A device includes a housing. An actuator is disposed within the housing. The actuator includes an actuator arm extending from the housing. A motor controller is disposed within the housing to control the actuator. A network input/output device is configured to communicate with a computer device over a communications network. The actuator is controlled remotely by one or more commands received from the computer device.

An assistance system that can be used for prosthetic heart valve manufacturing or suturing procedures includes an automated fixture that can comprise an articulation arm and a target device holder. The target device holder can be positioned and oriented to reduce operator strain during a manufacturing or inspection process. The assistance system includes a user input device enabling the operator to move between positions to assist in such processes. The assistance system can also be trained by capturing sequences of position data corresponding to a manufacturing or inspection process.

A system is disclosed and includes an electronic controller configured to generate a virtual reality representation of an environment. The electronic controller is configured to generate a menu within the virtual reality representation of the environment comprising at least one task user interface element and determine when an option for configuring a force parameter is selected from the at least one task user interface element in the menu. The electronic controller is configured to prompt a user to configure the force parameter for a virtual robot manipulation task and assign at least one of a force magnitude or a force direction to the virtual robot manipulation task in response to an input received from the prompt to configure the force parameter.

Methods and devices for controlling a robotic system include receiving a signal in response to movement of an input device through an input distance, determining the position of a repositioning control disposed on the input device, and moving the tool of the robotic system in response to movement of the input device the input distance. The input device is coupled to an input shaft of an input arm. The robotic system moving the tool a first distance when the repositioning control is in a deactivated position and moves the tool a second distance when the repositioning control in an activated position. The first distance is greater than the second distance.

A computer-assisted medical device includes an articulated arm with a plurality of joints and a control unit coupled to the articulated arm. The control unit is configured to send a command to a plurality of brakes in the articulated arm to begin a release of the plurality of brakes in a predetermined staggered manner. In some embodiments the predetermined staggered manner prevents the simultaneous release of the plurality of breaks. In some examples, the predetermined staggered manner causes each brake in the plurality of brakes to release within a predetermined time of each other. In some embodiments, the first predetermined staggered manner causes each brake in the first plurality of brakes to release within a predetermined time of each other. In some embodiments, the first predetermined staggered manner causes each brake in the first plurality of brakes to begin a gradual release within a predetermined time of each other.

A computer-assisted surgery system may have a robotic arm including a surgical tool and a processor communicatively connected to the robotic arm. The processor may be configured to receive, from a neural monitor, a signal indicative of a distance between the surgical tool and a portion of a patient's anatomy including nervous tissue. The processor may be further configured to generate a command for altering a degree to which the robotic arm resists movement based on the signal received from the neural monitor; and send the command to the robotic arm.

Provided is a control device including a control unit that calculates a first positional relationship between an eye of an observer observing an object displayed on a display unit and a first point in a master-side three-dimensional coordinate system, and controls an imaging unit that images the object so that a second positional relationship between the imaging unit and a second point corresponding to the first point in a slave-side three-dimensional coordinate system corresponds to the first positional relationship.

This multi-articulated manipulator is rich in reliability and follow-up property in medical applications. The multi-articulated manipulator is composed of more than one hollow outer shell, joint members to connect the outer shells each other, a grasping member fastened for rocking movement to the foremost outer shell, and a power transmission shaft to actuate the grasping member and the outer shell in a bending manner independently from each other. The power transmission shaft is composed of a universal join allowed to bend independently from each other and transmit the rotating torque, and a transmission shaft capable of making expansion and shrinkage and able to transmit rotating torque. The power transmission shaft at the foremost end thereof has male threads mating with the nut made at the boss portion inside the outer shell.

Methods, apparatus, systems, and computer-readable media are provided for selective robot deployment. In various implementations, a context of a user may be determined based at least in part on a record of one or more computing interactions associated with the user. In various implementations, a robot-performable task of the user may be identified based at least in part on the context. In various implementations, a measure of potential or actual interest of the user in deploying a robot to perform the robot-performable task may be determined. In various embodiments, the robot may be selectively deployed based on the measure of potential or actual interest.

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.