A method for examining a robot apparatus which includes a driving source configured to drive a joint, the position and orientation of which are controlled based on trajectory data determined in advance for a normal motion. The examination method includes generating examination motion data for driving a joint as an examination target under a driving speed that causes the examination target joint to resonate and causing the examination target joint to pass through a path based on the trajectory data. A resonance amplitude of the joint is acquired based on the examination motion data.

A method for examining a robot apparatus which includes a driving source configured to drive a joint, the position and orientation of which are controlled based on trajectory data determined in advance for a normal motion. The examination method includes generating examination motion data for driving a joint as an examination target under a driving speed that causes the examination target joint to resonate and causing the examination target joint to pass through a path based on the trajectory data. A resonance amplitude of the joint is acquired based on the examination motion data.

A method identifies an anomaly condition in operating a hand-held, mechanically unconstrained master device for controlling a robotic system for medical or surgical teleoperation. The method includes detecting or calculating the velocity vector of a point belonging to or integral with the master device, or of a virtual point uniquely and rigidly associated with the master device. A detectable anomaly condition is identified and recognized and/or discriminated based on the detected velocity vector, or based on a vector component. The detectable anomalies include master device excessive angular or linear velocity, inability to follow by the slave device, excessive vibrations or involuntary or abnormal opening of the master device. Each detectable anomaly is associated with a system state change to be performed if the anomaly is detected. The state change includes exiting or suspension from the teleoperation state. A robotic system for medical or surgical teleoperation performs the method.

A method identifies an anomaly condition in operating a hand-held, mechanically unconstrained master device for controlling a robotic system for medical or surgical teleoperation. The method includes detecting or calculating the velocity vector of a point belonging to or integral with the master device, or of a virtual point uniquely and rigidly associated with the master device. A detectable anomaly condition is identified and recognized and/or discriminated based on the detected velocity vector, or based on a vector component. The detectable anomalies include master device excessive angular or linear velocity, inability to follow by the slave device, excessive vibrations or involuntary or abnormal opening of the master device. Each detectable anomaly is associated with a system state change to be performed if the anomaly is detected. The state change includes exiting or suspension from the teleoperation state. A robotic system for medical or surgical teleoperation performs the method.

A robot system includes a robot; a peripheral device disposed around the robot; a control unit configured to operate at least the robot based on a program; a suspension unit configured to suspend a plurality of sequential operations performed by the robot in conjunction with the peripheral device based on an operation program if an irregular state occurs in the peripheral device; and a simulator. The simulator is configured to generate a recovery program based at least on a robot state information of the robot at the time of suspending the operation due to an occurrence of the irregular state, in which the control unit is further configured to cause the robot to operate with respect to the peripheral device based on the recovery program so that an operation by the suspended operation program becomes resumable.

A solution for performing a set of tasks using one or more robotic devices is provided. The robotic device can be configured to perform each task using one or more effector devices, one or more sensor devices, and a hybrid control architecture including a plurality of dynamically changeable levels of autonomy. The levels of autonomy can include: full autonomy of the robotic device, teleoperation of the robotic device by a human user, and at least one level of shared control between the computer system and the human user.

A method and apparatus for failure handling of a robot having at least a first and a second movement axis are disclosed. In one embodiment the method includes receiving a first position information of the first movement axis for a first point of time and a first position information of the second movement axis for the first point of time and storing the received first position information as a motion data set, receiving a second position information of the first movement axis for a second point of time and a second position information of the second movement axis for the second point of time and storing the received second position information in the motion data set and controlling the robot according to a failure procedure.

Methods and systems are provided for operating various robotic systems. The methods and systems involve applications of platforms that enable multiple-input teleoperation and a high degree of immersiveness for the user. The robotic systems may include multiple arms for manipulators and retrieving information from the environment and/or the robotic system. The robotic methods may include control modification modules for detecting that an operation of a robotic device based on the control commands fails to comply with one or more operational parameters; identifying the non-compliant control command; and generating a modifier for the secondary device to adjust the non-compliant control command to comply with the set of operational parameters.