Increased robotic sophistication and more efficient autonomous operation is implemented by providing separate physical autonomous robots shared and remote access to the sensory array and information from the sensory array of one another. Each robot can access a sensor of any other robot, or scans or other information obtained from the sensor of any other robot. The robots leverage the shared sensory access in order to perform batch order fulfillment, dynamic rearrangement of item or tote locations, and opportunistic charging. These coordinated robotic operations based on the shared sensory access increase the efficiency and productivity of the robots without adding resources or hardware to the robots, increasing the speed of the robots, or increasing the number of deployed robots.

An operation support device includes a connecting body in which a first support body and a second support body are detachably connected to each other; a first shaft engaging section; a shaft connecting member having a connection engaging section engaged with the first shaft engaging section; and a shaft fixing member. The shaft fixing member is movably installed with respect to a first shaft section or a second shaft section and is configured to selectively form a shaft engagement fixing state in which the connection engaging section is held down to retain an engagement state such that the connection engaging section is engaged with the first shaft engaging section and a second state in which holding down to the connection engaging section is released in accordance with a moved position with a moved position of the shaft fixing member.

A robot system control method includes a first step through a fifth step. Particularly in the second step, a second transformation matrix that represents the positional relation between a first slave robot and a second slave robot is generated and stored in a master robot. In the fourth step, based on a second command obtained using a first transformation matrix and the second transformation matrix, the master robot instructs the second slave robot to operate. In the fifth step, the first slave robot and the second slave robot perform a cooperative operation with the master robot. Thus, in the state where a working robot that can perform TCP matching with only part of the other robots is set to a master robot, all of the robots can perform a cooperative operation.

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.

A surgical instrument device includes a surgical instrument portion which is used in a surgical operation, a slave arm which holds the surgical instrument, a driving rod which is formed in a shaft shape, of which one end portion in the axial direction is connected to the surgical instrument and the other end portion in the axial direction is supported by the slave arm, and which transmits a force between the surgical instrument and the slave arm, a distance change detecting unit which detects a change in distance between two points in the axial direction of the driving rod based on a distance when no load is applied to the surgical instrument, and a force calculating unit which calculates a force applied from the surgical instrument or the slave arm to the driving rod based on the change in distance detected by the distance change detecting unit.

A method and apparatus for performing manufacturing functions on a workpiece. The apparatus may comprise a base, a plurality of autonomous functional components, and a plurality of autonomous movement systems. Each functional component of the plurality of autonomous functional components may be configured to perform a respective function. The plurality of autonomous movement systems may be associated with the base. Each of the plurality of autonomous movement systems may be connected to a respective functional component of the plurality of autonomous functional components.

A method and cooperative system for deploying a mobile robot of a plurality of mobile robots with a plurality of fixed sensors. The method includes broadcasting a position-request message including a request for a position and a demand for mobile robots, receiving the position-request message, and transmitting a position-demand message. The method also includes receiving position-demand messages from corresponding fixed sensors, determining a distance to the corresponding fixed sensors, storing information for the corresponding fixed sensor in a fixed sensor list when the distance to the corresponding fixed sensor is less than a predetermined distance, determining a closest fixed sensor, transmitting an association request message to the closest fixed sensor, receiving the association request message, and transmitting a confirmation message when the demand of the closest fixed sensor is not equal to zero or a rejection message when the demand of the closest fixed sensor is equal to zero.

A telerobotic communications system including a teleoperation center to transmit control data and receive non-control data by wireless connection to and from a first mobile telerobot and indirectly to and from a second mobile telerobot. The first mobile telerobot includes a transceiver for receiving and transmitting control and non-control data, respectively, and also a repeater for relaying control data to a second mobile telerobot and relaying non-control data back to the teleoperation center. The system allows the second mobile telerobot to travel beyond a communications-enabled distance of the wireless signal emitted directly by the teleoperation center. The system may also include wireless repeaters to extend the communications distance between the first and second telerobots.

A surgical system includes a robotic device, and a surgical tool coupled to the robotic device and comprising a distal end. The system further includes a neural monitor configured to generate an electrical signal and apply the electrical signal to the distal end of the surgical tool, wherein the electrical signal causes innervation of a first portion of a patient's anatomy which generates an electromyographic signal, and a sensor configured to measure the electromyographic signal. The neural monitor is configured to determine a distance between the distal end of the surgical tool and a portion of nervous tissue based on the electrical signal and the electromyographic signal, and cause feedback to be provided to a user based on the distance.

A manipulator system configured to perform a work to a workpiece being moved by a moving device, includes a robotic arm, having one or more joints and to which a tool configured to perform the work to the workpiece is attached, an operating device configured to operate the robotic arm, a first imaging means configured to image the workpiece, while following the movement of the workpiece, a second imaging means fixedly provided in a work area to image a situation of the work to the workpiece, a displaying means configured to display an image imaged by the first imaging means and an image imaged by the second imaging means, and a control device configured to control the operation of the robotic arm based on an operating instruction of the operating device, while detecting a moving amount of the workpiece being moved by the moving device and carrying out a tracking control of the robotic arm according to the moving amount of the workpiece.