A learning assistance system includes an operation control unit, a parameter acquisition unit, and a display control unit. The operation control unit causes an apparatus to be controlled to operate in accordance with force tactile sensation during operation by a user. The parameter acquisition unit acquires control parameters that are used for the control by the operation control unit. The operation control unit and the display control unit comparably provide, to a second user, a first control parameter acquired by the parameter acquisition unit in a case where the operation control unit controlled the operation of the apparatus based on operation by the first user and a second control parameter acquired by the parameter acquisition unit in a case where the operation control unit controlled the operation of the apparatus based on operation by the second user.

A learning assistance system includes an operation control unit, a parameter acquisition unit, and a display control unit. The operation control unit causes an apparatus to be controlled to operate in accordance with force tactile sensation during operation by a user. The parameter acquisition unit acquires control parameters that are used for the control by the operation control unit. The operation control unit and the display control unit comparably provide, to a second user, a first control parameter acquired by the parameter acquisition unit in a case where the operation control unit controlled the operation of the apparatus based on operation by the first user and a second control parameter acquired by the parameter acquisition unit in a case where the operation control unit controlled the operation of the apparatus based on operation by the second user.

A user system for a robotic surgical system, the user system including a handheld groundless user interface device configured to control the robotic surgical system, and a user console. The user console includes a seat and a first adjustable, ergonomic arm support linkage coupled to the seat, in which the first arm support linkage is movable between a folded storage configuration and at least one unfolded use configuration corresponding to at least one of a user characteristic and a surgical task characteristic. The at least one unfolded use configuration may be pre-stored in a database.

A user system for a robotic surgical system, the user system including a handheld groundless user interface device configured to control the robotic surgical system, and a user console. The user console includes a seat and a first adjustable, ergonomic arm support linkage coupled to the seat, in which the first arm support linkage is movable between a folded storage configuration and at least one unfolded use configuration corresponding to at least one of a user characteristic and a surgical task characteristic. The at least one unfolded use configuration may be pre-stored in a database.

An electronic apparatus for a database construction and control of a robotic manipulator is provided. The electronic apparatus stores information associated with a task of a robotic manipulator. The electronic apparatus further receives a first plurality of signals from a first plurality of sensors associated with a wearable device. The electronic apparatus further applies a predefined model on a first set of signals of the first plurality of signals. The electronic apparatus further determines arrow direction information based on the application of the predefined model on the first set of signals. The electronic apparatus further aggregates the determined arrow direction information with information about the first set of signals to generate output information. The electronic apparatus further stores the generated output information for each of a first plurality of poses performed for the task using the wearable device.

A position/force control system includes a worn unit and a control unit. The worn unit is configured to be worn on a body of a user, and provides force tactile sensation by an actuator. The control unit acquires data of a position of the worn unit in a space, based on data of space in which a touching object exists. The worn unit includes a control unit that acquires the data of the position from the control unit and controls driving of the actuator based on impedance and contour information of the touching object in the space, and the data of the position, thereby providing force tactile sensation.

A method, a non-transitory computer readable medium, and an apparatus for operating the robotic control system comprising a master apparatus (64) in communication with an input device (58, 60) having a handle (102) and a slave system (54, 74) having a tool (66, 67) having an end effector (73) whose position and orientation is determined in response to a current position and current orientation of the handle. The method involves producing a desired end effector position and orientation in response to a current position and orientation of the handle. The method involves causing the input device to provide haptic feedback that impedes translational movement of the handle, while permitting rotational movement of the handle and preventing movement of the end effector, when a rotational alignment difference between the handle and the end effector meets a disablement criterion. The method further involves re-enabling translational movement of the handle when the rotational alignment difference meets an enablement criterion.

A medical movable body system according to the present disclosure includes a medical movable body, a robot, a manipulator, and a controller. The robot is in a first space. The manipulator is in a second space. The controller executes: (A) making the robot self-travel to approach a patient; and after the (A), (B) operating an arm and/or a hand .

A robot hand is designed to open or close fingers using a linear actuator disposed in a housing. The robot hand has linear motion shafts extending from inside to outside the housing through guide holes formed in a wall of the housing. Each of the fingers includes a base portion and a tip portion. The base portions are secured to the linear motion shafts outside the housing. The tip portions are bent inwardly from the base portions in directions in which they approach each other and then extend toward tips of the fingers. A sealing member is disposed between each of the linear motion shafts and a corresponding one of the guide holes to hermetically isolate the inside of the housing from the outside thereof. This structure achieves an increased degree of sealing of the housing and is capable of having an increased opening or closing stroke of the fingers.

A robot hand is designed to open or close fingers using a linear actuator disposed in a housing. The robot hand has linear motion shafts extending from inside to outside the housing through guide holes formed in a wall of the housing. Each of the fingers includes a base portion and a tip portion. The base portions are secured to the linear motion shafts outside the housing. The tip portions are bent inwardly from the base portions in directions in which they approach each other and then extend toward tips of the fingers. A sealing member is disposed between each of the linear motion shafts and a corresponding one of the guide holes to hermetically isolate the inside of the housing from the outside thereof. This structure achieves an increased degree of sealing of the housing and is capable of having an increased opening or closing stroke of the fingers.