A method of operating a robotic control system comprising a master apparatus in communication with a plurality of input devices having respective handles capable of translational and rotational movement and a slave system having a tool positioning device corresponding to each respective handle and holding a respective tool having an end effector whose position and orientation is determined in response to a position and orientation of a corresponding handle. The method involves producing desired new end effector positions and orientations of respective end effectors in response to current positions and orientations of corresponding handles, using the desired new end effector positions and orientations to determine distances from each point of a first plurality of points along a first tool positioning device to each point of a plurality of points along at least one other tool positioning device, and determining and notifying that any of the distances meets a proximity criterion.

A control input assembly including a first link and a second link. A link housing extends from a second link first end portion to a second link second end portion. The second link first end portion is coupled to a first link second end portion via a joint shaft. An actuator is mounted within the link housing and the actuator defines an actuator axis. The actuator is configured to exert a torque on the joint shaft. The actuator axis and a rotational axis of the join shaft defines an offset angle, the offset angle being between about 20 degrees and 70 degrees.

Techniques for retracting an instrument into an entry guide include an entry guide manipulator configured to support an entry guide and an instrument manipulator configured to support an instrument. The robotic system is configured to receive a command indicating a commanded movement of the entry guide in a direction parallel to an insertion axis of the entry guide; in response to the commanded movement of the entry guide being greater than a threshold distance in the direction parallel to the insertion axis, cause a response comprising one or more actions selected from the group consisting of: movement, using the instrument manipulator, of one or more rotational joints of the instrument external to the entry guide toward a distal end of the entry guide; and actuation of the one or more rotational joints to straighten the instrument so that the instrument can be retracted into the entry guide.

A method of operating a robotic control system comprising a master apparatus in communication with a plurality of input devices having respective handles capable of translational and rotational movement and a slave system having a tool positioning device corresponding to each respective handle and holding a respective tool having an end effector whose position and orientation is determined in response to a position and orientation of a corresponding handle. The method involves producing desired new end effector positions and orientations of respective end effectors in response to current positions and orientations of corresponding handles, using the desired new end effector positions and orientations to determine distances from each point of a first plurality of points along a first tool positioning device to each point of a plurality of points along at least one other tool positioning device, and determining and notifying that any of the distances meets a proximity criterion.

Improved actuator and retraction mechanisms for force feedback exoskeletons are described. An actuator assembly for a force-feedback exoskeleton comprising: a rotating body coupled to a tendon and to a spring, said spring configured to produce a torque on the rotating body; and a second body having a surface configured to apply a variable force to a surface of the rotating body by means of a membrane enclosing a volume fluidically coupled to at least one control valve and to a pressurized fluid source, wherein the volume enclosed by the membrane comprises: a first pressure state in which the rotating body contacts the second body; and a second pressure state in which the rotating body does not contact the second body.

Haptic-robot control based on local autonomy and a dual-proxy model is provided. The dual proxy guarantees generation of safe and consistent commands for two local controllers, which ensure the compliance and stability of the systems on both sides. A Force-Space Particle Filter enables an autonomous modeling and rendering of the task contact geometry from the robot state and sensory data. The method suppresses the instability issues caused by the transfer of power variables through a network with communication delays in conventional haptic-robot controllers. The results demonstrated the transparency and high fidelity of the method, and robustness to communication delays. While the conventional method failed for communication delays higher that 150 milliseconds, the dual proxy method maintained high performance for delays up to one and a half seconds. The local autonomy-based haptic control of robots with the dual-proxy model enables applications in areas such as medical, underwater and space robotics.

The present disclosure provides a master manipulator device for a robot. The master manipulator device comprises an end control assembly and a posture adjustment member. The posture adjustment member includes a first rotation mechanism and a second rotation mechanism. The first rotation mechanism is connected to the end control assembly, and the second rotation mechanism is connected to the first rotation mechanism. The end control assembly drives the first rotation mechanism to rotate around a rotation axis of the first rotation mechanism, and the end control assembly also drives the first rotation mechanism and the second rotation mechanism to rotate around a rotation axis of the second rotation mechanism.

A manipulation device and a manipulation system of a simpler configuration. A manipulation device includes an input part configured to receive an input of an operational instruction by an operator in order to operate a manipulating target, and a speaker configured to receive a signal based on vibration detected at the manipulating target and generate vibration based on the received signal. The vibration generated by the speaker is transmitted to the operator through at least a part of the input part.

A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.

A surgical system, comprising an articulated mechanical arm with a plurality of arm joints, first and second user-input devices for controlling the arm, and a surgical end effector at the distal end of the arm, is operated initially in a retroflexing mode with the first user-input device is active to direct flexion and rotation of only a single given arm joints, and with the second user-input device is disabled. While in the retroflexing mode, a distal portion of the arm is retroflected by flexion and rotation of the single given arm joint. With the arm retroflected, the system is transitioned to surgical-operation mode which enables the second user-input device to flex and rotate any or all of the arm joints, to move the surgical end-effector to perform one or more surgical actions.