A dynamic representation of a robot in an environment is produced, one or more observer agent collects data, and respective values of one or more metrics for the robot are computed based at least in part on the collected data. Tasks for the robot to perform are generated. Ratings and challenge questions are generated. A server may produce a user interface and a value of a metric based on collected observer data.

A controller stores the orientations of a master tool grip and a slave surgical instrument tip upon completion of a master-slave alignment process, and enters following. During following each commanded movement of the slave surgical instrument tip from the master tool grip is processed by the controller to compensate for any alignment error between the master tool grip and the slave surgical instrument tip before following was entered. The result of this processing is that the motion of the slave surgical instrument tip intuitively corresponds to the motion of the master tool grip despite an initial swooping orientation misalignment between the master tool grip and the slave surgical instrument tip.

A dynamic representation of a robot in an environment is produced, one or more observer agent collects data, and respective values of one or more metrics for the robot are computed based at least in part on the collected data. Tasks for the robot to perform are generated. Ratings and challenge questions are generated. A server may produce a user interface and a value of a metric based on collected observer data.

A controller stores the orientations of a master tool grip and a slave surgical instrument tip upon completion of a master-slave alignment process, and enters following. During following each commanded movement of the slave surgical instrument tip from the master tool grip is processed by the controller to compensate for any alignment error between the master tool grip and the slave surgical instrument tip before following was entered. The result of this processing is that the motion of the slave surgical instrument tip intuitively corresponds to the motion of the master tool grip despite an initial swooping orientation misalignment between the master tool grip and the slave surgical instrument tip.

A system includes an input control, an instrument, a memory storing instructions, and one or more processors coupled to the memory. A first axis of a first coordinate frame is defined along a length of the input control and is associated with an orientation of the input control. A second axis of a second coordinate frame is defined along a length of the instrument and is associated with an orientation of the instrument. When executing the instructions, the one or more processors perform steps including, while in a following state, receiving a first command corresponding to a rotation of the input control about the first axis, in response to the first command, generating a second command to rotate the instrument around the second axis without rotating the instrument around any axis orthogonal to the second axis, and controlling movement of the instrument according to the second command.

The embodiments relate to a distributed marsupial robotic system. The system includes a parent component having a sensor suite to obtain and process environment data via a parent pattern classification algorithm, and one or more child components each having a sensor suite to obtain and process environment data via a child pattern classification algorithm. Each sensor suite includes one or more sensor devices in communication with a processing unit and memory. Each child component is configured to dock to the parent component, and to separate from the parent component in response to a deployment signal. Each child component obtains environment data during separation. The parent component is configured to construct a map of the environment by receiving and integrating the data obtained by each child component.

A dynamic representation of a robot in an environment is produced, one or more observer agent collects data, and respective values of one or more metrics for the robot are computed based at least in part on the collected data. Tasks for the robot to perform are generated. Ratings and challenge questions are generated. A server may produce a user interface and a value of a metric based on collected observer data.

A system includes a controller configured to be coupled to an input control and a robotic arm, the robotic arm being configured to hold and position an instrument. The controller is configured to receive a first command from the input control to manipulate the instrument; determine, when there is an orientation misalignment between an orientation of the input control in an eye coordinate frame and an orientation of a distal portion of the instrument in a camera coordinate frame, a desired orientation of the distal portion, the desired orientation for causing the distal portion to rotate in a same manner about an axis defined with respect to the distal portion as the input control rotates about a corresponding axis defined with respect to the input control; and transmit a second command to the robotic arm to cause the instrument to be oriented according to the desired orientation of the instrument.