In some aspects, a control algorithm is provided for manipulating a pair of articulation arms configured to control an articulation angle of an end effector of a robotic surgical instrument. Other aspects of the present disclosure focus on the robotic arm system, including the pair of articulation arms coupled to the end effector and guided by independent motors controlled by a control circuit. Each of the articulation arms are designed to exert antagonistic forces competing against each other that are apportioned according to a ratio specified in the control algorithm. The ratio of the antagonistic forces may be used to determine the articulation angle of the head or end effector of the robotic surgical arm.

A control system for a robotic surgical system is disclosed. The control system includes a control circuit configured to determine a closure force applied to a closure member, determine a position of a firing member, and set a new closure force based on the closure force applied to the closure member and the position of the firing member.

A robotic control system for a surgical system includes a control system, a control circuit, and a proportional, integral, derivative (PID) feedback control system. The control circuit determines actual closure force of a closure member, compares the actual closure force to a threshold, determines a set point velocity to displace the closure member based on the comparison, and controls the actual velocity of the closure member based on the set point velocity. A force sensor measures the closure force. A threshold closure force includes upper and lower thresholds. The set point velocity is configured to advance the closure member distally when the actual closure force is less than the lower threshold. The set point velocity is configured to retract the closure member proximally when the actual closure force is greater than the lower threshold.

The present disclosure provides a robotic surgical system that includes a control circuit configured to detect a condition at an end effector during a closure phase. The control circuit detects a condition at an end effector during a closure phase. The control sets command velocity of a motor coupled to a displacement member coupled to the end effector based on the detected condition at the end effector during the closure phase. The control circuit fires the displacement member at the set command velocity and detects a condition at the end effector during a firing phase. The control circuit sets command velocity of the motor based on the condition detected at the end effector during the firing phase.

A controller controls a first device, one of an endoscope and a treatment instrument being the first device, a remaining one of the endoscope and the treatment instrument being a second device, the endoscope comprising an insertion tube and a self-propelled mechanism adapted to generate force for insertion or removal of the insertion tube. The controller includes a determination unit configured to determine whether or not the second device is functioning; and a control unit configured to restrict an operation of the first device if the second device is determined to be functioning.

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 torque wrench for use in driving fasteners is provided. The wrench includes an electronics unit disposed within a housing engaged with the body of the wrench that is capable of sensing and measuring the torque applied to a fastener by the wrench and providing an output of the level of torque to the user. The data sensed by the electronics unit can be utilized to provide feedback to the user regarding the operation of the wrench, and to monitor the overall operation of the wrench for calibration purposes, among other functions. During use, the wrench can provide the user with visual, audible and tactile feedback regarding the operation of the device relative to stored maximum torque values stored in the electronics unit. The housing for the electronics unit can be formed to be a single use component of the tool or can be designed for multiple uses with a configuration that can be engaged with cradles forming the body of the wrench having various different configurations.

Surgical systems and methods for generating a tool path. A manipulator is configured to support and move a surgical instrument. Controller(s) obtain data that defines a volume of tissue to be removed from a surgical site. The controller(s) operate the manipulator to move the surgical instrument to remove first portions of the volume and acquire data defining the first portions removed from the volume. The controller(s) identify, based on the volume and the acquired data, additional portions of the volume of tissue that require removal. The controller(s) generate a tool path that passes through the additional portions and operate the manipulator to move the surgical instrument along the tool path to remove the additional portions.

A surgical robot system includes a surgical robot having a robot base and a robot arm connected to the robot base. The surgical robot system further includes a joint manipulation arm configured to be attached to the robot arm and to be connected to an appendage of a patient and moved to apply force and/or torque to a joint connecting the appendage through movement of the robot arm. The surgical robot system further includes force and/or torque sensor apparatus configured to output a feedback signal providing an indication of an amount of force and/or torque that is being applied to the robot arm and/or the joint manipulation arm. At least one controller is configured to determine ligaments balancing at the joint based on a plurality of measurements of the feedback signal, and to output information characterizing the ligaments balancing.

Disclosed is a surgical system, comprising an end effector configured to grasp tissue and provide therapeutic treatment to tissue. The surgical system further comprises a motor, a motor drive circuit, and a motor control circuit. The motor control circuit is configured to provide a motor drive signal to the motor drive circuit and adaptively control elements of the motor drive circuit to control deceleration of the motor in the absence of the motor drive signal. When the motor drive signal is present, the motor drive circuit can be configured to pass the motor drive signal through to the motor.