A robot control apparatus includes a selection part that selects a scenario to be used which an operator who operates a robot uses while operating the robot from among a plurality of scenario candidates in which an elapsed time since the robot has started an action and action contents of the robot are associated with each other, and a robot control part that controls the robot on the basis of the scenario to be used.

A robotic system includes a robot having a picking arm to grasp an inventory item and a shuttle. The shuttle includes a platform adapted to receive the inventory item from the picking arm of the robot. The platform is moveable between a pick-up location located substantially adjacent to the robot and an end location spaced a distance apart from the pick-up location. The system improves efficiency as transportation of the item from the pick-up location to the end location is divided between the robot and the shuttle.

A robot uses controlled omni-wheels and an arm assembly coupled to a gripper to facilitate the opening of doors. The gripper is rotatable around at least one of its axis to engage and rotate a door handle to unlatch a door. The omni-wheels are driven to move the robot along a curved path to open the door.

The system, devices and methods disclosed herein enable autonomous and tele-operation of tele-operated robots for maintenance of a property around known and unknown obstacles. A method may include using an unmanned aerial vehicle for obtaining additional data relating to the property and obstacles within the property and plan a path around the obstacles using data from sensors on-board the tele-operated robot and the aerial image. A method may also provide optimization of total time needed for performing the property maintenance and the labor costs in situations where manual intervention is needed for navigating the tele-operated robot around obstacles on the property or for removing obstacles on the property.

A system capable of communicating with a terminal includes a processor and a transmitter. The processor is configured to generate a first control signal including a first target position to operate at least part of the terminal and generate a second control signal including a second target position to operate at least part of the terminal after an operation of the at least part of the terminal in accordance with the first target position. The transmitter is configured to transmit the first control signal to the terminal at a first timing and transmit the second control signal to the terminal at a second timing after the first timing. The first target position is farther than a position which the at least part of the terminal is to reach at the second timing.

A robot uses controlled omni-wheels and an arm assembly coupled to a gripper to facilitate the opening of doors. The gripper is rotatable around at least one of its axis to engage and rotate a door handle to unlatch a door. The omni-wheels are driven to move the robot along a carved path to open the door.

A system and method of controlling an end effector includes a drive unit having a first actuator and a second actuator, a moveable platform drivably coupled to the first actuator, first and second engagement members drivably coupled to the second actuator; and a control unit. The control unit is configured to actuate the first actuator to drive the platform, detect engagement of the first engagement member with a third engagement member of an instrument, detect engagement of the second engagement member with a fourth engagement member of the instrument, and actuate the second actuator to drive the first and second engagement members. Movement of the third and engagement member causes movement of a degree of freedom of an end effector of the instrument in a first direction. Movement of the fourth engagement member causes movement of the degree of freedom in a second direction opposite the first direction.

A method includes receiving one or more signals indicative of a position of a distal-end assembly of a medical probe within an organ of a patient. Based on the received signals, an inner volume that is confined within the distal-end assembly is determined. An anatomical map of the organ is updated, to denote the inner volume of the distal-end assembly as belonging to an interior of the organ.

A method to enable autonomous and tele-operation of tele-operated robots for maintenance of a property around known and unknown obstacles may include using an unmanned aerial vehicle for obtaining additional data relating to the property and obstacles within the property and plan a path around the obstacles using data from sensors on-board the tele-operated robot and the aerial image. A method may also provide optimization of total time needed for performing the property maintenance and the labor costs in situations where manual intervention is needed for navigating the tele-operated robot around obstacles on the property or for removing obstacles on the property. Embodiments further include systems and devices practicing the method.

A computer-implemented method for collecting data within a facility is disclosed. The method includes receiving, by a computer system, perioperative data from a plurality of surgical devices located within the facility, the perioperative data associated with a plurality of surgical procedures performed in the facility; determining, by the computer system, procedural context data associated with the plurality of surgical procedures based at least in part on the perioperative data; aggregating, by the computer system, the perioperative data according to the procedural context data; and determining, by the computer system, trends associated with the surgical procedures performed in the facility according to the perioperative data and the procedural context data.