provided for automatically controlling zone interactions in a three dimensional virtual environment. A computing device provides a graphical user interface (GUI) to assign zone attributes to a zone, which is a volume of space in the virtual environment. A virtual object is assigned to the zone, as well as an interaction and a responsive operation that follows the detected interaction. The virtual object's position in the virtual environment corresponds to a physical object's position in a physical environment. For example, when the computing system detects that the virtual object has entered or left the zone, according to an assigned interaction, then an assigned operation is executed to control a physical device in the physical environment.

A robot system includes a robot for performing predetermined processing to a treating object, a photographing device for photographing the treating object, a robot control device for performing position compensation of a moving destination of the robot so as to track the treating object, on a basis of previously-set information on positions of the robot, the photographing device and the treating object, and an image of the treating object photographed by the photographing device, and a display device for providing an AR space. The robot control device calculates a position of the photographing device on the basis of the information on the positions of the robot and the photographing device. The display device displays an image imitating the photographing device at a corresponding position in the AR space, on a basis of the calculated position of the photographing device.

A computer-implemented method includes detecting, at a processor and by a plurality of associates, a mission to be performed by the plurality of associates; identifying the mission based on associated store information comprising an inventory status, sales data, and a set of predetermined rules; generating, by the processor, a queue of tasks to complete the mission based on priorities and dependencies of the tasks; determining a task for each associate whose profile defines best abilities matching a predetermined task dataset and the associated store information; assigning the queue of tasks to the plurality of the associates to complete the tasks; receiving, from each of the associates, a notification of a completion of an assigned task; verifying, by the processor, the completion of the assigned task; and determining, by the processor, completion of the mission when each task for the mission is verified to be completed.

Systems and methods for automated makeup application allow a user to select and apply desired makeup styles to the user's face. The systems and methods include a computer application with a graphical user interface which allows selection of a look from a plurality of preconfigured looks. A camera coupled with a robotic arm records a face map and color coding and sends that data to be stored on a virtual server database. The application calculates formula quantity and a pump extracts desired formula amounts from appropriate formula cartridges which it releases into reservoirs on the robotic arm's head. An airbrush compressor mixes the formula and plug triggers release one of several airbrush nozzles to start spraying the user's face with formula. A cleaning mechanism is provided between makeup applications and after the final application.

A feeder that feeds objects to be picked up by a robot, includes an object container unit having a first planar portion including a first planar surface in which the objects are thrown, and a groove portion including a plurality of grooves extending in a first direction from the first planar portion as seen from a normal direction in which a normal of the first planar surface extends, and a vibrator unit that applies vibration to the object container unit, wherein the vibrator unit has a first vibration mode in which the objects are moved in the first direction.