Abstract: A surgical system capable of securing a large movable range of a tip end of a surgical instrument even when the surgical instrument is inserted into a narrow region. One example of the surgical system includes: a manipulator; a surgical instrument including a shaft coupled to a tip end portion of the manipulator; a manipulation input portion to which an operator inputs a command regarding a position and posture of the surgical instrument; a control apparatus configured to control an operation of the manipulator based on the command input to the manipulation input portion; and a motion center position setting portion configured to set a desired position as a motion center position of the surgical instrument in the control apparatus, the desired position being located in an inner part under a body surface of the patient.

Abstract: Systems and methods for robot assisted personnel routing including a plurality of autonomous robots operating within a navigational space, each robot including a processor and a memory storing instructions that, when executed by the processor, cause the autonomous robot to detect completion of a task operation by a human operator, receive status information corresponding to at least one other robot, the status information including at least one of a location or a wait time associated with the other robot, determine, from the status information, at least one next task recommendation for directing the human operator to a next robot for a next task operation, and render, on a display of the robot, the at least one next task recommendation for viewing by the human operator, the next task recommendation including a location of the next robot corresponding to the next task.

Abstract: A robot with a noncontact sensor is configured to: perform the predetermined motion in a state where the moving object does not enter, and thereby store, for each of a plurality of measurement points set in a movable range of the robot, an output value of the noncontact sensor as a reference output value in advance, and stop the predetermined motion when the output value of the noncontact sensor changes from the reference output value at the measurement point closest to a current operating position of the robot by a first threshold value or larger when the robot is performing the predetermined motion in a state where the moving object could possibly enter and the current operating position of the robot is in a range in which it is necessary to determine an entering state of the moving object.

Abstract: Various medical devices and related systems, including robotic and/or in vivo medical devices, and various robotic surgical devices for in vivo medical procedures. Included herein, for example, is a robotic surgical system having a support beam positionable through an incision, and a robotic device having a device body, first and second rotating shoulder components coupled to the device body, and first and second robotic arms coupled to the first and second shoulder components, respectively.

Abstract: Systems and methods for operating an end effector include a first jaw, a second jaw, a first actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a first force, and a second actuation mechanism configured to actuate the first jaw and the second jaw toward each other with a second force greater than the first force. The second actuation mechanism is different from the first actuation mechanism. In some embodiments, the first actuation mechanism includes a first pull cable configured to increase an angle between the first jaw and the second jaw and a second pull cable configured to decrease the angle between the first jaw and the second jaw. In some embodiments, the second actuation mechanism includes a lead screw.

Abstract: A combined robot and a cruise path generating method thereof includes providing or generating a working map of a self-moving robot and marking a target point on the working map. A planned path is generated according to the location of the target point in the working map. The combined robot begins to walk according to the planned path and it is determined whether an obstacle is encountered during walking. If an obstacle is encountered, a different path adjustment mode is selected according to a relative location when the obstacle is encountered and the planned path is updated according to a walking path to form an actual path. Otherwise, the robot walks directly to form the actual path. The actual path is saved as a cruise path of the combined robot.

Abstract: A system for coupling a towing vehicle to a towed vehicle and/or for controlling charging/braking by the towed vehicle. The system may include a coupler coupling to the towing vehicle; and first and second tow bars having first and second ends and a rotational joint situated between the first and second ends, the first and second tow bars coupled to the coupler at the first ends and being non-parallel in at least one plane with the second ends located further apart from each other than the first ends. The rotational joint providing for the first and second tow bars to be positioned in an open and a folded position. The second ends of the first and second tow bars are configured to be coupled to the towed vehicle. For charging, a trip distance and charge of a towed vehicle battery is utilized to determine a charging rate for the trip.

Abstract: A robot with a safety fence includes: a base; a movable part having a base end supported to the base so as to be rotatable about a first axis, and a tip end performing operation on an operation target; and a safety fence rotated about the first axis together with the movable part, and disposed on a rear side opposite to a front side of the robot with a safety fence where the tip end of the movable part performs operation. The safety fence is disposed in a position radially closer to the first axis than the farthest distance the tip end of the movable part travels from the first axis on the front side, and a position radially farther away from the first axis than the farthest distance a portion of the movable part travels from the first axis during operation, on the rear side.

Abstract: Some embodiments may include a control system configured to monitor an online queue associated with a remote server for the presence of updated control software content; in the case of the presence of updated control software content in the online queue, provide data based thereon in an offline queue, wherein a portable computing device includes a storage for the offline queue; waiting for a time period in which a wired communication interface of the portable computing device is attached to a wired interface of the vehicle or a wireless communication interface of the vehicle is in range of a wireless communication interface of the portable computing device; and in the time period, transferring contents of the offline queue to the vehicle, wherein a processor of the vehicle distributes update(s) included in the contents to one or more of the GNSS receiver, the actuator assembly, and the steering control module.

Abstract: A method of adjusting multiple tools on a common mount includes the interrogating first and second actual target positions on at least one workpiece. A variance is determined between the first and second actual target position and first and second theoretical target positions. At least one of the first and second tools is moved relative to the other of the first and second tools from the first and second theoretical target positions to a desired spacing respectively aligned with the first and second actual target positions.

Abstract: A passive compliance gripper includes a passive compliance part, a displacement measuring element and a gripper mount. A first end of the passive compliance part is fixed, and a second end of the passive compliance part is configured to be transformed. The displacement measuring element is equipped to the passive compliance part, and measures displacement due to transformation of the passive compliance part. The gripper mount is connected to the second end of the passive compliance part, and has a gripper part gripping a component.

Abstract: An orientation system includes a base station comprising a light emitter that projects a pattern onto a projection surface of a space, an auxiliary station including an auxiliary emitter that projects an auxiliary pattern onto the projection surface, and a robot including a moveable base supporting an imaging device. The robot detects the pattern and the auxiliary pattern with the imaging device, and determines a location of the robot within the space based on the pattern.

Abstract: A robot system including at least one robot arm and a control unit which is designed such that it can pre-set at least one pre-defined operation carried out by the robot system. The robot system also includes a display device and at least one input device applied to the robot arm, which is designed such that the sequence of operations of the robot system is set and/or the pre-defined operations of the robot system is parameterized by means of the input device, and which is also designed such that it allows the user to control, on a graphic user interface, represented by the control unit on the display device, the setting of the pre-defined operations of the robot system, the setting of the sequence of operations and/or the parameterization of the pre-defined operations for the robot system.

Abstract: Techniques for providing a unified computational platform for implementing virtual reality systems. In an aspect, a virtual reality (VR) client includes input and output modules for generating a VR user experience. The client may also incorporate an assistant interface that couples the input and output modules to an assistant server using a semantic information interchange language (SIIL). The assistant server may include a command inference block for converting user-input SIIL messages to command-input SIIL messages, thereby encoding user VR inputs into a general command set that may be recognized and processed by both VR and non-VR modules. Further aspects disclose techniques for seamless integration between virtual environments and joint VR sessions supporting multiple users.

Abstract: For controlling a robotic surgical system including arms, consoles, and a controller in communication with the arms and consoles, systems and methods are provided that include receiving a request for selection of a first arm for assignment to a first console, and in response to the request, determining whether the first arm is already assigned, assigning the first arm to the first console, if a determination is made that the first arm is not already assigned, determining whether the first arm is to be deselected from a previous assignment, if a determination is made that the first arm is already assigned, generating an error message, if a determination is made that the first arm is not to be deselected, and deselecting the first arm from the previous assignment and assigning the first arm to the first console, if a determination is made that the first arm is to be deselected.

Abstract: The present invention relates to systems and methods for providing location and guidance, and more particularly for providing location and guidance in environments where global position systems (GPS) are unavailable or unreliable (GPS denied and/or degraded environments). The present invention further relates to systems and methods for using inertial measurement units IMUs to provide location and guidance. More particularly, the present invention relates to the use of a series of low-accuracy or low-resolution IMUs, in combination, to provide high-accuracy or high-resolution location and guidance results.

Abstract: Methods, systems, and apparatus, including computer-readable media storing executable instructions, for enhancing robot learning. In some implementations, a robot stores first embeddings generated using a first machine learning model, and the first embeddings include one or more first private embeddings that are not shared with other robots. The robot receives a second machine learning model from a server system over a communication network. The robot generates a second private embedding for each of the one or more first private embeddings using the second machine learning model. The robot adds the second private embeddings to the cache of the robot and removes the one or more first private embeddings from the cache of the robot.

Abstract: A footed robot landing control method and device are provided. The footed robot landing control method includes: detecting a landing motion state of the robot; if the landing motion state is a flight phase descending state, a motion of the foot portion of the robot with respect to a ground in the flight phase descending state is controlled based on a relative speed; if the landing motion state is a support phase landing state, a motion of joints of the robot in the support phase landing state is controlled based on a first expected joint torque. The footed robot landing control method and device are capable of reducing the impact of the foot portion against the ground, thereby realizing the flexible control of the landing process of the footed robot in a simple and rapid manner and reducing the cost of the footed robot.

Abstract: A mobile robot and method for interactively providing waypoints to a mobile robot for use in the marking of a geometric figure on a ground surface including the steps of: i) Selecting a control function accepting manual positioning of a mobile robot at two or more target locations on a ground surface; ii) Positioning the mobile robot in proximity to a first target location to be marked on a surface, and directing a position determining device of the mobile device to said first target location to be marked; iii) Instructing the mobile robot to store the first target location as a first waypoint; iv) Repeating steps ii)-iii) to obtain at least a second waypoint; v) Selecting a control function accepting manual selection of a geometric figure for being marked on said ground surface; vi) Instructing the mobile robot to compute the best fit for the selected geometric figure on the surface based on the two or more waypoints; vii) Instructing the mobile robot to compute waypoint coordinates of the geometric figure f

Abstract: A computer-implemented method executed by a robotic system for performing a positional search process in an assembly task is presented. The method includes applying forces to a first component to be inserted into a second component, detecting the forces applied to the first component by employing a plurality of force sensors attached to a robotic arm of the robotic system, extracting training samples corresponding to the forces applied to the first component, normalizing time-series data for each of the training samples by applying a variable transformation about a right tilt direction, creating a time-series prediction model of transformed training data, applying the variable transformation with different directions for a test sample, and calculating a matching ratio between the created time-series prediction model and the transformed test sample.