Source: https://patents.google.com/patent/JP2017514542A/en
Timestamp: 2019-11-21 02:09:38
Document Index: 140475751

Matched Legal Cases: ['Application No. 61', 'Application No. 62', 'Application No. 61', 'Application No. 62', 'art 210', 'art 210', 'art 210', 'art 210', 'art 210', 'art 210', 'art 210', 'art 210', 'art 210', 'art 300', 'art 300']

JP2017514542A - System and method for meeting reference goals - Google Patents
System and method for meeting reference goals Download PDF
JP2017514542A
JP2017514542A JP2016557122A JP2016557122A JP2017514542A JP 2017514542 A JP2017514542 A JP 2017514542A JP 2016557122 A JP2016557122 A JP 2016557122A JP 2016557122 A JP2016557122 A JP 2016557122A JP 2017514542 A JP2017514542 A JP 2017514542A
JP2016557122A
JP2017514542A5 (en
ハナスチック，マイケル
アール ニクソン，トーマス
2015-03-17 Priority to PCT/US2015/021097 priority patent/WO2015142947A1/en
2017-06-08 Publication of JP2017514542A publication Critical patent/JP2017514542A/en
2018-04-19 Publication of JP2017514542A5 publication Critical patent/JP2017514542A5/ja
A system and method for meeting reference goals includes a computer-aided medical device. The computer-aided medical device is located at the orientation platform, one or more first joints proximal to the orientation platform, one or more second joints distal to the orientation platform, distal to the orientation platform One or more links, a second joint and a reference instrument coupled to the orientation platform by the link, and a control unit coupled to the first joint and the second joint. The control unit determines the attitude of the reference instrument. The posture includes a reference point and a reference direction. The control unit further positions the orientation platform over the reference point using the first joint, rotates the orientation platform to align the orientation platform in the reference direction using the first joint, and the second joint. Use to maintain the posture of the reference instrument.
This disclosure includes US Provisional Application No. 61/952611, entitled “System and Method for Aligning with a Reference Target” filed on March 17, 2014, and “System and Method for Aligning with a Reference Target” filed on July 15, 2014. and claims for priority to US Provisional Application No. 62/024887 entitled “Method and Aligning with a Reference Target”, all of which are incorporated herein by reference.
The present disclosure relates generally to the operation of devices with articulated arms, and more specifically to meeting reference goals.
More and more devices are being replaced by autonomous and semi-autonomous electronic devices. This is especially true in today's hospitals where there are many autonomous and semi-autonomous electronic devices found in operating rooms, intervention rooms, intensive care units, emergency rooms and the like. For example, thermometers made of glass and mercury have been replaced with electronic thermometers, intravenous drip lines now include electronic monitors and flow regulators, and traditional handheld surgical instruments have been replaced with computer-assisted medical devices. Yes.
These electronic devices offer both advantages and challenges to those who operate them. Many of these electronic devices may allow autonomous or semi-autonomous operation of one or more articulated arms and / or end effectors. Before these articulated arms and their end effectors are used, they are typically moved to or near the desired working position and orientation. This movement may be performed by remote operation or remote operation using one or more user input controls. The complexity of these electronic devices is increasing, and the articulated arm includes many degrees of freedom, so movement to the desired working position and direction by remote control is complex and / or time consuming. Can be. Also, the operators of these electronic devices may not necessarily be aware of the movement limits of one or more of the end effectors, such as a multi-joint arm or a medical instrument coupled to the multi-joint arm. As a result, the operator may not be able to provide the best initial working position of the articulated arm that provides the optimal range of motion after setup.
US Provisional Application No. 61 / 95,261 US Provisional Application No. 62/024887
Accordingly, improved methods and systems for the initial positioning of articulated arms and their end effectors are desired.
In accordance with some embodiments, a computer-aided medical device includes an orientation platform, one or more first joints proximal to the orientation platform, and one or more second joints distal to the orientation platform. A joint, one or more links distal to the orientation platform, a reference instrument coupled to the orientation platform by a second joint and link, and a control unit coupled to the first joint and the second joint. Including. The control unit determines the attitude of the reference instrument. The posture includes a reference point and a reference direction. The control unit further positions the orientation platform over the reference point using the first joint, rotates the orientation platform to align the orientation platform in the reference direction using the first joint, and the second joint. Use to maintain the posture of the reference instrument.
According to some embodiments, a method for controlling movement in a medical device includes determining a posture of a reference device of the medical device. The posture includes a reference point and a reference direction. The method further includes positioning the orientation platform of the medical device over the reference point using one or more first joints, and aligning the orientation platform to align the orientation platform with the first joint using the first joint. Rotating and maintaining the posture of the reference instrument using one or more second joints. The one or more first joints are proximal to the orientation platform. The one or more second joints are distal to the orientation platform and proximal to the reference device.
According to some embodiments, the non-transitory machine readable medium causes the one or more processors to perform a method when executed by the one or more processors associated with the medical device. A plurality of machine readable instructions configured. The method includes determining a posture of a reference instrument of a medical device. The posture includes a reference point and a reference direction. The method further includes positioning the orientation platform of the medical device over the reference point using one or more first joints, and aligning the orientation platform to align the orientation platform with the first joint using the first joint. Rotating and maintaining the posture of the reference instrument using one or more second joints. The one or more first joints are proximal to the orientation platform. The one or more second joints are distal to the orientation platform and proximal to the reference device.
1 is a simplified diagram of a computer aided device according to some embodiments. FIG. FIG. 6 is a simplified diagram illustrating a computer-aided device according to some embodiments. FIG. 3 is a simplified diagram illustrating a top view of the orientation platform orientation of FIG. 2 prior to goal setting operations in accordance with some embodiments. FIG. 3 is a simplified diagram illustrating a top view of the orientation platform of FIG. 2 after a goal setting operation in accordance with some embodiments. FIG. 6 is a simplified diagram of a method for meeting a reference goal according to some embodiments. FIG. 6 is a simplified diagram of a process for maintaining the posture of a reference instrument during movement of an orientation platform according to some embodiments.
In the drawings, elements having the same symbol display have the same or equivalent functions. In the following description, specific details are set forth describing some embodiments according to the disclosure. However, it will be apparent to one skilled in the art that several embodiments may be practiced without some or all of these specific details. The specific embodiments disclosed herein are intended to be illustrative and not limiting. Those skilled in the art may implement other elements not specifically described herein but which are within the scope and spirit of the present disclosure. Also, to avoid unnecessary repetition, the one or more features illustrated and described in connection with one embodiment are not specifically described unless specifically stated otherwise. Unless an embodiment is non-functional, it can be incorporated into other embodiments.
FIG. 1 is a simplified diagram of a computer-aided system 100 according to some embodiments. As shown in FIG. 1, the computer-aided system 100 includes a device 110 having one or more movable or articulated arms 120. Each of the one or more articulated arms 120 may support one or more end effectors. In some examples, the device 110 may be consistent with a computer-assisted surgical device. The one or more articulated arms 120 each provide a support for surgical instruments, imaging devices, and / or the like. The apparatus 110 may further be coupled to an operator workstation (not shown). The operator workstation may include a device 110, one or more articulated arms 120, and / or one or more master controls for operating the end effector. In some embodiments, the device 110 and operator workstation may be compatible with the da Vinci® Surgical System marketed by Intuitive Surgical, Inc., Sunnyvale, California. In some embodiments, computer assisted surgical devices having other configurations, fewer or more articulated arms, and / or the like may be used with computer assisted system 100.
Device 110 is coupled to control unit 130 via an interface. The interface may include one or more cables, connectors, and / or buses, and may further include one or more networks with one or more network switching devices and / or routing devices. Control unit 130 includes a processor 140 coupled to memory 150. The operation of the control unit 130 is controlled by the processor 140. Although the control unit 130 is shown with only one processor 140, the processor 140 is one or more central processing units, multi-core processors, microprocessors, microcontrollers, digital signal processors, field programmable processors in the control unit 130. It should be understood that a gate array (FPGA), application specific integrated circuit (ASIC), and / or the like may be representative. The control unit 130 may be implemented as a stand-alone subsystem and / or board added to the computing device, or as a virtual machine. In some embodiments, the control unit may be included as part of the operator workstation and / or may be operated separately from the operator workstation in cooperation with the operator workstation.
The memory 150 may be used to store software executed by the control unit 130 and / or one or more data structures used during operation of the control unit 130. Memory 150 may include one or more types of machine readable media. Some common forms of machine-readable media are floppy disks, flexible disks, hard disks, magnetic tapes, any other magnetic media, CD-ROMs, any other optical media, punch cards, paper tapes, hole patterns Any other physical medium having RAM, PROM, EPROM, FLASH-EPROM, any other memory chip or cartridge, and / or any other medium configured to be readable by a processor or computer .
As shown, the memory 150 includes a motion control application 160 that can be used to support autonomous and / or semi-autonomous control of the device 110. The motion control application 160 receives position, motion, and / or other sensor information from the device 110, exchanges position, motion, and / or anti-collision information with other control units for other devices, and / or , Device 110, articulated arm 120, and / or one or more application programming interfaces (APIs) for planning and / or assisting with planning for the end effector of device 110. Moreover, although the exercise | movement control application 160 is represented as a software application, the exercise | movement control application 160 may be implement | achieved using the combination of hardware, software, and / or hardware and software.
In some embodiments, the computer-aided system 100 can be found in an operating room and / or interventional suite. The computer support system 100 also includes a single device 110 having two articulated arms 120, but the computer support system 100 is similar to the device 110 and / or has a different design than the device 110. Those skilled in the art will appreciate that and / or may include any number of devices having end effectors. In some examples, each of the devices may include fewer or more articulated arms and / or end effectors.
FIG. 2 is a simplified diagram illustrating a computer aided device 200 according to some embodiments. For example, the computer support apparatus 200 may coincide with the computer support apparatus 110. As shown in FIG. 2, the computer aided device 200 includes various links and joints. Computer aided devices typically have three different sets of links and joints. Beginning with the movable cart 210 at the proximal end is a setup structure 220. Coupled to the distal end of the setup structure is a series of setup joints 240. Also coupled to the distal end of the setup joint 240 is a manipulator 260, such as a universal surgical manipulator. In some examples, the series of setup joints 240 and manipulators 260 may correspond to one of the articulated arms 120. Also, although the computer support apparatus 200 is shown with only one series of setup joints 240 and corresponding manipulators 260, the computer support apparatus 200 can include a plurality of articulated arms. Those skilled in the art will appreciate that 200 may include two or more series of setup joints 240 and corresponding manipulators 260.
As illustrated, the computer support apparatus 200 is mounted on a movable cart 210. The movable cart 210 is moved from one position to another, such as between operating rooms or in an operating room, for example, to position the computer supporting apparatus 200 in a better position near the patient table. Like that. The setup structure 220 is mounted on the movable cart 210. As shown in FIG. 2, the setup structure 220 includes a two-part strut that includes strut links 221 and 222. Coupled to the upper or distal end of the strut link 222 is a shoulder joint 223. Coupled to the shoulder joint 223 is a two-part boom including boom links 224, 225. At the distal end of the boom link 225 is a wrist joint 226, which is coupled to the orientation platform 227.
The links and joints of the setup structure 220 include multiple degrees of freedom for changing the position and orientation (ie, attitude) of the orientation platform 227. For example, a two part strut can be used to adjust the height of the orientation platform 227 by moving the shoulder joint 223 up and down along the axis 232. Orientation platform 227 may additionally be rotated around movable cart 210, two-part strut, and axis 232 using shoulder joint 223. The horizontal position of the orientation platform 227 can also be adjusted along the axis 234 using a two-part boom. The orientation of orientation platform 227 can also be adjusted by rotation about axis 236 using wrist joint 226. Thus, depending on the link and joint motion limits in the setup structure 220, the position of the orientation platform 227 can be adjusted vertically on the movable cart 210 using a two-part strut. Also, the position of the orientation platform 227 can be adjusted radially and angularly about the movable cart 210 using a two-part boom and shoulder joint 223, respectively. The angular direction of the orientation platform 227 can also be changed by using the wrist joint 226.
Orientation platform 227 may be used as an attachment point for one or more articulated arms. The ability to adjust the height, horizontal position, and orientation of the orientation platform 227 with respect to the movable cart 210 positions and orients one or more articulated arms around a workspace such as a patient positioned near the movable cart 210. Provides a flexible setup structure for attaching. FIG. 2 shows a single articulated arm coupled to an orientation platform using a first setup joint 242. Also, although only one articulated arm is shown, those skilled in the art will appreciate that multiple articulated arms may be coupled to the orientation platform 227 using an additional first setup joint. One example is described in more detail with reference to FIGS. 3A and 3B.
The first setup joint 242 forms the most proximal portion of the setup joint 240 that is part of the articulated arm. The setup joint 240 may further include a series of joints and links. As shown in FIG. 2, the setup joint 240 includes at least links 244, 246 coupled via one or more joints (not explicitly shown). The joints and links of the setup joint 240 provide the ability to rotate the setup joint 240 about the orientation platform 227 about the axis 252 using the first setup joint 242, the height of the link 246 relative to the orientation platform along the axis 254. Including the ability to adjust and the ability to rotate the manipulator at least about axis 256 at the distal end of link 246. The setup joint 240 may further include additional joints, links, and axes that provide additional degrees of freedom for changing the attitude of the manipulator 260 with respect to the orientation platform 227.
The manipulator 260 is coupled to the distal end of the setup joint 240 and includes additional links and joints that allow control of the posture of an end effector or instrument 262 mounted on the distal end of the manipulator 260. The degree of freedom in the manipulator 260 may at least allow control of the roll, pitch, and yaw of the instrument 262 with respect to the distal end of the setup joint 240. In some examples, the degree of freedom in manipulator 260 may further include the ability to advance and / or retract instrument 262 with respect to the longitudinal axis of instrument 262. In some examples, the degrees of freedom in the setup joint 240 and manipulator 260 may be further controlled to maintain a remote center 270 with respect to a point on the instrument 262. In some examples, the remote center 270 is operated on the patient so that the remote center 270 remains stationary to limit the pressure on the patient's anatomy at the remote center 270 when the instrument 262 is used. It can correspond to a port. In some examples, the manipulator 260 may be consistent with a universal surgical manipulator used with the da Vinci® Surgical System marketed by Intuitive Surgical, Inc., Sunnyvale, California. In some examples, the instrument 262 is an imaging device such as an endoscope, a gripper, a surgical tool such as a cautery or a scalpel, and / or the like. There may be.
Even if the setup structure 220, the setup joint 240, and the manipulator 260 are given a large number of degrees of freedom, the attitude of the manipulator 260, and more importantly, the attitude of the instrument 262 is maintained as desired. Determining the best position of each joint is not always an easy task. Further, if the desired postures of manipulator 260 and instrument 262 are adjusted during operation of the computer aided device, the desired posture is not reached without reaching the limit of the range of motion of either joint in setup joint 240 or manipulator 260. Appropriate flexibility in the range of motion and direction should be available as obtained. For this implementation, the joints in the setup joint 240 and the manipulator 260 are positioned near the center of their respective range of motion, while at the same time establishing the desired posture of the instrument 262 and / or the location of the remote center 270. Alternatively, to maintain, the setup structure 220 and orientation platform attitude are typically selected during the setup phase or during the goal setting operation. In the computer aided device 200 in FIG. 2, this is such that the approximate center of rotation of the orientation platform 227 (eg, the axis 236 about which the wrist joint 226 rotates) is positioned vertically above the remote center 270. The orientation of the orientation platform 227, the setup joint 240, and the manipulator 260 can be roughly accommodated. The orientation platform 227 is then rotated so that the first setup joint 242 is approximately near the center of its movement. In some examples, the height of orientation platform 227 may be further adjusted with respect to remote center 270 to an appropriate working height.
3A and 3B are simplified diagrams illustrating top views of the orientation of the orientation platform 227 of FIG. 2 before and after a goal setting operation according to some embodiments. FIG. 3A shows a posture before a target setting operation of a part 300 of a computer support apparatus such as the computer support apparatus 200. The computer aided device portion 300 shown in FIG. 3A corresponds to the portion of the computer aided device beginning with the orientation platform 227 and the links and joints distal to the orientation platform 227. As shown in FIG. 3A, four articulated arms 310-340 are coupled to orientation platform 227, but those skilled in the art will appreciate that any other number of articulated arms may be used. . Each of the four articulated arms 310-340 may include a separate setup joint, manipulator, and / or instrument. As shown, the four articulated arms include two inner arms 320, 330 positioned between two outer arms 310, 340. The instrument on one of the articulated arms 310-340, typically one of the inner arms 320, 330, is selected as the reference target for the goal setting operation. For simplicity of explanation, the instrument 262 on the articulated arm 320 is selected as the reference target, but any instrument on the other articulated arm may be selected as the reference target.
Before the goal setting operation begins, the instrument 262 and the remote center 270 are typically positioned and oriented within the workspace to assist in identifying a region of interest in the workspace. In some examples, instrument 262 and remote center 270 may be positioned and / or oriented with respect to the patient's anatomy. In some examples, the instrument 262 may be inserted through the surgical port with the remote center 270 positioned at the surgical port on the patient. In some examples, a physician and / or other medical personnel may use the articulated arm 320 clutch feature to manually position and direct the instrument 262 and remote center 270. In some examples, instrument 262 may correspond to an endoscope, and the endoscope may be positioned and / or oriented toward a target portion of the patient's anatomy. After the instrument 262 is positioned and oriented, the position during the goal setting operation is reduced to reduce the possibility of causing injury to the patient and / or the possibility of damaging the instrument 262. And maintaining direction is important. In some examples, the remote center 270 may correspond to the position of the instrument 262 and the orientation axis 360 may correspond to the direction of the instrument 262 for purposes of goal setting operations. Orientation axis 360 is aligned with the shaft of instrument 262. In some examples, once instrument 262 has been positioned and oriented, the physician and / or other medical personnel can use goal-setting operations with controls positioned on articulated arm 320 and / or the operator console. May be started.
In some embodiments, one goal of the goal setting operation is to adjust the rotation center 350 of the orientation platform 227, such as the rotation center of the wrist joint 226, to be vertically above the remote center 270. possible. Another purpose of the goal setting operation may be to rotate the orientation platform 227 so that the front surface of the orientation platform 227 matches the horizontal component of the orientation axis 360. In some examples, this orientation purpose may be omitted if the orientation axis 360 is vertical. In some examples, the front direction may correspond to the front direction vector 370. In some examples, this rotation may direct the articulated arms 310-340 near the center of the respective range of motion of the first setup joint. In some examples, an additional purpose of the goal setting operation is to increase the orientation platform 227 height relative to the remote center 270 to place the vertical adjustment joint in the articulated arm 320 near the respective center of their range of motion. Adjusting the height and providing an appropriate working distance between the orientation platform 227 and the remote center 270 to provide adequate space for maneuvering the articulated arm 320 without collision with the orientation platform 227 Providing proper separation of the orientation platform 227 and the remote center 270 to maintain a sterile area around the remote center 270 and / or distant from the orientation platform 227 as determined by the operator It may be to maintain a predetermined distance between the center 270.
FIG. 3B shows the change in position and direction of part 300 of the computer-assisted device as a result of the target setting operation. As shown, the rotation center 350 of the orientation platform 227 is moved to coincide with the remote center 270 in the vertical direction. Further, the orientation platform 227 is rotated so that the front direction vector 370 matches the horizontal component of the orientation axis 360. FIG. 3B further shows that the positions of the various joints of the setup joint and manipulator in the articulated arm 320 are changed to offset changes in the relative position and orientation of the instrument 262 relative to the orientation platform 227.
To achieve these objectives, the position of the remote center 270 and the direction of the orientation axis 360 are determined by a sensor that monitors the position of the joint in the computer aided device and one or more kinematic models of the computer aided device. To be determined. The joint in the setup structure proximal to the orientation platform 227 is adjusted to move the center of rotation 350 over the remote center 270, and the orientation platform 227 has a frontal vector on the horizontal component of the orientation axis 360. 370 is rotated to match. In some examples, the joints in the setup structure can be adjusted to change the height of the orientation platform 227. In some examples, if the setup structure corresponds to the setup structure 220 of FIG. 2, the center of rotation 350 may be matched by changing the length of the two-part boom and rotating the shoulder joint 223; The orientation platform 227 may be rotated using the wrist joint 226 and the height of the orientation platform 227 may be adjusted using a two-part strut. While the setup structure is being moved, the setup joints and manipulator joints in the articulated arm 320 are adjusted to offset the movement and redirection of the orientation platform 227. This is done to maintain the fixed position of the remote center 270 and the fixed direction of the orientation shaft 360 even when the relative position and orientation of the instrument 262 with respect to the orientation platform 227 is changing. In some examples, joint sensors and one or more kinematic models and / or an inverse Jacobian transpose matrix may be used to determine joint changes in setup joints and manipulators. In some examples, the location of the remote center 270 and the orientation of the orientation axis 360 are further maintained using resistance from the patient port and / or by a physician and / or by other medical personnel. May be. Other articulated arms 310, 330, and / or 340 may also move with orientation platform 227. In some embodiments, an anti-collision algorithm is used to prevent collisions between the articulated arms 310-340 and between the articulated arms 310-340 and the setup structure proximal to the orientation platform 227. May be used.
In some embodiments, one or more joints in the articulated arms 310-340 may be left floating when the orientation platform 227 is moving. In the floating state, there is a free movement and / or almost free movement of each of the joints. In some examples, the joints that are placed in a floating state may be a subset of the joints in each of the articulated arms 310-340. In some examples, this allows these joints to react to reduce and / or mitigate the effects of external stimuli applied to each of the articulated arms 310-340. In some examples, the brakes applied to each of the floating joints that are inactive joints may be released to allow the respective movements of the inactive joints. In some examples, each of the floating joints that are non-actuating joints is a value from one or more sensors associated with an articulated joint and / or an articulated arm 310-340, and / or It may be commanded to move to an actual position and / or at an actual speed determined for each joint based on values from one or more kinematic models. In some examples, setting the command position of the feedback controller of the actuating joint to the actual position and / or setting the command speed of the feedback controller to the actual joint speed may cause the actuating joints to move freely. It also gives the impression of an apparent weightlessness when gravity correction is applied.
In some embodiments, floating joint motion may be subject to attenuation. In order to suppress and / or prevent unlimited and / or vigorous movement of the articulated arm when floating, one or more joints placed in the floating state may be subject to some form of damping movement. . For example, it may be undesirable for any of the articulated arms 310-340 exposed to a strong external stimulus, such as a violent collision, to move away from the strong external stimulus without any limitation. Suppressing the floating movement of the articulated arm 310-340 may reduce the risk of injury and / or damage caused by the rapidly moving articulated arm. In some examples, the dampening motion may be performed at the inactive joint by partially releasing the brake to paginate the inactive joint movement. In some examples, the brakes are partially released by controlling one or more of the voltage, current, duty cycle, and / or the like of the signals used to control the brakes. May be. In some examples, the dampening motion is large by commanding the actuating joint to move a small distance behind the actual position based on the direction of motion and / or the stability margin. Introducing reverse current and / or reverse voltage to the actuator of the actuating joint to increase the derivative constant in the feedback controller without affecting and / or to counteract resistance and / or torque And may be performed at that actuation joint. In some examples, the damped motion may be performed at the working joint by commanding the speed of the working joint to be less than the joint speed determined based on the value of the corresponding sensor. Good.
FIG. 4 is a simplified diagram of a method 400 for meeting a reference goal in accordance with some embodiments. One or more processes 410-450 in method 400 may be performed at least in part by one or more of the one or more processors when executed by one or more processors (eg, processor 140 in control unit 130). Can be implemented in the form of executable code stored on a non-transitory, specific machine-readable medium that can cause the processes 410-450 of FIGS. In some examples, method 400 may be performed by an application such as motion control application 160. In some embodiments, the method 400 may include various joint and link positions and / or positions in a setup structure, setup joint, and / or manipulator joint in a computer-aided device while maintaining the posture (position and orientation) of the reference instrument. Can be used to adjust direction.
In process 410, the posture of the reference instrument is determined. The reference goal for the alignment or goal setting operation of the method 400 is based on the attitude (position and orientation) of the reference instrument. The reference instrument is typically located at the distal end of the articulated arm of the computer aided device. In some examples, one or more sensors associated with joints and links in the articulated arm and computer-aided device, and one or more kinematic models of the articulated arm and computer-assisted device are used to determine the position of the reference instrument. And can be used to determine the direction. In some examples, the posture of the reference instrument may be determined based on the reference point on the reference instrument and the reference direction of the reference instrument. In some examples, the reference instrument may be pre-positioned by a computer-assisted device operator, manually or with computer assistance. In some examples, the operator may initiate the process of determining the posture of the reference instrument using one or more control inputs. In some examples, the articulated arm may be the articulated arm 320, the reference instrument may be the instrument 262, and the attitude of the reference instrument may be determined by the remote center 270 and the orientation axis 360.
In process 420, the orientation platform is positioned over the reference point of the reference instrument. In order to better position the orientation platform over the desired workspace for the computer aided device, one or more joints in the computer aided device proximal to the orientation platform are determined during process 410. The computer support device orientation platform is instructed to move so that the computer support device orientation platform is positioned over the reference point. In some examples, the orientation platform may be moved to position a predetermined point on or near the orientation platform vertically above the reference point. In some examples, the predetermined point may be associated with the center of gravity and / or other center point of the orientation platform and / or the axis around which the orientation platform can be rotated. In some examples, positioning the orientation platform may include adjusting the horizontal distance and / or angular position of the orientation platform relative to the central column of the computer-aided device. In some examples, one or more kinematic models and / or motion planning algorithms are used to determine one or more motion commands and / or positioning commands that are transmitted to one or more actuators in a computer-aided device. May be used. In some examples, if the computer-assisted device is computer-assisted device 200, one or more joints in setup structure 220 may be commanded to position the orientation platform horizontally over the remote center. In some examples, the process 420 may include positioning the center of rotation 350 over the remote center 270.
In process 430, the orientation platform is rotated to align the orientation platform with the orientation of the reference instrument. To provide an improved range of motion in the reference instrument, the orientation platform may be rotated to align the orientation platform with the orientation of the reference instrument determined during process 410. In some examples, the orientation platform may be rotated to align a predetermined orientation vector of the orientation platform with the orientation of the reference instrument. In some examples, the orientation platform may be rotated about its axis of rotation. This is so that the first set-up joint of the articulated arm to which the reference instrument is attached is at or near the rotational range of its movement. In some examples, the orientation platform may be rotated using one or more revolute joints, such as a wrist joint proximal to the orientation platform. In some examples, one or more kinematic models and / or motion planning algorithms are used to determine one or more motion commands and / or positioning commands that are transmitted to one or more actuators in a computer-aided device. May be. In some examples, process 430 may be performed concurrently with process 420. In some examples, process 430 may be omitted if the orientation of the reference instrument does not include a horizontal component. In some examples, if the computer aided device is computer aided device 200, orientation platform 227 uses wrist joint 226 to rotate with axis 236 to align front direction vector 370 with the horizontal component of orientation axis 360. It may be rotated about the center 350.
In an optional process 440, the distance between the orientation platform and the reference instrument may be adjusted. In some examples, the distance between the predetermined point on the orientation platform and the reference point of the reference instrument may be adjusted. In some examples, the orientation platform distance is used to position the joints in the articulated arms near the center of their respective range of motion and / or the articulated arm and / or reference instrument and computer. In order to reduce the possibility of a collision with the set-up structure of the support device and / or to help maintain a sterile area around the reference instrument and / or a predetermined distance determined by the operator It may be adjusted to maintain. In some examples, the distance may be a vertical distance between a reference point determined during process 410 and a predetermined point adjusted during process 420. In some examples, the distance between the orientation platform and the reference instrument may be adjusted using one or more joints proximal to the orientation platform. In some examples, one or more kinematic models and / or motion planning algorithms are used to determine one or more motion commands and / or positioning commands that are transmitted to one or more actuators in a computer-aided device. May be used. In some examples, process 440 may be performed concurrently with process 420 and / or process 430.
In process 450, the posture of the reference device is maintained during the movement of the orientation platform. While the orientation platform is moved during processes 420, 430, and / or 440, the orientation of the reference instrument with respect to the workspace for the computer aided device is maintained. Even if the position and / or orientation of the reference device relative to the orientation platform is changing, its posture is maintained. This is in an articulated arm distal to the orientation platform in response to movement of one or more joints proximal to the orientation platform being commanded during processes 420, 430, and / or 440. It can be realized by adjusting one or more joints.
As described above and further emphasized herein, FIG. 4 is merely an example and should not unduly limit the scope of the claims. Those skilled in the art will recognize many variations, alternatives, and improvements. According to some embodiments, one or more of processes 420-450 may be performed simultaneously. According to some embodiments, additional conditions may result in premature termination of method 400, such as by returning control of the computer-assisted device to the operator and / or by stopping operation of the computer-assisted device. is there. In some examples, the additional condition may be that the desired movement cannot be completed, operator manual intervention and / or override using one or more controls at the operator workstation and / or articulated arm, It may include detection of operator detachment from the operator workstation by one or more safety interlocks, location tracking errors in computer aided devices, system failures, and / or the like. In some examples, detection of impending collisions between links and / or joints in a computer-aided device, limiting the range of motion of one or more joints in a computer-aided device, maintaining the posture of the reference instrument during process 450 However, the desired movement may not be possible due to the inability to position and / or orient the orientation platform and / or the like. In some examples, the early termination of method 400 may result in an error notification being sent to the operator. In some examples, the error notification may include a text message, an audible indication, a spoken phrase, and / or the like.
FIG. 5 is a simplified diagram of a process 450 for maintaining the posture of a reference instrument during movement of an orientation platform according to some embodiments. When the orientation platform is positioned and oriented during processes 420, 430, and / or 440, the movement of the orientation platform includes the reference instrument and the articulated arm distal to the orientation platform Affects each of the links and joints in Since these movements result in changes in the posture of the reference instrument, processes 510-550 cancel out those changes so that the posture of the reference instrument is maintained.
In process 510, a reference instrument reference transform is determined. Prior to the start of exercise during processes 420, 430, and / or 440, one or more kinematic models of the computer aided device are used to determine a reference transformation for the reference instrument. In some examples, the one or more kinematic models are one or more for a setup structure proximal to the orientation platform, a setup joint distal to the orientation platform, and / or a manipulator to which the reference instrument is attached. Multiple kinematic models may be included. In some examples, the reference transformation may model the posture of the reference instrument in a world coordinate system with respect to the computer-aided device and / or with respect to a workspace that includes the reference instrument in part.
In process 520, the actual conversion of the reference instrument is determined. When a joint proximal to the orientation platform is commanded during processes 420, 430, and / or 440, the orientation of the reference instrument begins to change because the reference instrument is distal to the orientation platform. Their commanded changes in joint positions and / or angles of joints proximal to the orientation platform are monitored and one or more kinematic models are reapplied to determine the actual transformation of the reference instrument Is done. The actual transformation represents how the movements in processes 420, 430, and / or 440 tend to move the reference instrument away from its desired posture.
In process 530, the difference between the actual transformation and the reference transformation is determined. The difference between the actual transformation and the reference transformation is the error that would have been introduced into the posture of the reference instrument if the joint position and / or angle changes at the joint distal to the orientation platform were not offset Represents. In some examples, these differences can be determined by subtracting the corresponding matrix and / or vector representation of the motion and reference transforms.
In process 540, compensation joint changes are determined based on the differences. Using the difference between the actual and reference transforms determined during process 530, one or more compensation joint changes are determined. Since the compensation joint is distal to the orientation platform, the difference between the actual transformation and the reference transformation is mapped from the world coordinate system of the actual transformation and the reference transformation to the local coordinate system based on the compensation joint. . In practice, this translates the error in the absolute attitude of the reference instrument from the world coordinate system into a relative error in the attitude between the reference instrument and the most proximal one of the compensation joint. In some examples, one or more kinematic models may be used to convert those differences into a local coordinate system. In some examples, the compensation joints may include one or more manipulator joints. In some examples, the compensation joint may further include one or more setup joints between the orientation platform and the manipulator. Once the relative errors in posture are determined, they can be used to determine compensation joint changes. In some examples, an inverse Jacobian may be used to map the relative error to the compensation joint change. In some examples, the compensation joint change may include a joint speed for the compensation joint.
In process 550, the compensation joint is driven. One or more commands are transmitted to one or more actuators at the compensation joint based on the compensation joint change determined during process 540. The command sent to the compensation joint will compensate for errors in the reference instrument posture introduced by the movement of the joint proximal to the orientation platform so that the reference instrument attitude in the world coordinate system is maintained with minimal error. to correct. As long as processes 420, 430, and / or 440 continue to cause changes in the orientation platform position and / or orientation, processes 520-550 are repeated to offset any errors introduced into the reference instrument posture.
As described above and further emphasized herein, FIG. 5 is merely an example and should not unduly limit the scope of the claims. Those skilled in the art will recognize many variations, alternatives, and improvements. According to some embodiments, the compensation joint may include a set-up joint and / or a subset of the joints in the manipulator. In some examples, the compensation joint may include only a roll joint, a pitch joint, and a yaw joint in the manipulator. In some examples, during processes 510-550, the manipulator and / or other joints in the setup joint may be locked to prevent relative movement. In some examples, during process 510-550, one or more non-actuated joints in the setup joint and / or manipulator distal to the orientation platform are unlocked and / or left floating. Also good. This is to ensure that errors in the attitude of the reference instrument are at least partially reduced by changes in the unlocked joint. In some examples, changes in the unlocked joint may reduce the amount that the compensation joint should be driven. In some examples, the posture of the reference instrument can be maintained at least in part by using resistance from the patient port and / or by the operator of the computer aided device.
Some examples of a control unit, such as control unit 130, have executable code that, when executed by one or more processors (eg, processor 140), causes the one or more processors to perform the method 400 process. Non-transitory specific machine-readable media may be included. Some common forms of machine-readable media that may include the process of method 400 are, for example, floppy disks, flexible disks, hard disks, magnetic tapes, any other magnetic media, CD-ROM, and any other optical media. , Punch card, paper tape, any other physical medium with a hole pattern, RAM, PROM, EPROM, FLASH-EPROM, any other memory chip or cartridge, and / or configured to be readable by a processor or computer Any other medium may be included.
While exemplary embodiments have been illustrated and described, a wide range of improvements, variations, and substitutions are anticipated in the foregoing disclosure and in some examples, and some features in the examples correspond to other features. It may be adopted without use. Those skilled in the art will recognize many variations, alternatives, and improvements. Thus, the scope of the present invention should be limited only by the following claims, and those claims should be construed broadly and in a manner consistent with the scope of the embodiments disclosed herein. It is.
A computer-aided medical device:
One or more first joints proximate to the orientation platform;
One or more second joints distal to the orientation platform;
One or more links distal to the orientation platform;
A reference instrument coupled to the orientation platform by the second joint and the link; and a control unit coupled to the first joint and the second joint;
Determining a posture of the reference instrument including a reference point and a reference direction;
Using the first joint to position the orientation platform over the reference point;
Using the first joint to rotate the orientation platform to align the orientation platform with the reference direction; and using the second joint to maintain the posture of the reference instrument;
Computer assisted medical device.
The control unit further adjusts a distance between the orientation platform and the reference point;
The distance is selected to maintain a sterile area,
The distance is selected to maintain the working height of the orientation platform above the reference point;
The reference point is a remote center of the reference instrument;
The reference instrument is an endoscope;
The reference point is associated with a surgical port of the patient;
The control unit further locks one or more of the second joints;
The control unit further releases one or more locks of the second joint which is a non-actuating joint;
The control unit releases one or more brakes associated with one or more of the second joints being unlocked;
The control unit partially releases one or more brakes associated with one or more of the second joints being unlocked;
The control unit further positions the center of gravity of the orientation platform vertically above the reference point;
The control unit further positions a rotation center of the orientation platform vertically above the reference point;
The control unit further sends one or more commands to one or more first actuators coupled to the first joint to position and rotate the orientation platform.
The control unit further sends one or more commands to one or more first actuators coupled to the second joint to maintain the posture of the reference instrument.
Determining a reference transformation of the reference instrument in a first coordinate system before positioning or rotating the orientation platform;
Determining an actual transformation of the reference instrument in the first coordinate system while the orientation platform is positioned and rotated;
Determining a difference between the reference transformation and the actual transformation; and driving the second joint based on the difference to maintain the posture of the reference instrument;
The control unit further transforms the difference into a second coordinate system unique to the second joint;
The control unit further determines a command for the second joint based on an inverse Jacobian for the second joint;
The control unit further determines the reference transformation and the actual transformation based on the positions of the first joint and the second joint and one or more kinematic models of the computer-aided medical device;
The positions of the first joint and the second joint are based on measurements from one or more sensors that monitor the first joint and the second joint,
The control unit further determines the posture of the reference instrument based on the positions of the first joint and the second joint and one or more kinematic models of the computer-aided medical device;
The control unit further adjusts the front direction vector of the orientation platform to the horizontal component of the reference direction.
The second joint is configured to control roll, pitch, and yaw of the reference instrument with respect to the orientation platform;
The control unit further simultaneously positions the orientation platform, rotates the orientation platform, and maintains the posture of the reference instrument.
Further comprising one or more articulated arms distal to the orientation platform;
Each of the articulated arms includes one or more third joints,
The control unit further locks one or more of the third joints;
The control unit further places one or more of the third joints in a floating state.
The control unit releases one or more brakes associated with one or more of the third joints when one or more of the third joints, which are joints that are not articulated, are in the floating state;
30. The device of claim 28.
The control unit partially releases one or more brakes associated with one or more of the third joints when one or more of the third joints are in the floating state;
The control unit issues a command for each actual position to one or more of the third joints when one or more of the third joints that are working joints are in the floating state.
The control unit issues a command for each actual speed to one or more of the third joints when one or more of the third joints that are actuating joints are in the floating state.
The control unit provides resistance or torque to one or more of the third joints when one or more of the third joints that are working joints are in the floating state, respectively.
The control unit may be configured such that when one or more of the third joints, which are actuating joints, are in the floating state, the one or more of the third joints have their actual positions and respective commanded positions. Issue commands for each position of
The control unit commands the one or more of the third joints for their respective speeds that are smaller than their actual speeds when one or more of the third joints that are working joints are in the floating state. ,
A method for controlling movement in a medical device comprising:
Determining a posture of the reference instrument of the medical device including a reference point and a reference direction;
Positioning the orientation platform over the reference point using one or more first joints proximal to the orientation platform of the medical device;
Rotating the orientation platform with the first joint to align the orientation platform with the reference direction; and one or more located distal to the orientation platform and proximal to the reference instrument Maintaining the posture of the reference instrument using a second joint of
Further comprising adjusting a distance between the orientation platform and the reference point;
37. The method of claim 36.
Further comprising unlocking one or more second joints that are non-actuating joints;
Determining a difference between the reference transformation and the actual transformation; and maintaining the posture of the reference instrument by driving the second joint based on the difference;
Further comprising aligning a front direction vector of the orientation platform with a horizontal component of the reference direction;
Maintaining the posture of the reference instrument includes controlling roll, pitch, and yaw of the reference instrument with respect to the orientation platform.
Locating the orientation platform, rotating the orientation platform, and maintaining the posture of the reference instrument are performed simultaneously.
A non-transitory machine readable medium comprising a plurality of machine readable instructions configured to cause the one or more processors to perform a method when executed by one or more processors associated with a medical device. ,
JP2016557122A 2014-03-17 2015-03-17 System and method for meeting reference goals Pending JP2017514542A (en)
JP2017514542A true JP2017514542A (en) 2017-06-08
JP2017514542A5 JP2017514542A5 (en) 2018-04-19
JP2016557131A Active JP6537523B2 (en) 2014-03-17 2015-03-17 System and method for maintaining tool attitude
JP2016557122A Pending JP2017514542A (en) 2014-03-17 2015-03-17 System and method for meeting reference goals
JP2019104259A Pending JP2019141721A (en) 2014-03-17 2019-06-04 System and method for maintaining tool posture
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2015-03-17 CN CN201580014405.3A patent/CN106102645B/en active IP Right Grant
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CN110192919A (en) 2019-09-03
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