CN112057170B - Surgical robot and control method and control device thereof - Google Patents

Abstract

The invention relates to a surgical robot and a control method and a control device thereof. The control method comprises the following steps: obtaining description information for describing structural characteristics of the arm body mechanism; and generating a user interface component containing a control with the degree of freedom which can be configured by the arm body mechanism according to the description information. Through the embodiment, the flexibility and the usability of the control of the arm body mechanism can be improved.

Description

Surgical robot and control method and control device thereof

The present application is a divisional application filed on 2019, 09, 10, under the name of "surgical robot and control method and control device thereof", by the chinese patent office, with the application number CN201910854921.7, the entire content of which is incorporated herein by reference.

Technical Field

The invention relates to the field of medical instruments, in particular to a surgical robot and a control method and a control device thereof.

Background

The minimally invasive surgery is a surgery mode for performing surgery in a human body cavity by using modern medical instruments such as a laparoscope, a thoracoscope and the like and related equipment. Compared with the traditional minimally invasive surgery, the minimally invasive surgery has the advantages of small wound, light pain, quick recovery and the like.

With the progress of science and technology, the minimally invasive surgery robot technology is gradually mature and widely applied. The minimally invasive surgery robot generally comprises a main operation table and a slave operation device, wherein the main operation table comprises a handle, a doctor sends a control command to the slave operation device through the operation handle, the slave operation device comprises a mechanical arm and a plurality of operation arms arranged at the far end of the mechanical arm, the operation arms are provided with tail end instruments, and the tail end instruments move along with the handle in a working state so as to realize remote operation.

The prior art surgical robot generally only provides two control modes which can be freely switched by a doctor, wherein one control mode allows the far end of the mechanical arm to freely move in a Cartesian space, and the other control mode allows the far end of the mechanical arm to move around a fixed point in the Cartesian space, so that the robot is not applicable when other task scenes occur, and the problem of low flexibility and usability exists.

Disclosure of Invention

Accordingly, there is a need for a surgical robot, a control method thereof, and a control device thereof, which are flexibly configurable and highly easy to use.

In one aspect, a method for controlling a surgical robot is provided, including the steps of: obtaining description information for describing structural characteristics of the arm body mechanism; and generating a user interface component containing a control with the degree of freedom which can be configured by the arm body mechanism according to the description information.

Wherein the description information includes information of effective degrees of freedom of the arm mechanism; in the step of generating a user interface component containing a control with a degree of freedom that the arm mechanism can be configured to according to the description information, the method comprises the following steps: and generating a user interface component containing a control of the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism.

After the step of generating the user interface component of the control with the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism, the method comprises the following steps: acquiring an operation instruction generated aiming at the control operation, and generating information of task freedom degree according to the operation instruction; and calling a user interface component of a control of a common task mode which contains the information of the task freedom degree, which is available for configuration of the arm body mechanism and comprises and is related to the information of the task freedom degree according to the generated information of the task freedom degree.

Wherein the common task mode is a combination of two or more task degrees of freedom that is preset.

The common task mode comprises all task degrees of freedom which can be configured, and/or task degrees of freedom which are related to posture degrees of freedom in all task degrees of freedom which can be configured, and/or task degrees of freedom which are related to position degrees of freedom in all task degrees of freedom which can be configured.

Wherein the common task mode is a combination of more than two task degrees of freedom generated from high to low according to the recorded historical use frequency.

The common task mode is a combination which is generated according to the control configuration and comprises more than two task degrees of freedom.

After the step of generating the user interface component of the control with the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism, the method comprises the following steps: and acquiring an operation instruction generated aiming at the control operation, and generating configuration information of the task freedom degree of the arm body mechanism according to the operation instruction.

After the step of obtaining an operation instruction generated for the control operation and generating configuration information of the task degree of freedom of the arm body mechanism according to the operation instruction, the method comprises the following steps: detecting whether a fine adjustment control instruction is acquired; and when the fine adjustment control instruction is acquired, generating a user interface component which can be configured and only contains a control corresponding to the task degree of freedom according to the configuration information of the task degree of freedom of the current arm body mechanism.

The description information also comprises the motion range information of each effective degree of freedom in the arm body mechanism; after the step of generating the user interface component containing the control of the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism, the method further comprises the following steps: and generating a user interface component containing a control of the motion range corresponding to each task degree of freedom which can be configured by the arm body mechanism according to the motion range information of each effective degree of freedom of the arm body mechanism.

After the step of generating the user interface component of the control with the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism, the method comprises the following steps: detecting whether a trigger signal for enabling the far end of the mechanical arm to move around a fixed point is acquired; and when the trigger signal is acquired, generating a user interface component containing a control which is provided for configuration by the arm body mechanism and only has task freedom degrees related to the posture freedom degrees.

Wherein the description information includes joint component information and link assembly information of the arm body mechanism; in the step of generating a user interface component containing a control with a degree of freedom that the arm mechanism can be configured to according to the description information, the method comprises the following steps: and generating a user interface component containing a control of joint freedom degree which can be configured by the arm body mechanism according to the joint component information of the arm body mechanism and the connecting rod assembly information.

Wherein, in the step of generating the user interface component of the control with the joint freedom degree which can be configured by the arm body mechanism according to the joint component information and the connecting rod assembly information of the arm body mechanism, the method comprises the following steps: and generating a user interface component which comprises a model image simulating the structure of the arm body mechanism and a control part with joint freedom degrees for configuration at each joint component in the model image according to the joint component information and the connecting rod component information of the arm body mechanism.

Wherein, after the step of generating the user interface component containing the control of the joint freedom degree which can be configured by the arm body mechanism according to the joint component information and the connecting rod assembly information of the arm body mechanism, the method comprises the following steps: and acquiring an operation instruction generated by the control operation aiming at the joint freedom degree, and enabling and/or disabling the corresponding joint freedom degree according to the operation instruction.

The description information also comprises the motion range information of each joint component in the arm body mechanism; after the step of generating the user interface component containing the control of the joint freedom degree which can be configured by the arm body mechanism according to the joint component information and the connecting rod assembly information of the arm body mechanism, the method further comprises the following steps: and generating a user interface component containing a control of the motion range corresponding to the freedom degree of each joint, which can be configured by the arm body mechanism, according to the motion range information of each joint component of the arm body mechanism. In another aspect, a computer-readable storage medium is provided, in which a computer program is stored, the computer program being configured to be loaded by a processor and to execute steps implementing the control method according to any one of the embodiments described above.

In still another aspect, a control device for a surgical robot is provided, including: a processor for loading and executing a computer program; and a computer-readable storage medium for storing a computer program; wherein the computer program is configured to be loaded by one or more processors and to perform the steps of implementing the control method according to any of the embodiments described above.

In still another aspect, a method for controlling a surgical robot is provided, including the steps of: obtaining description information describing structural characteristics of an arm body mechanism, wherein the description information comprises joint component information of the arm body mechanism, connecting rod component information and motion range information of each joint component; generating a user interface component containing a control of joint freedom degree which can be configured by the arm body mechanism according to the joint component information of the arm body mechanism and the connecting rod component information; and generating a user interface component containing a control of the motion range corresponding to the freedom degree of each joint, which can be configured by the arm body mechanism, according to the motion range information of each joint component of the arm body mechanism.

The invention has the following beneficial effects:

by generating a user interface component containing a control corresponding to the configurable degree of freedom of the arm mechanism according to the description information describing the structural characteristics of the arm mechanism, a doctor or an assistant can freely set the degree of freedom which is allowed to be adjusted according to the operation requirement of the surgical process, and the flexibility and the usability of the arm mechanism control can be improved.

Drawings

FIG. 1 is a schematic structural diagram of a surgical robot according to an embodiment of the present invention;

FIG. 2 is a partial schematic view of the surgical robot of FIG. 1;

FIG. 3 is a partial schematic view of the surgical robot of FIG. 1;

FIG. 4 is a schematic diagram of a robot arm of the surgical robot arm mechanism shown in FIG. 1;

FIG. 5 is a flowchart of an embodiment of a method for controlling a surgical robot according to the present invention;

FIG. 6 is a flowchart of an embodiment of a method for controlling a surgical robot according to the present invention;

FIG. 7 is a schematic diagram illustrating the analysis of the spatial movement angle in the control method of the surgical robot according to the present invention;

FIG. 8 is a flow chart of the control method of the surgical robot of the present invention in a one-to-one mode of operation;

FIG. 9 is a schematic view of the operation of the control method of the surgical robot of the present invention in a one-to-one operation mode;

FIG. 10 is a flow chart of one embodiment of a method of controlling a surgical robot in a two-to-one mode of operation in accordance with the present invention;

FIG. 11 is a schematic view of the operation of one embodiment of the control method of the surgical robot in a two-to-one operation mode according to the present invention;

FIG. 12 is a flow chart of another embodiment of the method of controlling a surgical robot of the present invention in a two-to-one mode of operation;

FIG. 13 is a flow chart of another embodiment of the method of controlling a surgical robot of the present invention in a two-to-one mode of operation;

FIG. 14 is a schematic view of another embodiment of a method for controlling a surgical robot according to the present invention in a two-to-one operation mode;

FIG. 15 is a flowchart of another embodiment of a method of controlling a surgical robot in accordance with the present invention;

FIGS. 16-20 are schematic diagrams of user interface components provided by the control method of FIG. 15;

FIG. 21 is a flowchart of an embodiment of a method of controlling a surgical robot in accordance with the present invention;

FIGS. 22-24 are schematic diagrams of user interface components provided by the control method of FIG. 21;

FIG. 25 is a flowchart of a method of controlling a surgical robot in accordance with an embodiment of the present invention;

FIG. 26 is a schematic illustration of user interface components provided by the control method of FIG. 25;

FIGS. 27-29 are schematic diagrams of alternative user interface components provided by the control method of FIG. 15;

FIG. 30 is a schematic illustration of another user interface component provided by the control method of FIG. 15;

FIG. 31 is a flowchart of a method of controlling a surgical robot in accordance with an embodiment of the present invention;

FIG. 32 is a schematic illustration of another user interface component provided by the control method of FIG. 15;

FIG. 33 is a schematic view of another embodiment of a surgical robot in accordance with the present invention; .

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "coupled" to another element, it can be directly coupled to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments. As used herein, the terms "distal" and "proximal" are used as terms of orientation that are conventional in the art of interventional medical devices, wherein "distal" refers to the end of the device that is distal from the operator during a procedure, and "proximal" refers to the end of the device that is proximal to the operator during a procedure.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items. In the present invention, "each" includes one or more.

Fig. 1 to 3 are schematic structural diagrams and partial schematic diagrams of a surgical robot according to an embodiment of the present invention.

The surgical robot includes a master operation table 1 and a slave operation device 2. The main operating table 1 has a motion input device 11 and a display 12, and a doctor transmits a control command to the slave operating device 2 by operating the motion input device 11 to make the slave operating device 2 perform a corresponding operation according to the control command of the doctor operating the motion input device 11, and observes an operation area through the display 12. The slave operating device 2 has an arm mechanism having a mechanical arm 21 and an operating arm 31 detachably mounted on a distal end of the mechanical arm 21, and specifically, the operating arm 31 is mounted on a power mechanism 22 on the distal end of the mechanical arm 21 and driven by the power mechanism 22. The robot arm 21 includes a base and a connecting member connected in sequence, and the connecting member has a plurality of joint members. The operating arm 31 comprises a connecting rod 32, a connecting component 33 and a terminal instrument 34 which are connected in sequence, wherein the connecting component 33 is provided with a plurality of joint components, and the operating arm 31 adjusts the posture of the terminal instrument 34 through adjusting the joint components; end instrument 34 has an image end instrument 34A and a manipulation end instrument 34B. Wherein the robot arm 21 and/or the operation arm 31 can follow the motion input device 11.

For example, the motion-input device 11 may be connected to the main console 1 by a wire, or connected to the main console 1 by a rotating link. The motion-input device 11 may be configured to be hand-held or wearable (often worn at the far end of the wrist, such as the fingers or palm), with multiple degrees of freedom available. The motion-input device 11 is, for example, configured in the form of a handle as shown in fig. 3. In one case, the number of degrees of freedom available for the motion-input device 11 is configured to be lower than the number of degrees of freedom defined for the task at the distal end of the arm mechanism; in another case, the number of effective degrees of freedom of the motion-input device 11 is configured not to be lower than the number of task degrees of freedom of the distal end of the arm mechanism. The number of effective degrees of freedom of the motion input device 11 is at most 6, and in order to freely move and rotate along with the hand of the doctor without restriction, the motion input device 11 is exemplarily configured to have 6 effective degrees of freedom, wherein the effective degrees of freedom of the motion input device 11 refer to the effective degrees of freedom that can move along with the hand, so that the doctor has a large operation space, and the control of the robot arm 21 in almost all configurations can be satisfied by generating more meaningful data through the analysis of each effective degree of freedom.

The motion input device 11 follows the hand motion of the doctor, and collects the motion information of the motion input device itself caused by the hand motion in real time. The position information, attitude information, velocity information, acceleration information, and the like can be analyzed using the motion information. The motion-input device 11 includes, but is not limited to, a magnetic navigation position sensor, an optical position sensor, or a link-type main operator, etc.

In one embodiment, a control method for a surgical robot is provided, and more particularly, to a flexible configuration method for a degree of freedom of an arm mechanism of a surgical robot, which may be a task degree of freedom in cartesian space and/or a joint degree of freedom in joint space. As shown in fig. 15, the control method includes the steps of:

in step S41, description information describing the structural features of the arm mechanism is acquired.

And step S42, generating a user interface component containing a control with the degree of freedom which can be configured by the doctor by the arm mechanism according to the description information.

Wherein the user interface components can be displayed by the display 12 of the main console 1 or an auxiliary display connected to the control device, thereby providing useful reference information for the doctor or assistant to help configure the degrees of freedom of the arm mechanism.

In a specific embodiment, the description information of step S41 includes information of effective degrees of freedom of the arm mechanism. Further, step S42 may be implemented by: and generating a user interface component containing a control of the task freedom degree which can be configured by the doctor by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism. The task degrees of freedom are described in cartesian space, and their definition may be referred to in detail in the following description.

Taking the structure of the arm mechanism shown in fig. 4 as an example, the user interface assembly may be exemplarily represented as fig. 16. For example, fig. 17 shows user interface components of a process of selecting five task degrees of freedom, namely x, y, z, α, β, and the user interface components after selection are shown in fig. 18, and the control of the arm mechanism can be performed by selecting, for example, a "cancel" option to end the task degree of freedom after the control is finished, wherein fig. 18 shows that the arm mechanism can be freely controlled. For another example, fig. 19 shows a user interface component of a process of selecting two task degrees of freedom α and β, and the user interface component after selection can also select, for example, a "cancel" option to end the control of the arm mechanism in such a task degree of freedom after the control is ended, as shown in fig. 20, where fig. 20 shows that the RCM constraint control can be performed on the arm mechanism.

In one embodiment, after step S42, the physician is allowed to freely set several common task modes according to actual needs and the control device generates the user interface component of the control of the related common task mode to facilitate the subsequent quick use. Configuration information of task freedom degrees for guiding a doctor to configure a plurality of arm mechanisms in a user-defined mode can be generated, and then several kinds of configurable user interface components of controls of common task modes can be generated. The generated guidance information may include, for example, such contents: please select more than one task freedom options from the screen and confirm whether to generate the common mode 1, please select more than one task freedom options from the screen and confirm whether to generate the common mode 2 '… …' and confirm whether to finish the setting, and other words or voice prompts, and after finishing the setting, a user interface assembly with a plurality of controls of the common task modes is generated, and the controls are provided for the doctor to select.

Preferably, in order to prevent the widgets of different common task modes from being repeatedly configured by the doctor, the control device is configured to detect whether the information of the task degree of freedom associated with the currently-set common task mode is completely matched with the information of the task degree of freedom associated with the previously-set common task mode in real time when generating the user interface components of the widgets of several kinds of commonly-used task modes which can be configured, and if the information of the task degree of freedom associated with the currently-set common task mode is completely matched, the user interface components of the widgets which can be configured are prohibited from being generated by the currently-set common task mode, and the doctor can be reminded of the repetition of the setting.

In an embodiment, specifically after step S42, step S43 is included, where an operation instruction generated by an operation of a degree-of-freedom control that is available for configuration of the arm mechanism is obtained, and configuration information of the task degree-of-freedom of the arm mechanism is generated according to the operation instruction. The configuration is often made by the doctor by selecting it through an input device such as a touch screen, mouse, keypad, the aforementioned motion input device 11, etc.

Further, approximately equivalent to the aforementioned custom setting common task mode, the control device may automatically generate a plurality of user interface components including controls of the common task mode according to the historical habit information of the doctor, specifically, as shown in fig. 21, while executing step S43, execute:

step S4311, recording the configuration information of the task freedom degree of the current arm mechanism and updating the historical use frequency of the current arm mechanism;

step S4312, generating the configuration information of the task freedom degrees of the arm body mechanism which is sequenced at a plurality of times before according to the sequence of the historical use frequency from high to low to generate a plurality of user interface components of the control of the commonly used task mode which can be configured.

Of course, the common task mode can also generate a corresponding user interface component containing the control of the common task mode directly according to the definition of the system file.

The above-mentioned common task mode may be set to more than one. According to the actual historical use frequency, three modes can be set for example, namely a free control mode, an RCM constraint control mode and a posture-fixing constraint control mode. Specifically, the free control mode refers to a case where the configuration information of the task degree of freedom of the arm mechanism completely matches the information of the effective degree of freedom of the arm mechanism; the RCM constraint control mode refers to a case where the configuration information of the task degrees of freedom of the arm mechanism does not completely match the information of the effective degrees of freedom of the arm mechanism, but is included in the information of the effective degrees of freedom related to the attitude degrees of freedom in the arm mechanism; the fixed-attitude constraint control mode refers to a case where the information on the arrangement of the task degrees of freedom of the arm mechanism does not completely match the information on the effective degrees of freedom of the arm mechanism, but is included in the information on the effective degrees of freedom of the arm mechanism with respect to the positional degrees of freedom.

After step S42, when used in particular, it includes: acquiring an operation instruction generated by the operation of the control for the task freedom degree which can be configured, and generating information of the task freedom degree according to the operation instruction; and calling a user interface component containing a control of a common task mode, which is configured by the arm body mechanism and comprises and is related to the information of the task freedom degree, according to the generated information of the task freedom degree. To further assist the operator in quick selection. For example, when the common task modes include a common task mode 1 (i.e., [ x, y, z, α, β ]), a common task mode 2 (i.e., [ x, y, z ]), and a common task mode 3 (i.e., [ α, β ]), and [ x ] is selected by the task degree-of-freedom control in the user interface component generated in step S42, a user interface component including new selectable controls, specifically, the common task mode 1 and the common task mode 2, is generated; if the control with the task degree of freedom in the user interface component generated in step S42 is selected [ α ], a user interface component including new selectable controls, specifically, a common task mode 1 and a common task mode 3, is generated; the association input mode can provide more convenient and faster selection for operators. Of course, the new user interface component may still include the task degree of freedom control generated in step S42 for the operator to configure configurations other than the common task mode.

Still taking the structure of the arm mechanism shown in fig. 4 as an example, the user interface assembly may illustratively be represented as fig. 22. In FIG. 22, the user interface components contain controls for task degrees of freedom that are available for configuration and controls for common task modes that are available for configuration. As shown in fig. 23, the names of the common task modes can be set in a self-defined manner, such as naming the task mode 1 as the free control mode and naming the task mode 2 as the RCM constraint control mode in fig. 22. Fig. 24 shows a process of controlling the movement of the arm mechanism by selecting a common task mode, and since five task degrees of freedom [ x, y, z, α, β ] are associated with the corresponding free control mode in the arm mechanism of this configuration, the user interface component after selection can be as shown in fig. 18.

When the common task mode is defined, especially when the common task mode is automatically defined according to historical use frequency, the common task mode can be frequently defined after a doctor logs in an operating system of the surgical robot, the operating system can provide a plurality of account numbers to allow a plurality of doctors to log in and use at different times, and then the control device can provide different controls of the common task mode for each doctor according to the use habits of each doctor so as to realize more personalized configuration. For example, the control device may be configured to generate a login interface at startup, obtain and verify login information of a doctor, and provide the user interface component described in the foregoing embodiment for the doctor after the login information verification is passed. The configuration information of the common task modes is finally stored by the control device in association with the login information of the doctors for subsequent use, and the control of the common task modes aiming at different doctors can be conveniently and individually configured or generated.

In one embodiment, during the adjustment of the arm mechanism in combination with the configuration information of the task degree of freedom of the arm mechanism, the arm mechanism may be further configured based on the configuration information of the task degree of freedom of the current arm mechanism to achieve fine tuning of the arm mechanism. Specifically, as shown in fig. 25, after step S42 is executed:

step S4321, detecting whether a fine adjustment control instruction is acquired in real time.

The fine control command represents the intention of the doctor to actively trigger the precise adjustment of the arm mechanism, and can be input through an input device connected with the control device.

Step S4322, after the fine tuning control instruction is detected and obtained, generating a user interface component which can be configured and only contains a control of the corresponding task degree of freedom according to the configuration information of the task degree of freedom of the current arm mechanism.

The user interface component comprises updated controls of degrees of freedom configurable by a doctor, and the updated controls only comprise configuration information of the task degrees of freedom of the current arm body mechanism. By enabling some degrees of freedom of the task and/or disabling some degrees of freedom of the task, it is possible to adjust only on the enabled degrees of freedom, and not on the disabled degrees of freedom of the task, with the aim of achieving a precise adjustment.

If the currently configured task degree of freedom is as shown in fig. 18, after the fine adjustment control instruction is acquired, the user interface component shown in fig. 16 is skipped to. If the currently configured task degree of freedom is as shown in fig. 20, after the switching instruction is obtained, the user interface component as shown in fig. 26 is skipped to, so that the two task degrees of freedom [ α, β ] can be further configured, in which case, one of the task degrees of freedom is generally selected to individually adjust the arm mechanism in the task degree of freedom.

For example, it is necessary to adjust [ x, y, z, α, β, γ ], if the doctor finds that the two degrees of freedom of x and y have reached the desired degree, the above fine adjustment control command may be triggered, and the task degree of freedom of the distal end of the arm mechanism may be reconfigured to [ z, α, β, γ ] according to the generated task degree of freedom information of the new arm mechanism that is available for configuration, so as to continue to adjust z, α, β, γ by using the above control method for the arm mechanism, further, if there is difficulty in adjusting [ z, α, β, γ ] together, the task degree of freedom of the distal end of the arm mechanism may be reconfigured, and then [ z, α, β, γ ] may be adjusted one by using the above control method for the arm mechanism until finally the distal end of the arm mechanism completely moves to the target pose.

In one embodiment, the description information in step S41 further includes range of motion information of each effective degree of freedom in the arm mechanism. Further, after executing step S41, the following steps may be further executed:

and generating a user interface component containing a control of the motion range of each task degree of freedom, which can be configured by the doctor, of the arm body mechanism according to the motion range information of each effective degree of freedom of the arm body mechanism.

The control of the movement range of each task degree of freedom of the arm body mechanism can be configured, so that the movement range of the corresponding task degree of freedom is limited when the arm body mechanism is controlled to move subsequently, and the arm body mechanism can be accurately controlled to move in a small space. When the movement range of each task degree of freedom is configured, the configuration needs to be performed within the movement range of the task degree of freedom, namely, the configuration cannot be performed beyond the movement range, or if the movement range is exceeded, the configuration is defaulted to the maximum value of the movement range. Which can be configured by inputting and/or selecting a range of motion. For example, the range of motion of the effective degrees of freedom of the arm mechanism corresponding to the yaw and pitch angles of the mission degrees of freedom is 180 °, and the yaw and pitch angles of the mission degrees of freedom may be assigned, for example, 150 ° to 180 ° in the configuration, to allow the arm mechanism to move only within 150 ° of yaw and pitch angles when moving in cartesian space.

In another embodiment, the description information of step S41 includes joint assembly information of the arm body mechanism and link assembly information. Further, step S42 can be implemented as follows: and generating a user interface component containing a control of the joint degree of freedom which can be configured by the doctor by the arm body mechanism according to the joint component information of the arm body mechanism and the connecting rod assembly information.

Preferably, the user interface component which comprises a 2D or 3D model image simulating the structure of the arm body mechanism can be generated according to the joint component information and the connecting rod component information of the arm body mechanism. And a control of joint freedom degree which can be configured by a doctor is generated at each joint component in the model image. By generating a model image corresponding to the structure of the arm mechanism, it is possible to more intuitively facilitate the doctor to configure the joint degrees of freedom of the arm mechanism.

Still taking the structure of the arm mechanism shown in fig. 4 as an example, the user interface assembly may exemplarily be represented as fig. 27. For example, the process of configuring the adjustable joint degree of freedom for inhibiting the third joint is shown in fig. 28, and the configured user interface component is shown in fig. 29, and after the control is finished, an option such as "cancel" can be selected to finish the control of the arm body mechanism under the joint degree of freedom.

Preferably, the description information in step S41 includes range of motion information of each joint component in the arm mechanism. After the step of generating the user interface component containing the control of the joint freedom degree which can be configured by the doctor by the arm body mechanism according to the joint component information of the arm body mechanism and the connecting rod assembly information, the method can further comprise the following steps: and generating a user interface component containing a control of the motion range corresponding to the freedom degree of each joint, which can be configured by the arm body mechanism, according to the motion range information of each joint component of the arm body mechanism. The motion range of the joint freedom degree can be configured to limit the motion of the joint.

In this embodiment, with the generated user interface component containing the control of the joint degree of freedom that the arm body mechanism can be configured by the doctor and/or the control of the range of motion that each joint degree of freedom can be configured, the doctor can avoid collision between the arm body mechanism and the human body or foreign objects in some specific occasions by configuring the joint degree of freedom (enabling or disabling the relevant joint degree of freedom) and/or combining the configuration of the range of motion of the corresponding joint degree of freedom; alternatively, the configuration of the arm body mechanism can be changed in a method for adapting to a specific use scene through the configuration, such as changing a snake-shaped arm body mechanism into a linear arm body mechanism; or the energy consumption of the arm body mechanism during working can be reduced.

In an embodiment, the description information in step S41 optionally includes information of effective degrees of freedom of the arm mechanism, information of a range of motion of each effective degree of freedom, information of joint components, and information of the linkage assembly and/or information of a range of motion of each joint component, and then a user interface component having a relatively comprehensive control can be generated according to the description information in step S42. Such as even more controls including controls for the task degrees of freedom that the arm mechanism can configure for the physician and controls including the joint degrees of freedom that the arm mechanism can configure for the physician.

Therein, a user interface assembly as shown in fig. 30 may be provided for the physician to select whether to configure the task degrees of freedom or the joint degrees of freedom. In fig. 30, if the option for task degree of freedom setting is selected, the user interface assembly shown in fig. 16 or 22 is subsequently entered for configuration by the physician, and if the option for joint degree of freedom setting is selected, the user interface assembly shown in fig. 27 is subsequently entered for configuration by the physician.

The above-mentioned description information may be instruction information which is input step by step directly by the doctor via the input device. Preferably, the description information may be stored in a description file, and the description file is stored in an arm mechanism provided with a memory or an electronic tag, and further automatically acquired through an input device having a data interface function or an induction recognition function.

Preferably, as shown in fig. 31, according to the specific use case, the control device is configured to further perform, when generating the user interface component including the control with the degree of freedom that the arm mechanism can be configured by the doctor according to the description information:

step S4331, detecting whether a trigger signal for enabling the far end of the mechanical arm to move around the fixed point is acquired.

Step S4332, when the trigger signal is acquired, generating a user interface component containing a control which is provided for configuration by the arm mechanism and only has task freedom degrees related to the posture freedom degrees.

In one embodiment, the arm body mechanism comprises at least a mechanical arm, and the distal end of the mechanical arm is detachably connected with an operating arm with a terminal instrument through a power mechanism, namely, the arm body mechanism does not obviously need to comprise the operating arm in certain adjusting processes, and can be installed when the arm body mechanism is used in specific needs.

In this embodiment, the distal end of the mechanical arm is detachably connected to a puncture device (commonly referred to as a "puncture card"), which includes a cannula and a needle that are engaged with each other, the needle mainly serves to puncture the tissue of the human body, and the cannula mainly serves to establish a cavity passage, such as an abdominal cavity passage, after puncturing, for inserting the operation arm having the distal end instrument into the cavity of the human body. The distal end of the robotic arm is more specifically connected to the cannula.

On one hand, in the safe operation process, the cavity channel is generally established by using the insertion tube, then the distal end of the mechanical arm is connected with the insertion tube, and then the distal end of the mechanical arm is provided with the operation arm penetrating through the insertion tube. Preferably, a detection unit connected with the control device is arranged at the joint of the distal end of the mechanical arm and the puncture outfit, and the detection element continuously generates a trigger signal when the puncture outfit is reliably connected to the distal end of the mechanical arm.

On the other hand, in some special cases, the cannula may be connected to the distal end of the mechanical arm first, and then the cannula may be inserted into the cavity or a connecting part connected to the cavity. In this case, it is therefore also possible to provide the puncture device with a detection unit at its distal end, which is connected to the control device, the detection element continuously generating the trigger signal when the puncture device is reliably inserted into the patient or into a connection which has been connected beforehand to the patient. In this case, the detection element is actually provided on the cannula.

Wherein the detection element may be selected from one of a contact, a micro switch or a proximity sensor.

This means that since the puncture instrument connected to the robot arm has already been connected to the human body, the control device automatically limits the function of the robot arm distal end that is adjustable in the degree of freedom of the task in relation to the degree of freedom of the position (i.e. not available for configuration) from the viewpoint of safety in order to avoid trauma to the human body by random adjustment of the robot arm distal end, while only allowing the function of the robot arm distal end that is adjustable in the degree of freedom of the task in relation to the degree of freedom of the posture, i.e. automatically achieving the locking of the degree of freedom of the task in relation to the state of danger.

Still taking the structure of the arm body mechanism shown in fig. 4 as an example, when the currently configured task degree of freedom is shown in fig. 18, when the trigger signal is detected, a jump is made to another user interface component, which is shown in fig. 26, that is, at most two task degrees of freedom, i.e., the pose degrees of freedom α and β, can be configured.

In one embodiment, when the manipulator arm is connected to the robot arm in the arm body mechanism, in step S41, the method includes:

and respectively generating a control with the degree of freedom which can be configured by the doctor and a user interface component with the control with the degree of freedom which can be configured by the doctor.

The installation information of the operation arm (including the information about where the operation arm is installed, such as the information about which robot arm is installed and/or the information about which driving part of the robot arm) and the description information of the structural characteristics of the operation arm may be manually input by the operator, or may be obtained by using the aforementioned series of automatic obtaining methods, which will not be described again here.

When the robot is used specifically, the task freedom degree of the far end (namely a power mechanism) of the mechanical arm can be optionally and independently configured so that the mechanical arm is independently controlled; or individually configure the task degrees of freedom of the distal end of the manipulator arm (i.e., the end instrument) such that the manipulator arm is independently controlled; alternatively, the robotic arm and manipulator arm may be considered as a tandem structure, with the degrees of freedom of the task at the distal end of the manipulator arm being configured to allow the two to be linked.

The various controls described in the above embodiments may be generated by the control device to enable or disable the corresponding information when selected. The various controls described in the above embodiments may be included in the same interface, or may be included in different interfaces, for example, "in generating a user interface component including a control with a degree of freedom that the robot arm can configure for the doctor and a control with a degree of freedom that the manipulator arm can configure for the doctor", it does not mean that the control with a degree of freedom that the robot arm can configure for the doctor and the control with a degree of freedom that the manipulator arm can configure for the doctor are necessarily displayed on the same interface, and they may be displayed on different two, three, or more interfaces.

For example, an interface configured by a user may be generated as shown in fig. 32, where the interface includes controls of three control modes, that is, controls of an independent control mode of a mechanical arm, an independent control mode of an operating arm, and a linkage control mode of the mechanical arm and the operating arm, and by selecting a specific control, the user may jump to another interface corresponding to the specific control to freely configure the task degree of freedom in the mode. In some cases, although it may happen that the controls corresponding to the task degrees of freedom included in the interface displayed in the three control modes are the same, the control device necessarily knows which of the cases the doctor has configured, and then uses the configuration information of these task degrees of freedom correctly in the control of the corresponding arm mechanism.

The control of the above embodiments may be one or a combination of two or more of a button control, a text box control, a drop-down list control, a check box control, and the like.

In one embodiment, the control device is configured to perform coordinated control of the joint assemblies of the arm mechanism in combination with configuration information of the task degrees of freedom of the distal end of the arm mechanism and operation information of the distal end of the arm mechanism controlled by the doctor.

Specifically, if the arm body mechanism to be controlled is a robot arm and/or an operation arm, the operation information may be own motion information collected via a motion input device connected to the control apparatus. The method mainly utilizes the pose information in the motion information.

If the controlled arm body mechanism is only the mechanical arm, the operation information may be not only the external force information directly applied to the distal end of the mechanical arm by the doctor but also the movement information of the doctor collected via the aforementioned movement input device.

In one embodiment, a method for controlling a surgical robot is provided, which is only suitable for controlling a case where an arm mechanism is a mechanical arm, and the method controls a distal end (and a power mechanism) of the arm mechanism by an external force following a doctor dragging the distal end, and includes the steps of:

and acquiring a six-dimensional force/moment vector of the external force.

And analyzing the six-dimensional force/moment vector of the external force into incremental pose information of the far end of the arm body mechanism.

And controlling the joint components of the arm body mechanism to be linked according to the incremental pose information of the far end of the arm body mechanism so as to enable the far end of the arm body mechanism to carry out incremental movement.

When the six-dimensional force/moment vector of the external force is analyzed to be the increment pose information of the far end of the arm body mechanism, the motion information can be analyzed to be the increment pose information of the arm body mechanism by combining the configuration information of the task freedom degree of the far end of the arm body mechanism. Furthermore, the motion information can be analyzed into the increment pose information of the arm mechanism according to the configuration information of the task freedom degree of the far end of the arm mechanism, and meanwhile, the increment pose information of the arm mechanism obtained through mapping is limited by combining the configuration information of the motion range of each task freedom degree of the arm mechanism.

In one embodiment, as shown in fig. 5, another control method for a surgical robot is provided, which is adapted to control a robot arm 21 or an operation arm 31, and includes the steps of:

in step S1, the motion information input by the motion input device is acquired.

And step S2, analyzing the motion information into incremental pose information of the far end of the arm body mechanism.

And step S3, controlling the linkage of each joint component of the arm body mechanism according to the incremental pose information so as to enable the distal end of the arm body mechanism to carry out incremental movement.

In step S2, motion information of preceding and following times is mainly analyzed, and the preceding and following times may be adjacent to each other in the front and back direction or spaced apart from each other in the front and back direction for a certain period of time. In one mode, the pose change of the motion information at the later time relative to the motion information at the previous time in a fixed coordinate system, that is, incremental pose information, is calculated. And then mapping the incremental pose information under the fixed coordinate system into the incremental pose information of the arm mechanism. The fixed coordinate system may be defined, for example, on the display, but it may also be defined elsewhere in the surgical robot, which is immovable at least during operation. Wherein "mapping" represents a relationship corresponding to the transformation.

In one embodiment, as shown in fig. 6, the distal end of each arm mechanism (the mechanical arm 21 or the operation arm 31) can be controlled to move to the target pose by a position control method. Specifically, in step S203, the method includes:

in step S31, position information of each joint component of the arm mechanism is acquired.

The corresponding position information can be obtained by a position sensor such as an encoder installed at the joint component. In the exemplary embodiment illustrated in fig. 1 and 4, the robot arm 21 has 5 degrees of freedom, and a set of position information (d1, θ) can be detected by means of position sensors₂，θ₃，θ₄，θ₅)。

In step S32, the current position information of the arm mechanism is calculated from the position information of each joint component.

Wherein, in general, mayTo perform calculations in conjunction with positive kinematics. Establishing a kinematic model from the fixed point of the mechanical arm 21 (namely, the point C, the origin of the tool coordinate system of the mechanical arm 21 is on the fixed point) to the base of the mechanical arm 21, and outputting a model conversion matrix of the point C and the base

The calculation method is

And step S33, calculating the target pose information according to the current pose information and the incremental pose information of the arm body mechanism.

Wherein, the model conversion matrix is based on the C point and the base

And acquiring the pose information of the point C in the fixed coordinate system. Assuming that the coordinate system of the point C is rotated to the posture described by the model transformation matrix without changing the position of the point C, the rotation axis angle [ theta ] can be obtained_x0,θ_y0,θ_z0]As shown in fig. 7. Theta_x0Is the roll angle, theta_y0Is yaw angle, θ_z0For pitch angle, whereas in the robot arm 21 shown in fig. 14, there is a lack of freedom of roll angle and thus theta is actually_x0Is not adjustable.

And step S34, calculating the target position information of each joint component of the arm body mechanism according to the target position and orientation information.

This step can typically be calculated in conjunction with inverse kinematics.

And step S35, controlling the linkage of each joint component of the arm body mechanism according to the target position information of each joint component so as to enable the far end of the arm body mechanism to move to the target pose.

Wherein, different information of the task degree of freedom of the arm body mechanism far end actually reflects different control requirements for the arm body mechanism far end. That is, it can be understood that the motion information is parsed according to different control requirements and mapped to incremental pose information of the arm mechanism.

In particular, the task degree of freedom of the distal end of the arm mechanism may be understood as the degree of freedom of the distal end of the arm mechanism allowing movement in cartesian space, which is at most 6. The effective degrees of freedom of the distal end of the arm mechanism, which are related to its configuration (i.e., structural features), are understood to mean the degrees of freedom that the distal end of the arm mechanism can achieve in cartesian space, which is likewise up to 6. The configuration information of the task degrees of freedom of the distal end of the arm body mechanism is the degrees of freedom in which the distal end of the arm body mechanism is allowed to move.

The motion information may be parsed from the information in step S2, and then the parsed motion information may be mapped to incremental pose information of the distal end of the arm mechanism. For example, if the information is to allow movement of three degrees of freedom [ x, y, z ] in pose information [ x, y, z, α, β, γ ], when motion information is analyzed, only motion information corresponding to the three degrees of freedom [ x, y, z ] is analyzed, and then the motion information corresponding to the three degrees of freedom [ x, y, z ] is mapped to incremental pose information of the distal end of the arm mechanism.

Of course, the motion information may be comprehensively analyzed first, and then the analyzed motion information is mapped to the incremental pose information of the distal end of the arm body mechanism according to the information. For example, the information is also allowed to move in three degrees of freedom [ x, y, z, α, β, γ ] in the pose information [ x, y, z, α, β, γ ], when the motion information is analyzed, the motion information corresponding to all six degrees of freedom [ x, y, z, α, β, γ ] is analyzed, and then the motion information corresponding to the three degrees of freedom [ x, y, z ] is mapped to the incremental pose information of the distal end of the arm body mechanism.

For example, in the robot arm 21 shown in FIG. 4, the information about the effective degrees of freedom of the robot arm 21 includes [ x, y, z, α, β ], which comes from the joint assemblies 210-214, which has no degree of freedom in roll angle γ:

if the configuration information of the task degree of freedom of the power mechanism 22 (which is installed at the far end of the mechanical arm 21 and used for installing and driving the operating arm 31) is [ x, y, z, α, β ], the configuration information of the task degree of freedom of the power mechanism 22 is completely matched with the information of the effective degree of freedom of the mechanical arm 21, and at this time, the power mechanism 22 is freely controlled, so that the power mechanism 22 can be controlled to move in a large range to adapt to the arrangement of the operating room;

if the configuration information for configuring the degrees of freedom of the task of the power mechanism 22 is [ x, y, z, α ] or [ x, y, z ], the configuration information for configuring the degrees of freedom of the task of the power mechanism 22 is included in the information of the effective degrees of freedom of the robot arm 21 and does not completely match with the information, and when the power mechanism is controlled, the adjustment can be performed only at several corresponding degrees of freedom [ x, y, z, α ] or [ x, y, z ], and at this time, the power mechanism 22 is subjected to constraint control, and the power mechanism 22 can be controlled within a limited range.

In particular, if the configuration information configuring the degree of freedom of the power mechanism 22 includes only α, β, this belongs to the RCM constraint control in the constraint control, i.e. the RCM constraint control moves around the remote motion center (i.e. the motionless point), and only the yaw angle and the pitch angle can be adjusted, which can meet the requirement of fine adjustment during the operation.

Of course, if the information of the effective degrees of freedom of the robot arm 21 includes [ x, y, z, α, β, γ ], the RCM constraint control may include a total of these various types of adjustment for yaw angle only, pitch angle only, roll angle only, yaw and pitch angle, yaw and roll angle, pitch and roll angle, and yaw, pitch and roll angles, by the configuration of the task degrees of freedom of the power mechanism 22.

In one arrangement, if the information about the arrangement of the degrees of freedom of the task of the power mechanism 22 is only partially included in the information about the effective degrees of freedom of the robot arm 21, a preferable option is to indicate an arrangement error, and another option is to allow only the partial degrees of freedom of the information about the effective degrees of freedom included in the robot arm 21 to be adjustable. Still taking the mechanical arm 21 shown in fig. 4 as an example, if the configuration information of the task degrees of freedom of the power mechanism 22 is [ y, z, α, β, γ ] or [ x, y, z, α, β, γ ], on the one hand, a configuration error message may be presented, and on the other hand, the adjustment of the corresponding degrees of freedom in [ y, z, α, β ] or [ x, y, z, α, β ] may be allowed. This can be configured according to actual needs.

In an embodiment, specifically in step S2, the motion information may be analyzed according to the configuration information of the task degrees of freedom at the distal end of the arm mechanism and mapped to the incremental pose information of the arm mechanism, and the mapped incremental pose information of the arm mechanism may be limited according to the configuration information of the motion range of each task degree of freedom of the arm mechanism. The configuration information of the task degree of freedom of the distal end of the arm mechanism and the configuration information of the range of motion thereof can be freely configured by the doctor according to the user interface components displayed on the display 12 described in the above embodiments.

The surgical robot may provide one or more motion-input devices 11. In an embodiment, the surgical robot provides two motion-input devices 11. For ease of operation, the two motion-input devices 11 are provided for operation by two hands, either by one person or by two persons. Controlled tip instrument 34 may selectively follow one motion-input device or two motion-input devices, i.e., controlled tip instrument 34 may follow either or both of the two motion-input devices 11, defining a one-to-one mode of operation for controlling the motion of one controlled tip instrument 34 with one motion-input device 11, and defining a two-to-one mode of operation for controlling the motion of one controlled tip instrument 34 together with two motion-input devices 11. In controlling the movement of one controlled end instrument 34, either a one-to-one or two-to-one mode of operation may be selected. For a one-to-one operation mode, it may further be chosen which motion-input device is used for control. For example, the same operator may control one controlled end instrument 34 in a two-to-one operation mode or two controlled end instruments 34 in a one-to-one operation mode, depending on the configuration.

In one embodiment, for one-to-one operation mode, the formula P is used for example_n＝KP_nObtaining pose information P of one motion-input device 11 corresponding to the selected operation at the nth time, where K is a scale factor, and in general, K is>0, more preferably, 1. gtoreq.K>And 0, so as to realize the scaling of the pose and facilitate the control.

In one embodiment, for the two-to-one operation mode, for example, the operation mode can be selectedFormula P_n＝K₁P_nL+K₂P_nRObtaining pose information P of the two motion-input devices 11 corresponding to the selected operation at the nth time, wherein K₁And K₂Respectively representing the scaling factors of different motion-input devices 11, typically K₁>0，K₂>0; more preferably, 1 is not less than K₁>0，1≥K₂>0。

Calculating incremental pose information Δ p of the motion input apparatus 11 corresponding to a one-to-one operation mode or a two-to-one operation mode at a certain time and after a certain time_{n_n-1}The method can be calculated according to the following formula:

Δp_{n_n-1}＝P_n-P_n-1

of course, mapping of the incremental pose information of the fixed coordinate system to the incremental pose information of controlled tip instrument 34 in the first coordinate system may generally be accomplished in conjunction with the task degrees of freedom of controlled tip instrument 34.

In one embodiment, referring to fig. 8 and 9, for the one-to-one operation mode, the steps of acquiring motion information input by the motion input device, and resolving and mapping the motion information into incremental pose information of the controlled tip instrument in the first coordinate system include:

step S211, acquiring first position information of the motion input device at the previous time.

Step S212, second position and posture information of the motion input equipment at the later moment is acquired. The latter time can be generally understood as the current time, and as the time changes, the latter time is relative to the former time of the later time. In step S211 and step S212, the pose information input by the motion input device selected for the one-to-one operation mode is acquired.

And step S213, calculating and acquiring the incremental pose information of the motion input equipment in the fixed coordinate system according to the first pose information and the second pose information of the motion input equipment.

Step S214, the incremental pose information of the motion input device in the fixed coordinate system is mapped to the incremental pose information of the controlled end instrument in the first coordinate system.

In one embodiment, referring to fig. 10 and 11, for the two-to-one operation mode, the step of acquiring the motion information input by the motion input device and resolving the motion information into incremental pose information of the distal end of the arm mechanism comprises:

step S221, respectively obtaining respective first position information of two motion input devices at a previous time.

Step S222, respectively obtaining second position information of the two motion input devices at the next moment.

And step S223, calculating and acquiring the incremental pose information of the two motion input devices in the fixed coordinate system by combining the proportion coefficient and the first pose information and the second pose information of the two motion input devices.

The step S223 can be specifically realized by the following steps:

calculating the increment position and posture information of the first position and posture information and the second position and posture information of one motion input device in a fixed coordinate system, and calculating the increment position and posture information of the first position and posture information and the second position and posture information of the other motion input device in the fixed coordinate system;

and calculating the increment pose information of one motion input device in the fixed coordinate system and the increment pose information of the other motion input device in the fixed coordinate system by combining the proportionality coefficients to respectively obtain the increment pose information of the two motion input devices in the fixed coordinate system.

Step S224, the incremental pose information of the two motion input devices in the fixed coordinate system is mapped to the incremental pose information of the controlled end instrument in the first coordinate system.

Wherein, in the two-to-one operation mode, for example, the proportionality coefficient K₁And K₂And if the values of the two motion input devices are both 0.5, the acquired incremental pose information represents the incremental pose information of the central point of the connecting line between the two motion input devices. According to the actual situation, K can be matched₁And K₂Additional assignments are made.

Further, consideration may be given to the configuration information of the task degrees of freedom of controlled tip instrument 34. On the one hand, only the pose information of the degrees of freedom of the motion-input device 11 associated with the task degrees of freedom of the controlled tip instrument 34 may be acquired in step S213 (or step S223), and then step S214 (or step S224) may be performed. On the other hand, it is also possible to acquire the pose information of all the effective degrees of freedom of the motion-input device in step S213 (or step S223), but map the pose information of the degree of freedom associated with the task degree of freedom of the controlled tip instrument 34 in the incremental pose information of the fixed coordinate system to the incremental pose information of the controlled tip instrument 34 in the first coordinate system in step S214 (or step S224), while maintaining the pose information of the degree of freedom not associated with the task degree of freedom of the controlled tip instrument 34.

In one embodiment, in implementing step S2, the following steps may be performed:

and correcting different parameters in different modes according to different types (related to the degree of freedom of the task) of the parameters contained in the acquired incremental pose information. If different types of parameters are corrected by setting different correction coefficients, the parameters before and after correction can be expressed as a relation of multiplication and division; or different compensation values can be set to correct different types of parameters, and the parameters before and after correction can be expressed as addition and subtraction relations; alternatively, different types of parameters may be modified in combination with the setting of the correction coefficient and the compensation value, and the parameters before and after the modification may be expressed as a relationship including multiplication, division, and addition and subtraction.

The step of performing the correction in different ways for different parameters may be performed in any step between steps S211 to S214 (steps S221 to S224). For example, it may be recommended to proceed in step S214 (or step S224). The step can more accurately reflect the operation intention of a doctor to reduce the influence of misoperation, can compensate the problem that part of rotation angles cannot reach due to the hand flexibility factor, and realizes the adjustment of any angle.

It is to be noted that, since the one-to-one operation mode and the two-to-one operation mode are different in habit or flexibility, even if different types of parameters in the incremental pose information are corrected in the same correction manner, different correction coefficients and/or compensation values can be set for the two operation modes.

Both the one-to-one and two-to-one modes of operation are applicable to different degrees of freedom of the task of the controlled end instrument. From the perspective of convenience and accuracy, the one-to-one operation mode is suitable for the case that the controlled end instrument has more freedom degrees of task (for example, more than 4 freedom degrees of task), and the two-to-one operation mode is suitable for the case that the controlled end instrument has less freedom degrees of task (for example, within 3 freedom degrees of task).

By correcting the related incremental information, the operation intention of a doctor can be more accurately reflected, the influence of misoperation can be reduced, the problem that part of rotation angles cannot be reached due to hand flexibility factors can be compensated, and the adjustment of any angle can be realized.

In one embodiment, when the doctor controls the distal end of the arm mechanism (for example, the controlled end instrument) to move to the target pose, and the doctor finds that the distal end of the arm mechanism cannot move to the target pose when the hand moves to the extreme pose, an input device for outputting a control command for holding the pose and a control command for releasing the holding of the pose may be provided in the master console and/or the slave operation device. If the hand needs to be restored to the pose easy to operate, the output device needs to be triggered to output a control command for keeping the pose, and then after the control command is obtained, the pose of the far end of the arm body mechanism is kept unchanged, namely the far end of the arm body mechanism is not controlled to move along with the hand, so that the hand can be restored to the pose easy to operate; and then, if the arm body mechanism needs to be adjusted continuously, the output device needs to be triggered to output a control command for releasing the position and posture, and the far end of the arm body mechanism moves along with the hand again after the control command is acquired. In order to ensure that the two control commands can be intervened at any time and to free the hands, the input device may be configured as a speech recognition module or as a foot-operated input device or the like.

For example, when a two-to-one operation mode is adopted, the RCM constraint control can be conveniently and accurately performed on the controlled terminal instrument, and at this time, only the position information included in the motion information needs to be analyzed and mapped into the posture information of the controlled terminal instrument, so that the two motion input devices are easily utilized for control.

For example, the translational motion information of the two motion input devices 11 in the horizontal direction may be analyzed and mapped to yaw angle increment information of the controlled end instrument in the first coordinate system, the translational motion information of the two motion input devices 11 in the vertical direction may be analyzed and mapped to pitch angle increment information of the controlled end instrument in the first coordinate system, and the rotational motion information of the two motion input devices 11 in any plane, such as the vertical plane, may be analyzed and mapped to roll angle increment information of the controlled end instrument in the first coordinate system, for example, as shown in fig. 12, the horizontal movement increment information, the vertical movement increment information, and the rotational increment information of the two motion input devices 11 in the fixed coordinate system may be performed by the following steps:

step S231, respectively acquiring respective first position information of the two motion input devices at the previous time.

Step S232, respectively obtaining second position information of the two motion input devices at the later time.

And step S233, calculating and acquiring horizontal movement increment information, vertical movement increment information and rotation increment information of the two motion input devices in a fixed coordinate system by combining the proportionality coefficient and the first position information and the second position information of the two motion input devices.

In step S233, the horizontal movement increment information and the vertical movement increment information of the fixed coordinate system may be obtained by calculation according to the method described above, and the rotation increment information of the fixed coordinate system may be obtained by calculation, for example, as shown in fig. 13 and 14:

in step S2331, a first position vector between two motion-input devices at a previous time is established.

In step S2332, a second position vector between the two motion-input devices at a later time is established.

Step S2333, calculating an included angle between the first position vector and the second position vector by combining the scaling factor, and further obtaining rotation increment information of the two pieces of motion equipment in the fixed coordinate system.

Step S2334, mapping the horizontal movement increment information, the vertical movement increment information and the rotation increment information of the two motion devices in a fixed coordinate system into yaw angle increment information, pitch angle increment information and roll angle increment information of the controlled terminal instrument in a one-to-one manner.

An input device can be configured in the master console and/or the slave console, and the input device is used for outputting a control command for switching the mapping relationship. For example, the mapping relationships include natural mapping relationships and unnatural mapping relationships.

The natural mapping relationship may be defined as incremental pose information of the controlled end instrument in the first coordinate system, which is obtained by analyzing motion information and mapping incremental pose information of the controlled end instrument in the first coordinate system in a one-to-one manner according to the type of parameters of the incremental pose information, specifically, mapping incremental horizontal movement information of the fixed coordinate system to incremental horizontal movement information of the controlled end instrument in the first coordinate system, mapping incremental vertical movement information of the fixed coordinate system to incremental vertical movement information of the controlled end instrument in the first coordinate system, mapping incremental back-and-forth movement information of the fixed coordinate system to incremental back-and-forth movement information of the controlled end instrument in the first coordinate system, mapping incremental yaw angle information of the fixed coordinate system to incremental yaw angle information of the controlled end instrument in the first coordinate system, mapping incremental pitch angle information of the fixed coordinate system to incremental pitch angle information of the controlled end instrument in the first coordinate system, and mapping incremental pitch angle information of the controlled end instrument in the first coordinate system, And mapping the roll angle increment information of the fixed coordinate system to the roll angle increment information of the controlled terminal instrument in the first coordinate system. These may each be selected based on configuration information for the task degrees of freedom of the controlled tip instrument.

The unnatural mapping is a mapping other than the natural mapping, and in one example, the unnatural mapping includes, but is not limited to, a transformation mapping, which includes, but is not limited to, the aforementioned one-to-one mapping of the horizontal movement increment information, the vertical movement increment information, and the rotation increment information of the fixed coordinate system to the yaw increment information, the pitch increment information, and the roll increment information of the controlled tip instrument. Being configured in an unnatural mapping allows for easier control of the controlled end instrument in certain situations, such as in a two-to-one mode of operation.

And analyzing the motion information and mapping the motion information into the incremental pose information of the remote end of the controlled end instrument in the first coordinate system by combining the acquired configuration information of the task degree of freedom of the remote end of the controlled end instrument, and/or the type information of the operation mode and/or the type information of the mapping relation. Furthermore, the doctor can set a mode which is easy to understand and convenient to operate according to own habits.

Wherein, the mechanical arm and the operation arm can be configured to be in a natural mapping relation or a non-natural mapping relation, or one of the mechanical arm and the operation arm is configured to be in a natural mapping relation and the other is configured to be in a non-natural mapping relation. This can be configured or selected in a predefined configuration by an input device provided in the master console and/or the slave console depending on the purpose of operation.

The above described embodiments are suitable for controlling a surgical robot of the type shown in figure 1. The surgical robot of this type includes one robot arm 21 and one or more operation arms 31 having end instruments 34 installed at the distal end of the robot arm 21, and the robot arm 21 and the operation arms 31 each have several degrees of freedom.

The above embodiments are equally applicable to the control of a surgical robot of the type shown in figure 33. The surgical robot of this type includes a main arm 32 ', one or more adjusting arms 30' installed at a distal end of the main arm 32 ', and one or more manipulation arms 31' having a distal end instrument installed at a distal end of the adjusting arm 30 ', the main arm 32', the adjusting arm 30 ', and the manipulation arm 31' each having several degrees of freedom. As shown in fig. 33, in the surgical robot, four adjustment arms 30 ' may be provided, and only one operation arm 31 ' may be provided for each adjustment arm 30 '. According to the actual use scenario, the three-segment arm structure of the surgical robot shown in fig. 33 can be configured as the two-segment arm structure of the surgical robot shown in fig. 1 to realize control. In an embodiment, in case the concepts of the operation arms in the two types of surgical robots are identical, for example, depending on the configuration, each adjustment arm 30' in the type of surgical robot shown in fig. 33 may be regarded as a robot arm 21 in the type of surgical robot shown in fig. 1 to control; for example, depending on the arrangement, the entire adjustment arm 30 'and the entire main arm 32' of the surgical robot of the type shown in fig. 33 may be controlled as the robot arm 21 of the surgical robot of the type shown in fig. 1. In one embodiment, the main arm 32 ' of the surgical robot of the type shown in fig. 33 may be regarded as the mechanical arm 21 of the surgical robot of the type shown in fig. 1, and the whole of the adjusting arm 30 ' and the corresponding operation arm 31 ' of the surgical robot of the type shown in fig. 33 may be regarded as the operation arm 31 of the surgical robot of the type shown in fig. 1 for control.

The aforementioned input devices configured for various purposes of the master console (including motion input devices) and/or the slave console include, but are not limited to, touch screens, buttons, knobs, pedals, and voice recognition modules. They can be used in combination or individually; they may be used in the same manner or in plural. For example, the input device is mostly configured at the main console, so that the doctor can operate the input device without leaving the current position. For example, the input device may mostly adopt a voice recognition module, and generate and output a corresponding control command according to the voice of the doctor to select a corresponding mode, so that the surgical robot has a relatively simple structure, frees both hands and feet, and can implement more continuous (i.e., without interrupting the current operation) operations.

In one embodiment, the control method of the surgical robot is generally configured to be implemented in a control device of the surgical robot, and the control device has more than one processor.

In one embodiment, a computer-readable storage medium is provided, in which a computer program is stored, the computer program being configured to be executed by one or more processors to implement the steps of the control method according to any one of the above-mentioned embodiments.

The surgical robot, the control method thereof and the computer readable storage medium of the invention have the following advantages:

the far end of the arm body mechanism can move along with the hands of a doctor, the doctor can move the far end of the arm body mechanism to an expected pose without separating from a seat, and the arm body mechanism is easy and convenient to operate and has excellent flexibility.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (13)

1. A control method of a surgical robot is characterized by comprising the following steps:

obtaining description information describing structural characteristics of an arm body mechanism, wherein the description information comprises joint component information of the arm body mechanism, connecting rod component information and motion range information of each joint component;

generating a user interface component containing a control of joint freedom degree which can be configured by the arm body mechanism according to the joint component information of the arm body mechanism and the connecting rod component information;

generating a user interface component containing a control of a motion range corresponding to each joint degree of freedom which can be configured by the arm body mechanism according to the motion range information of each joint component of the arm body mechanism;

and acquiring an operation instruction generated by the control operation aiming at the joint freedom degree, and enabling and/or disabling the corresponding joint freedom degree according to the operation instruction so as to change the configuration of the arm body mechanism.

2. The control method according to claim 1, characterized in that:

the description information further includes information of effective degrees of freedom of the arm mechanism;

after the step of obtaining the description information describing the structural characteristics of the arm body mechanism, the method further comprises the following steps:

and generating a user interface component containing a control of the task freedom degree which can be configured by the arm body mechanism according to the information of the effective freedom degree of the arm body mechanism.

3. The control method according to claim 2, characterized in that:

after the step of obtaining the description information describing the structural characteristics of the arm body mechanism, the method further comprises the following steps:

acquiring an operation instruction generated aiming at the control operation, and generating information of task freedom degree according to the operation instruction;

and calling a user interface component of a control of a common task mode which contains the information of the task freedom degree, which is available for configuration of the arm body mechanism and comprises and is related to the information of the task freedom degree according to the generated information of the task freedom degree.

4. The control method according to claim 3, characterized in that:

the common task mode is a combination of more than two task degrees of freedom which is preset.

5. The control method according to claim 4, characterized in that:

the common task mode comprises all the task degrees of freedom which can be configured, and/or the task degree of freedom related to the posture degree of freedom in all the task degrees of freedom which can be configured, and/or the task degree of freedom related to the position degree of freedom in all the task degrees of freedom which can be configured.

6. The control method according to claim 3, characterized in that:

the common task mode is a combination of more than two task degrees of freedom generated from high to low according to the recorded historical use frequency.

7. The control method according to claim 3, characterized in that:

the common task mode is a combination which is generated according to the control configuration of the task freedom degree and comprises more than two task freedom degrees.

8. The control method according to claim 2, characterized in that:

after the step of obtaining the description information describing the structural characteristics of the arm body mechanism, the method further comprises the following steps:

and acquiring an operation instruction generated aiming at the control operation, and generating configuration information of the task freedom degree of the arm body mechanism according to the operation instruction.

9. The control method according to claim 2, characterized in that:

the description information also comprises the motion range information of each effective degree of freedom in the arm body mechanism;

after the step of obtaining the description information describing the structural characteristics of the arm body mechanism, the method further comprises the following steps:

and generating a user interface component containing a control of the motion range corresponding to each task degree of freedom which can be configured by the arm body mechanism according to the motion range information of each effective degree of freedom of the arm body mechanism.

10. The control method according to claim 1, characterized in that:

in the step of generating a user interface component including a control of joint degrees of freedom that the arm body mechanism can be configured to according to the joint component information of the arm body mechanism and the link assembly information, the method includes:

and generating a user interface component which comprises a model image simulating the structure of the arm body mechanism and a control part with joint freedom degrees for configuration at each joint component in the model image according to the joint component information and the connecting rod component information of the arm body mechanism.

11. A computer-readable storage medium, characterized in that it stores a computer program configured to be loaded by a processor and to execute steps implementing a control method according to any one of claims 1 to 10.

12. A control device for a surgical robot, comprising:

a memory for storing a computer program;

and a processor for loading and executing the computer program;

wherein the computer program is configured to be loaded by the processor and to execute steps implementing a control method according to any of claims 1-10.

13. A surgical robot, comprising:

an arm mechanism for performing a surgical procedure;

a display for displaying user interface components;

and a control device connected with the arm body mechanism and the display and used for executing the steps of realizing the control method according to any one of claims 1-10.

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