An ultrasonic surgical device includes a power source configured to generate power, an ultrasonic transducer electrically coupled to the power source and generating ultrasonic motion in response to the generated power, a sensor sensing current of the generated power supplied to the ultrasonic transducer, an ultrasonic probe mechanically couplable to the ultrasonic transducer, and a controller that receive a sensed current from the sensor, performs a frequency response analysis based on the sensed current, calculates a first resonant frequency and a first anti-resonant frequency of the transducer prior to coupling the ultrasonic probe based on the frequency response analysis, calculates a second resonant and second anti-resonant frequencies of the transducer based on the frequency response analysis prior to determining coupling to the ultrasonic transducer, and determines whether the ultrasonic probe is mechanically coupled to the ultrasonic transducer based on the first and second resonant and anti-resonant frequencies.

A device including smart sensors with a local signal processor is disclosed. The device includes an end-effector including at least one sensor and a signal processing component corresponding to the at least one sensor; and a handle configured to receive processed information from the signal processing component. The processed information is generated by the signal processing component at the end-effector based on data received from the at least one sensor at the end-effector.

A surgical instrument that includes an end effector and a trigger that is actuatable between a first position and a second position. An actuation drive is movable between an unactuated position and an actuated position in response to actuation of the trigger. A toggle assembly is transitionable between a folded configuration and an expanded configuration, wherein the toggle assembly is configured to motivate the actuation drive to effectuate a movement in the end effector in the folded configuration. The toggle assembly being configured to bypass the actuation drive when in the expanded configuration. A resetting member is operable to return the toggle assembly to the folded configuration.

A method comprising receiving an input coupling adjacent to a drive input driven by an actuating element, the input coupling being coupled to a joint output and the joint output being connected to a movable object. The method further comprising rotating the actuating element to drive the drive input and determining, by a control system, whether a resistance torque greater than an inherent drivetrain resistance torque is experienced by the actuating element. The inherent drivetrain resistance torque is for a drivetrain including the input coupling, the drive input, and the joint output. The method also includes determining, by the control system, whether the drive input has engaged the input coupling based on the determination that the resistance torque greater than the inherent drivetrain resistance torque has been experienced by the actuating element.

Generally, a sterile adapter for use in robotic surgery may include a frame configured to be interposed between a tool driver and a surgical tool, a plate assembly coupled to the frame, and at least one rotatable coupler supported by the plate assembly and configured to communicate torque from an output drive of the tool driver to an input drive of the surgical tool.

A tool for implementing a correction plan in an external fixation frame having a plurality of adjustment elements or screws, for example, generally includes a driver, a motor, a controller, and a processor. The driver is adapted to engage and rotate each of the screws. The motor is coupled the driver and adapted to rotate the driver. The controller is connected to the motor and configured to control operation of the motor. The controller may determine whether the tool is engaged with a strut and which strut is engaged, and may determine how much the strut has rotated, taking into account intentional or unintentional manual rotation of the tool. The tool may also include features to help ensure proper engagement between the drive and the strut. Variations may be provided in which similar functionality is provided with manual rotation of a motorless tool.

A surgical instrument system that includes a housing and a rotatable drive shaft, a motor operably coupled to the drive shaft, and a plurality of replaceable end effectors that can be connected to the housing. Each replaceable end effector includes a drive screw that is turned a fixed number of revolutions by the motor-driven rotatable drive shaft when the end effector is connected to the housing. Each end effector further comprises a firing member operably coupled with the drive screw of the end effector. The drive screw is configured to displace the firing member over a firing length as a result of the fixed number of revolutions. In certain embodiments, each replaceable end effector can include a drive screw with a thread pitch set to the firing length divided by the fixed number of revolutions.

A measuring system having a measuring tool with a probe body and an optical marker, a camera for recording image data of the measuring tool, and an evaluation and control unit which is configured to evaluate the image data recorded by the camera and use the image data for determining, with the aid of the optical marker, position data of the probe body which contain the spatial position coordinates of the probe body. The evaluation and control unit is further configured to calculate speed data and/or acceleration data of the probe body from the position data of the probe body and to determine, on the basis of the speed data and/or acceleration data of the probe body, whether or not probing is present in which the probe body makes contact with a measurement object for the purpose of capturing a measuring point.

A system and method are provided for determining one or more characteristics of a device. The system and method comprises initiating an algorithm to correct for shift and drift of a reference catheter (203), determining an initial shape and position of a portion of the reference catheter at time 0 when the algorithm is initiated (201), determining a current shape and position of the portion of the reference catheter at time t after the algorithm has been initiated (205), calculating a closest fit of the current shape and position of the portion of the reference catheter to the initial shape and position of the portion of the reference catheter by iteratively adjusting a set of solution parameters (209), and determining a minimal error solution parameter (211).

A surgical stapling device includes an anvil assembly including an anvil shaft and an anvil head assembly that is supported on a distal end portion of the anvil shaft. The anvil shaft defines a longitudinal axis and supports a first spline, a second spline, and a third spline. Each of the first, second, and third splines includes a pair of tapered camming surfaces that meet at a proximal end of the respective spline to define an apex. The apex of the first spline is positioned on the anvil shaft at a location proximal of the apex of the second spline, and the apex of the second spline is positioned on the anvil shaft at a location proximal of the apex of the third spline. In embodiments, each of the splines includes an apex. The apex of the first spline is aligned with a longitudinal axis of the first spline and the apex of the second and third splines are aligned with a longitudinal axis of the second and third splines, respectively.