Embodiments herein describe forming clusters of network connected orchestration components (referred to herein as orchestrators) and distributing the management of a plurality of work cells among the orchestrators. That is, each cluster can include a plurality of work cell orchestration nodes which are the compute resources used to host an orchestrator for managing the work cells. Each cluster can be assigned to manage a particular type or version of a work cell. Because managing a work cell may use only a small fraction of the compute resources of the orchestration nodes, each orchestration node can manage multiple work cells. The embodiments herein describe distributing the work cells amongst the orchestration nodes using a work cell table which permits the orchestration nodes to assert ownership over new work cells and enable automated failover in case one of the orchestration nodes fails.

A system for inspecting, cleaning, and/or repairing one or more blades attached to a rotor of a gas turbine engine. The system includes a track disposed adjacent to the rotor, a mechanical arm moveable along the track, a number of tools attachable to the mechanical arm, and a controller configured to control a position of at least one of the tools that is attached to the mechanical arm about the one or more blades.

A robotic system (new robot) operative for performing at least one task in an environment, the system comprising: learn-from-predecessor functionality governed by a data exchange protocol, which controls short-range wireless knowledge transfer from a short-range wireless transmitter in a predecessor robot system (old robot) to a short-range wireless receiver in said robotic system, said knowledge comprising at least one environment-specific datum previously stored by the predecessor robot.

A robot system which includes a manipulator, slave arm, an output device, a storage device and a control device. Control device is configured, after a given first process, to output to the output device an inquiry of asking which operating mode among three operating modes of an automatic operation mode, manual operation mode, and hybrid operation mode the slave arm is to be operated in a second process, and execute first operation processing in which, when selected information for instructing the operating mode selected from the three operating modes is inputted, the selected information is stored in the storage device, and second operation processing in which, when the number of times that first selected information is stored in the storage device becomes equal to or more than a first threshold number of times, the selected operating mode is outputted to the output device after the first process is ended.

Robot system includes robot main body including robot arm, end effector attached to robot arm, and force sensing device detecting force applied to end effector's tip end, actual reaction-force information generator generating force-sensing information according to force detected by force sensing device, and output force-sensing information as actual reaction-force information, virtual reaction-force information generator outputting force component detected by force sensing device, that has a magnitude proportional to time differentiation value, as virtual reaction-force information, adder configured to output information obtained by adding actual reaction-force information outputted from actual reaction-force information generator to virtual reaction-force information outputted from virtual reaction-force information generator, as synthetic reaction-force information, operating device outputting, when operator is made to sense a force according to synthetic reaction-force information outputted from adder and operator operates, operating information according to operation, and motion controller controlling robot main body's operation according to operating information outputted from operating device.

A robot system includes a robot main body, memory part configured to store information for causing robot main body to perform given operation, as saved operational information, motion controller configured to control operation of robot main body by using saved operational information as automatic operational information for causing robot main body to operate, and an operation correcting device configured to generate, by being operated, manipulating information for correcting operation of robot main body during operation. Motion controller controls robot main body to perform an operation corrected from operation related to automatic operational information in response to a reception of the manipulating information while robot main body is operating by using automatic operational information. Memory part is configured to be storable of corrected operational information for causing robot main body to perform corrected operation as saved operational information, when robot main body performs corrected operation.

A robot system is provided, which includes a robot body including, robot arm and an end effector attached to robot arm, and operating device, having operating part and configured to output, when operating part is operated, operational information according to operation, a motion controller configured to control operation of robot body according to the operational information outputted from the operating device, a velocity detector configured to detect a velocity at a tip end of the end effector, a virtual reaction-force information generating module configured to output force information containing a first force component having a positive correlation to the velocity at the tip end of the end effector, as virtual reaction-force information, and a force applying device configured to give a force to the operating part in order to make an operator perceive a force according to the virtual reaction-force information outputted from the virtual reaction-force information generating module.

Increased robotic sophistication and more efficient autonomous operation is implemented by providing separate physical autonomous robots shared and remote access to the sensory array and information from the sensory array of one another. Each robot can access a sensor of any other robot, or scans or other information obtained from the sensor of any other robot. The robots leverage the shared sensory access in order to perform batch order fulfillment, dynamic rearrangement of item or tote locations, and opportunistic charging. These coordinated robotic operations based on the shared sensory access increase the efficiency and productivity of the robots without adding resources or hardware to the robots, increasing the speed of the robots, or increasing the number of deployed robots.

The robotic device for positioning a surgical instrument relative to the body of a patient includes a first robotic arm with a device for rigidly connecting to at least one surgical instrument, a device for anatomical realignment of the first arm by realigning an image that is of an area of the anatomy of the patient, and a device for compensating the movements of the first arm on the basis of detected movements. One version of the device includes at least one second robotic arm having sensors for detecting inner movements of the anatomical area, and a device for controlling the positioning of the first arm relative to sensed inner movements and to the outer movements induced in the second arm.

A robotic system (new robot) operative for performing at least one task in an environment, the system comprising: learn-from-predecessor functionality governed by a data exchange protocol, which controls short-range wireless knowledge transfer from a short-range wireless transmitter in a predecessor robot system (old robot) to a short-range wireless receiver in said robotic system, said knowledge comprising at least one environment-specific datum previously stored by the predecessor robot.