CN109330685A - A kind of porous abdominal operation robot laparoscope automatic navigation method - Google Patents

Abstract

The invention discloses a kind of porous abdominal operation robot laparoscope automatic navigation methods, this method utilizes the interventional operation equipment and surgical field of view image processing techniques for carrying multiple mark points, pass through the adjust automatically of adjust automatically and laparoscope focal length to operation field-of-view image center, so that field of view image keeps clear, surgical instrument distal end is always positioned in the suitable field of view of operative doctor, surgical quality and efficiency can be effectively improved, the labor intensity of doctor is reduced.

Description

A kind of porous abdominal operation robot laparoscope automatic navigation method

Technical field

The present invention relates to Minimally Invasive Surgery field more particularly to porous abdominal operation robot laparoscope automatic navigation technologies.

Background technique

Porous abdominal operation robot has robot control system, robots arm, interventional operation equipment and binocular phase Mechanism at laparoscope, image that surgeon is generated by means of laparoscope with the hands operates robot control system Main hand, to control the movement and operation of interventional operation equipment.Porous abdominal operation robot can make surgeon more square Just carry out Minimally Invasive Surgery, effectively reduce the fatigue of operative doctor, improve surgical quality and efficiency, operative incision is small, Huan Zheyi In recovery.

In laparoscopic procedures, surgeon need to receive hand by the binocular camera (laparoscope) being placed in the patient The stereoscopic vision in art region is fed back, to carry out accurate surgical procedure.In order to keep suitable operation field of view and figure The high quality of picture, camera posture and focal length need to adjust movement and behaviour to follow surgical instrument in due course according to operation actual conditions Make.Currently used technology includes the modes such as voice control, surgeon's visual pursuit, foot pedal control, but these modes are deposited Additional burden is being brought to operative doctor, is difficult to the problems such as flexibly being accurately controlled to camera.

It is therefore, clinical that there is an urgent need to camera posture and the schemes of Focussing in a kind of convenient accurate art.

Chinese Patent Application No. 201580025333.2 proposes " for controlling the position of camera in surgical robot system System and method ", it carries out artificial master & slave control to camera using the method for control mode switch.In that patent, machine People's surgery systems include at least one robots arm, camera and console.Console include first handle, second handle and It is configured to carry out the selector switch of selection between robot control model and camera control model.In systems, first Handle or second handle control at least one robots arm under robot control model, and first handle and second handle exist Camera is controlled under camera control model.This mode needs to switch between two different control modes, in real time Property is poor, and increases the added burden of operative doctor.

Using the interventional operation equipment and surgical field of view image processing techniques for carrying multiple mark points, to automatically adjust abdominal cavity Mirror posture and camera focus, have many advantages, such as economical, convenient, accurate, can effectively reduce the burden of doctor, improve surgical quality and Efficiency.

Summary of the invention

The technical problem to be solved by the present invention is to provide a kind of porous abdomen for defect involved in background technique Chamber operating robot laparoscope automatic navigation method.

The present invention uses following technical scheme to solve above-mentioned technical problem:

A kind of porous abdominal operation robot laparoscope automatic navigation method comprising the steps of:

Step 1), clinical operation doctor region according to locating for patient's lesion, adjusts the pose of laparoscope, so that lesion is located at Surgical field of view and image clearly, and it is located at two interventional operation equipment distal ends in the visual field；It is remote for each interventional operation equipment End is equipped at least two for demarcating its institute's mark point on straight line thereon, record each mark point and its end away from From；

Step 2) calculates the intersecting point coordinate O of the straight line where the first two interventional operation equipment distal end₀, current laparoscope Focal length f₀And the angle α when the first two interventional operation equipment end and the formation of surgical field of view picture centre line₀；

Step 2.1) obtains the focal length f of current procedure field-of-view image and laparoscope₀: worked as using image acquisition units acquisition The image of preceding surgical field of view, and record the focal length f of current laparoscope₀；

Step 2.2) obtains the image coordinate of two upper all mark points in interventional operation equipment distal end: according to surgical field of view Image detects two all mark points in interventional operation equipment distal end, records the image coordinate of all mark points；

Step 2.3), the equation and ending coordinates of straight line where obtaining two interventional operation equipments: according to each mark point Coordinate, determine linear equation of two interventional operation equipments distal end in surgical field of view image, and according to interventional operation equipment Each mark point and the distance of its end calculate the ending coordinates of each interventional operation equipment；

Step 2.4) calculates two according to linear equation of two interventional operation equipment distal ends in surgical field of view image The intersecting point coordinate O of straight line where interventional operation equipment distal end₀；

Step 2.5) calculates the angle of two interventional operation equipment ends and the formation of surgical field of view picture centre line α₀, enabling two interventional operation equipment ends is respectively E₁、E₂, surgical field of view picture centre is O, connects E₁O and E₂O, then E₁O with And E₂Angle between O is α₀；

Step 3) after two interventional operation equipment distal ends are mobile, calculates straight line where two interventional operation equipment distal ends Intersecting point coordinate O₁, the angle α that is formed of two interventional operation equipment ends and surgical field of view picture centre line₁；

Step 3.1), the surgical field of view image after obtaining movement；

Step 3.2) detects two all labels in interventional operation equipment distal end according to the surgical field of view image after movement Point records the image coordinate of all mark points；

Step 3.3), the equation and ending coordinates of straight line where two interventional operation equipments after obtaining movement: according to shifting The coordinate of each mark point after dynamic determines straight line side of mobile latter two interventional operation equipment distal end in surgical field of view image Journey, and according to the distance of each mark point of interventional operation equipment and its end calculate it is mobile after each interventional operation equipment end Sit up straight mark；

Step 3.4) is calculated according to linear equation of mobile latter two interventional operation equipment distal end in surgical field of view image The intersecting point coordinate O of straight line where moving latter two interventional operation equipment distal end out₁；

Step 3.5) calculates what latter two mobile interventional operation equipment end was formed with surgical field of view picture centre line Angle α₁；

Step 4) calculates variable angle ratio r, r=α₁/α₀, the focal length f, f=f of laparoscope are adjusted according to r₀/r；

Step 5) adjusts the posture of laparoscope, moves the center of surgical field of view image, and displacement and intersection point are sat Mark O₀、O₁Between displacement it is identical.

As a kind of further prioritization scheme of porous abdominal operation robot laparoscope automatic navigation method of the invention, institute It states two interventional operation equipments distal end and is respectively provided with that there are three spherical labels points.

The invention adopts the above technical scheme compared with prior art, has following technical effect that

The present invention is led using the surgical instrument and surgical field of view image processing techniques that carry multiple mark points by laparoscope Boat initialization and two steps of self-navigation are automatically adjusted laparoscope posture and laparoscope focal length in real time, have it is economical, The advantages that convenient, accurate, can effectively reduce the burden of doctor, improve surgical quality and efficiency, be conducive to clinical diagnosis and treatment.

Detailed description of the invention

Fig. 1 is flow diagram of the invention；

Fig. 2 is two interventional operation equipment ends, surgical field of view picture centre, intersecting point coordinate O in the present invention₀Between pass It is schematic diagram；

Fig. 3 is the schematic diagram of one of interventional operation equipment distal marker point in the present invention.

Specific embodiment

Technical solution of the present invention is described in further detail with reference to the accompanying drawing:

As shown in Figure 1, the invention discloses a kind of porous abdominal operation robot laparoscope automatic navigation method, comprising with Lower step:

Step 1), clinical operation doctor region according to locating for patient's lesion, adjusts the pose of laparoscope, so that lesion is located at Surgical field of view and image clearly, and it is located at two interventional operation equipment distal ends in the visual field；It is remote for each interventional operation equipment End is equipped at least two for demarcating its institute's mark point on straight line thereon, record each mark point and its end away from From；

Step 2) calculates the intersecting point coordinate O of the straight line where the first two interventional operation equipment distal end₀, current laparoscope Focal length f₀And the angle α when the first two interventional operation equipment end and the formation of surgical field of view picture centre line₀；

Step 2.1) obtains the focal length f of current procedure field-of-view image and laparoscope₀: worked as using image acquisition units acquisition The image of preceding surgical field of view, and record the focal length f of current laparoscope₀；

Step 2.2) obtains the image coordinate of two upper all mark points in interventional operation equipment distal end: according to surgical field of view Image detects two all mark points in interventional operation equipment distal end, records the image coordinate of all mark points；

Step 2.3), the equation and ending coordinates of straight line where obtaining two interventional operation equipments: according to each mark point Coordinate, determine linear equation of two interventional operation equipments distal end in surgical field of view image, and according to interventional operation equipment Each mark point and the distance of its end calculate the ending coordinates of each interventional operation equipment；Calculate each interventional operation equipment Ending coordinates when, in fact it is only necessary to know that in interventional operation equipment a mark point and its end distance, but can To be corrected with the distance of other mark points and its end, keep its more accurate；

Step 2.4) calculates two according to linear equation of two interventional operation equipment distal ends in surgical field of view image The intersecting point coordinate O of straight line where interventional operation equipment distal end₀；

Step 2.5) calculates the angle of two interventional operation equipment ends and the formation of surgical field of view picture centre line α₀, as shown in Fig. 2, enabling two interventional operation equipment ends is respectively E₁、E₂, surgical field of view picture centre is O, connects E₁O and E₂O, then E₁O and E₂Angle between O is α₀；

Step 3) after two interventional operation equipment distal ends are mobile, calculates straight line where two interventional operation equipment distal ends Intersecting point coordinate O₁, the angle α that is formed of two interventional operation equipment ends and surgical field of view picture centre line₁；

Step 3.1), the surgical field of view image after obtaining movement；

Step 3.2) detects two all labels in interventional operation equipment distal end according to the surgical field of view image after movement Point records the image coordinate of all mark points；

Step 3.3), the equation and ending coordinates of straight line where two interventional operation equipments after obtaining movement: according to shifting The coordinate of each mark point after dynamic determines straight line side of mobile latter two interventional operation equipment distal end in surgical field of view image Journey, and according to the distance of each mark point of interventional operation equipment and its end calculate it is mobile after each interventional operation equipment end Sit up straight mark；

Step 3.4) is calculated according to linear equation of mobile latter two interventional operation equipment distal end in surgical field of view image The intersecting point coordinate O of straight line where moving latter two interventional operation equipment distal end out₁；

Step 3.5) calculates what latter two mobile interventional operation equipment end was formed with surgical field of view picture centre line Angle α₁；

Step 4) calculates variable angle ratio r, r=α₁/α₀, the focal length f, f=f of laparoscope are adjusted according to r₀/r；

Step 5) adjusts the posture of laparoscope, moves the center of surgical field of view image, and displacement and intersection point are sat Mark O₀、O₁Between displacement it is identical.

As shown in figure 3, described two interventional operation equipment distal ends are respectively provided with, there are three spherical labels points.

Those skilled in the art can understand that unless otherwise defined, all terms used herein (including skill Art term and scientific term) there is meaning identical with the general understanding of those of ordinary skill in fields of the present invention.Also It should be understood that those terms such as defined in the general dictionary should be understood that have in the context of the prior art The consistent meaning of meaning will not be explained in an idealized or overly formal meaning and unless defined as here.

Above-described specific embodiment has carried out further the purpose of the present invention, technical scheme and beneficial effects It is described in detail, it should be understood that being not limited to this hair the foregoing is merely a specific embodiment of the invention Bright, all within the spirits and principles of the present invention, any modification, equivalent substitution, improvement and etc. done should be included in the present invention Protection scope within.

Claims (2)

1. a kind of porous abdominal operation robot laparoscope automatic navigation method, which is characterized in that comprise the steps of:

Step 1), clinical operation doctor region according to locating for patient's lesion, adjusts the pose of laparoscope, so that lesion is located at operation The visual field and image clearly, and it is located at two interventional operation equipment distal ends in the visual field；For each interventional operation equipment distal end, its On be equipped at least two for demarcate its mark point on straight line, record the distance of each mark point He its end；

Step 2) calculates the intersecting point coordinate O of the straight line where the first two interventional operation equipment distal end₀, current laparoscope focal length f₀And the angle α when the first two interventional operation equipment end and the formation of surgical field of view picture centre line₀；

Step 2.1) obtains the focal length f of current procedure field-of-view image and laparoscope₀: current procedure is obtained using image acquisition units The image in the visual field, and record the focal length f of current laparoscope₀；

Step 2.2) obtains the image coordinate of the upper all mark points in two interventional operation equipments distal end: according to surgical field of view image, Two all mark points in interventional operation equipment distal end are detected, the image coordinate of all mark points is recorded；

Step 2.3), the equation and ending coordinates of straight line where obtaining two interventional operation equipments: according to the seat of each mark point Mark determines linear equation of two interventional operation equipment distal ends in surgical field of view image, and each according to interventional operation equipment Mark point and the distance of its end calculate the ending coordinates of each interventional operation equipment；

Step 2.4) calculates two interventions according to linear equation of two interventional operation equipment distal ends in surgical field of view image The intersecting point coordinate O of straight line where surgical instrument distal end₀；

Step 2.5) calculates the angle α of two interventional operation equipment ends and the formation of surgical field of view picture centre line₀, enable two A interventional operation equipment end is respectively E₁、E₂, surgical field of view picture centre is O, connects E₁O and E₂O, then E₁O and E₂O it Between angle be α₀；

Step 3), after two interventional operation equipment distal ends are mobile, the friendship of straight line where calculating two interventional operation equipment distal ends Point coordinate O₁, the angle α that is formed of two interventional operation equipment ends and surgical field of view picture centre line₁；

Step 3.1), the surgical field of view image after obtaining movement；

Step 3.2) detects two all mark points in interventional operation equipment distal end, note according to the surgical field of view image after movement Record the image coordinate of all mark points；

Step 3.3), the equation and ending coordinates of straight line where two interventional operation equipments after obtaining movement: after movement Each mark point coordinate, determine linear equation of mobile latter two interventional operation equipment distal end in surgical field of view image, And the end of each interventional operation equipment after movement is calculated according to the distance of each mark point of interventional operation equipment and its end Coordinate；

Step 3.4) calculates shifting according to linear equation of mobile latter two interventional operation equipment distal end in surgical field of view image The intersecting point coordinate O of straight line where moving latter two interventional operation equipment distal end₁；

Step 3.5) calculates the angle of latter two mobile interventional operation equipment end and the formation of surgical field of view picture centre line α₁；

Step 4) calculates variable angle ratio r, r=α₁/α₀, the focal length f, f=f of laparoscope are adjusted according to r₀/r；

Step 5) adjusts the posture of laparoscope, moves the center of surgical field of view image, displacement and intersecting point coordinate O₀、 O₁Between displacement it is identical.

2. porous abdominal operation robot laparoscope automatic navigation method according to claim 1, which is characterized in that described Two interventional operation equipments distal end is respectively provided with that there are three spherical labels points.