CN212438831U - Positioning scale - Google Patents

Abstract

The embodiment discloses a positioning scale, which comprises a first flat panel, a second flat panel and a connecting panel; the first and second flat panels do not intersect; the first flat panel and the second flat panel are connected through the connecting panel; the first flat panel, the second flat panel and the connecting panel are all transparent to X-rays; the first flat panel and the second flat panel are respectively provided with four mark points, and each mark point is an X-ray opaque component. Adopt the utility model discloses can effectively reduce the location consuming time, effectively improve location efficiency, and then can effectively reduce the operation consuming time.

Description

Positioning scale

Technical Field

The utility model relates to a space positioning technical field, concretely relates to location scale.

Background

With the development of human-computer interaction technology, more and more surgical robots are used to assist doctors in performing surgery. In order to improve the precision of the operation and reduce the perspective radiation, the target position of the operation needs to be accurately positioned in space.

At this stage, an existing positioning scale is usually used as a reference datum for spatial positioning. Specifically, the conventional positioning ruler is usually based on the principle of a biplane positioning algorithm, and when performing biplane positioning, first, three marking points are set in a front and rear coordinate system of each plane, the conventional positioning ruler is installed between an X-ray (X-ray) light source and an X-ray imaging device, and the X-ray (X-ray) light source is adjusted so that an optical axis of the light source is perpendicular to the marking points of the positioning ruler, so that a generated X-ray perspective image simultaneously includes the marking points of an operation site and the coordinate system. Then, the coordinates of the target position may be calculated based on the principle of scaling.

In the prior art, in actual operation, the position is usually required to be adjusted for many times to enable the optical axis to be perpendicular to the mark point of the positioning scale under the limitation of operation conditions, so that the positioning time is long, and the positioning efficiency is low.

SUMMERY OF THE UTILITY MODEL

Because of the technical problem, an embodiment of the present invention provides a positioning scale, including a first flat panel, a second flat panel and a connecting panel; the first and second flat panels do not intersect; the first flat panel and the second flat panel are connected through the connecting panel;

the first flat panel, the second flat panel and the connecting panel are all transparent to X-rays; the first flat panel and the second flat panel are respectively provided with four mark points, and each mark point is an X-ray opaque component.

Optionally, the thickness of the connecting plate, the thickness of the first plane plate and the thickness of the second plane plate are the same; the connecting panel is a plane plate or a curved plate.

Optionally, a first connection interface is arranged on the lower surface of the bottom surface of the connection panel, and the first connection interface is used for connecting the multi-degree-of-freedom holding device.

Optionally, one side of the connection panel is provided with a second connection interface, and the second connection interface is used for connecting an optical tracking device.

Optionally, each of the mark points is a hard small ball opaque to X-ray.

Optionally, the distance between any two of the four mark points arranged on each of the plane plates is different.

Optionally, the cross ratio corresponding to the mark point arranged on the first flat panel is different from the cross ratio corresponding to the mark point arranged on the second flat panel.

According to the above technical scheme, the embodiment of the utility model provides a location scale includes two disjoint plane boards, and each plane all has the mark point. Like this, need not to carry out angular adjustment, can both carry out the shooting of X-ray perspective image at arbitrary angle to can effectively reduce the location consuming time, effectively improve location efficiency, and then can effectively reduce the operation consuming time.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a positioning scale according to an embodiment of the present invention;

fig. 2 is a schematic flow chart of a method for locating a landmark according to an embodiment of the present invention;

fig. 3 is a schematic diagram illustrating a distribution of the mark points according to an embodiment of the present invention;

fig. 4 is a schematic diagram illustrating a distribution of the mark points according to an embodiment of the present invention;

fig. 5 is a schematic view of an X-ray perspective image according to an embodiment of the present invention;

fig. 6 is a schematic view of projective transformation according to an embodiment of the present invention.

Detailed Description

The following describes the present invention with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.

Figure 1 shows a positioning scale provided by the present embodiment,

a first flat panel 2, a second flat panel 3 and a connection panel 1; the first and second flat panels 2 and 3 do not intersect; the first flat panel 2 and the second flat panel 3 are connected through the connecting panel 1; the connection panel 1 in fig. 1 comprises panels for each side of a first planar panel 2 and a second planar panel 3.

The first flat panel 2, the second flat panel 3 and the connecting panel 1 are all transparent to X-rays, the first flat panel 2 and the second flat panel 3 are respectively provided with four mark points 21 and 31, and each mark point is an X-ray opaque component. Wherein four marking points 21 are arranged on the first planar sheet 2 and four marking points 31 are arranged on the second planar sheet 3.

Further, the thickness of the connection panel 1, the thickness of the first flat panel 2 and the thickness of the second flat panel 3 are all the same, and if the thickness of the first flat panel 2 is 1mm, the thickness of the connection panel 1 and the thickness of the second flat panel 3 are all 1 mm; the connection panel 1 may be a flat plate or a curved plate.

Further, a first connection port 11 is provided on a lower surface of a bottom surface of the connection panel 1, and the first connection port 11 is used for connecting a multi-degree-of-freedom gripping device. The first connection interfaces 11 are stud bump structures in fig. 1, the number and size of the stud bump structures may be two, or may be set according to actual needs, and the stud bump structures may be used to connect other devices such as a multi-degree-of-freedom holding device.

Further, one side of the connection panel 1 is provided with a second connection interface 4, which second connection interface 4 may be used for connecting an optical tracking device.

Further, each marker point is a hard X-ray opaque bead.

Furthermore, the distance between any two of the four mark points arranged on each plane board is different.

Furthermore, the cross ratio corresponding to the mark point arranged on the first flat panel is different from the cross ratio corresponding to the mark point arranged on the second flat panel. That is, the intersection ratios corresponding to the four marking points 21 on the first flat panel 2 are different from the intersection ratios corresponding to the four marking points 31 on the second flat panel 3.

According to the above technical scheme, the embodiment of the utility model provides a location scale includes two disjoint plane boards, and each plane all has the mark point. Like this, need not to carry out angular adjustment, can both carry out the shooting of X-ray perspective image at arbitrary angle to can effectively reduce the location consuming time, effectively improve location efficiency, and then can effectively reduce the operation consuming time.

Fig. 2 shows a schematic flow chart of a landmark positioning method provided in this embodiment, where the embodiment of the method is implemented based on the positioning scale shown in fig. 1, and the landmark positioning method includes:

s201, determining a reference cross ratio corresponding to the mark points on each plane board of the positioning scale, shooting an X-ray perspective image of the positioning scale through medical imaging equipment, extracting coordinates of eight mark points from the X-ray perspective image, and selecting one reference mark point from the eight mark points according to the coordinates of the eight mark points.

Wherein the reference cross ratio refers to a cross ratio determined based on four marker points on each plane plate of the positioning scale.

The reference mark point refers to a mark point selected as a reference according to the coordinates of the mark point.

The calculation formula for determining the reference cross ratio is as follows:

wherein R represents the cross ratio, A, B, C and D respectively represent four collinear mark points, and R (A, B, C and D) represents the cross ratio of the mark points A, B, C and D; AC represents the distance between the marker points A and C; BC represents the distance between landmark points B and C; AD represents the distance between landmark points a and D; BD represents the distance between marker points B and D.

In implementation, first, the reference cross ratios corresponding to the four mark points on each plane plate of the positioning scale (i.e. the first plane plate and the second plane plate) may be determined, for example, the reference cross ratios corresponding to the mark points of the first plane plate 2 may be determined based on the four mark points 21 of the first plane plate 2, and the reference cross ratios corresponding to the mark points of the second plane plate 3 may be determined based on the four mark points 31 of the second plane plate 3, see fig. 3, which shows a distribution of the four mark points 21 of the first plane plate 2, see fig. 4, which shows a distribution of the four mark points 31 of the second plane plate 3. Then, the medical imaging device shoots the X-ray perspective image of the positioning scale, namely the medical imaging device generates the X-ray perspective image based on the two plane plates of the positioning scale and the mark point on each plane plate, and can extract the coordinate of each mark point in the X-ray perspective image, at this time, only the mark point in the X-ray perspective image can be identified, and 8 coordinates are extracted, but the corresponding relation between different mark points and coordinates is unknown. Referring to fig. 5, an X-ray fluoroscopic image of the positioning scale is shown. Then, one of the eight marker points may be selected as a reference marker point based on the coordinates of each marker point in the X-ray fluoroscopic image.

S202, determining that three collinear marker points are collinear with four points of the reference marker point from the seven marker points except the reference marker point, determining the sequence of the reference marker point and the three collinear marker points, and determining the sequence of four marker points except the reference marker point and the three collinear marker points.

Wherein, the collinear marker point refers to three marker points collinear with the four reference marker points.

In an embodiment, after the reference mark point is determined, three collinear mark points are determined to be collinear with the four reference mark points among the seven mark points except the reference mark point, the four mark points are determined as a first group of mark points, and the four mark points except the reference mark point and the three collinear mark points are determined as a second group of mark points. Then, the order of the two sets of the aforementioned marker points (i.e., one set is the reference marker point and the three collinear marker points, and the other set is four marker points other than the reference marker point and the three collinear marker points) can be determined, that is, the order of the reference marker point and the three collinear marker points in the first set of marker points and the order of the four marker points other than the reference marker point and the three collinear marker points in the second set of marker points can be determined.

S203, determining a first actual cross ratio of the reference mark point and the three collinear mark points and a second actual cross ratio of the four mark points except the reference mark point and the three collinear mark points.

Wherein the first actual cross ratio is a cross ratio calculated based on the reference mark point and the three collinear mark points.

The second actual intersection ratio refers to an intersection ratio calculated based on four marker points other than the reference marker point and the three collinear marker points.

The calculation formula for determining the reference cross ratio is as follows:

wherein R represents the cross ratio, A, B, C and D respectively represent four collinear mark points, and R (A, B, C and D) represents the cross ratio of the mark points A, B, C and D; AC represents the distance between the marker points A and C; BC represents the distance between landmark points B and C; AD represents the distance between landmark points a and D; BD represents the distance between marker points B and D.

In implementation, after three collinear landmark points that are collinear with the four fiducial landmark points are determined and the order of the fiducial landmark points and the three collinear landmark points is determined, a first actual cross-ratio may be calculated based on the fiducial landmark points and the three collinear landmark points; after determining the order of the four marker points other than the reference marker point and the three collinear marker points, the second actual cross ratio may be calculated based on the four marker points other than the reference marker point and the three collinear marker points.

And S204, determining the positions of the eight mark points in the X-ray perspective image on the positioning scale based on the reference cross ratio, the first actual cross ratio and the second actual cross ratio.

In an implementation, after the reference cross ratio, the first actual cross ratio, and the second actual cross ratio are calculated, the positions of eight marker points (i.e., the two sets of marker points, one set of the reference marker point and the three collinear marker points, and the other set of four marker points except the reference marker point and the three collinear marker points) on the positioning scale in the X-ray fluoroscopic image may be determined based on the reference cross ratio, the first actual cross ratio, and the second actual cross ratio.

According to the above technical scheme, the embodiment of the utility model provides a through the first actual odds with the community or the leadership ratio of the corresponding benchmark odds with the community or the leadership mark point of every plane board of confirming the location scale, X-ray perspective image benchmark mark point and three collineation mark point, and the second actual odds with the community or the leadership ratio of four mark points except benchmark mark point and three collineation mark point to confirm based on aforementioned benchmark odds with the community or the leadership ratio, first actual odds with the community or the leadership ratio of second eight mark points in the X-ray perspective image are in the position on the location scale. Therefore, on one hand, the angle of the positioning scale is not required to be adjusted, and the marker point can be positioned based on the X-ray perspective image shot at any angle, so that the time consumption for positioning can be effectively reduced, the positioning efficiency is improved, and the time consumption for operation can be effectively shortened; meanwhile, the positioning of the mark points is not influenced by the angle between the optical axis and the positioning scale, so that the positioning precision can be effectively improved. On the other hand, because X-ray imaging equipment field of vision is less usually, need gather the X-ray perspective image of two different angles usually during the marking point location, and the utility model provides a marking point location method can obtain required X-ray perspective image through once taking based on two flat panels of location scale to can reduce the X-ray perspective number of times among the operation process, effectively reduce the radiation, shorten operation time.

Further, on the basis of the above method embodiment, the process of selecting the reference mark point in step S201 may be as follows: and determining the X coordinate value/Y coordinate value in the coordinates of the eight mark points, selecting the maximum/small value in all the X coordinate value/Y coordinate values, and determining the mark point corresponding to the maximum/small value as a reference mark point.

In implementation, when selecting the reference mark point, first, the X-coordinate value or the Y-coordinate value of each of the eight mark points may be obtained. Then, a maximum value or a minimum value may be determined among all the aforementioned X-coordinate values or Y-coordinate values, and a marker point corresponding to the maximum value or the minimum value may be determined as a reference marker point. The reference mark point may be a mark point corresponding to any one of the X coordinate value maximum value, the X coordinate value minimum value, the Y coordinate value maximum value, and the Y coordinate value minimum value among the eight mark points.

Further, on the basis of the above method embodiment, the collinear mark point may be determined according to the cross product of the vectors, and accordingly, the partial processing of step S202 may be as follows: calculating vectors of the reference mark point and each mark point except the reference mark point to obtain seven vectors, and calculating cross products of any two vectors in the seven vectors; and calculating the modulus of each cross product, performing ascending arrangement on the moduli of all the cross products, and determining three mark points corresponding to the moduli of the first three cross products in the sequence as three collinear mark points which are collinear with the four points of the reference mark point.

In implementation, when three collinear landmark points collinear with the four reference landmark points are determined, vectors between the reference landmark points and the other seven landmark points may be calculated to obtain seven vectors. Then, the cross product of every two vectors in the aforementioned seven vectors can be calculated, resulting in 21 cross products. Thereafter, the modulus of each of the aforementioned 21 cross products may be calculated, and all the moduli of the cross products may be arranged in ascending order. Then, the modules of the first three cross products in the sequence can be selected, three mark points corresponding to the modules of the first three cross products are determined, and the three mark points are determined as three collinear mark points which are collinear with the four points of the reference mark point.

Further, on the basis of the above method embodiment, the sorting may be performed according to the distance of the mark point, and accordingly, the processing of step S202 may be as follows: determining the reference mark point and the three collinear mark points as a first group of mark points, and calculating the distance between any two mark points in the first group of mark points; determining the sequence of the reference marker point and the three collinear marker points based on the distance between any two marker points; determining four marker points except the reference marker point and the three collinear marker points as a second group of marker points, and calculating the distance between any two marker points in the second group of marker points; the order of the four marker points other than the reference marker point and the three collinear marker points is determined based on the distance of any two marker points.

In an implementation, the reference landmark and the three collinear landmark points may be determined as a first set of landmark points, and the distance between any two landmark points in the first set of landmark points may be calculated. Then, the order of the reference marker point and the three collinear marker points in the first set of marker points may be determined according to the distance between any two of the aforementioned marker points. Assuming that the maximum distance is AD and the minimum distance is CD, the landmark point A, C, D can be determined, and the other landmark point is B. Four marker points other than the reference marker point and the three collinear marker points may also be determined as the second set of marker points, and the distance between any two marker points in the second set of marker points may be calculated. Then, the order of the four marker points other than the reference marker point and the three collinear marker points, that is, the order of the four marker points in the second set of marker points, may be determined based on the previously calculated distances between any two marker points. The specific process of determining the order of the four marker points in the second set of marker points is the same as the process of determining the order of the four marker points in the first set of marker points, and is not described herein again.

Further, on the basis of the above-mentioned method embodiment, the process of determining the positions of the eight marker points on the positioning scale in the X-ray fluoroscopic image based on the reference cross ratio, the first actual cross ratio and the second actual cross ratio may be as follows: determining whether a first reference cross ratio identical to the first actual cross ratio exists in the reference cross ratios corresponding to the mark points on each plane plate of the positioning scale; if a first reference cross ratio which is the same as the first actual cross ratio exists, determining the positions of the reference mark point and the three collinear mark points as mark points corresponding to the first reference cross ratio; determining whether a second reference cross ratio except the first reference cross ratio is the same as a second actual cross ratio in the reference cross ratios corresponding to the mark points on each plane plate of the positioning scale; and if the second reference cross ratio is the same as the second actual cross ratio or not, determining the positions of the four mark points except the reference mark point and the three collinear mark points as mark points corresponding to the second reference cross ratio.

In order to make the method provided by the embodiment of the present invention clearer, the above method is now fully described, specifically: step 1, calculating the intersection ratio of the mark points on two non-intersecting planes of the positioning scale, namely the reference intersection ratio. And 2, processing the X-ray perspective image of the positioning scale, identifying coordinates of eight mark points (namely, the spherical centers) on the X-ray perspective image, and randomly identifying the mark points. And 3, selecting the point with the minimum (or the maximum, or one of the two X coordinates) of the Y coordinates (or one of the two X coordinates) in the eight mark points as a reference mark point. And 4, finding out the three collinear mark points from the seven mark points except the reference point to be collinear with the four points of the reference mark point, specifically, respectively calculating vectors formed by the reference mark point and the other seven mark points, calculating cross products between every two seven vectors to obtain 21 cross products, selecting three vectors with the minimum modulus of the cross products, and obtaining the collinear mark points which are collinear with the reference mark points by the collinear three mark points of the three groups of vectors and the four points of the reference mark point. And 5, dividing the identified eight mark points into two groups: the reference points and the three points collinear thereto are a first set, and the remaining four points are a second set. And 6, calculating the distance between every two of the four mark points in each group, and determining the sequence of the four mark points according to the distance, wherein if the two mark points with the largest distance are AD (ad) and the two mark points with the smallest distance are CD (cd), the mark points A, C and D (a, C and D) can be determined, and the rest mark point is B (b). Step 7, calculating the cross ratio of each group of points after sorting, namely determining a first actual cross ratio of the reference mark point and the three collinear mark points and a second actual cross ratio of the four mark points except the reference mark point and the three collinear mark points; and according to the unchanged cross ratio, determining that the two groups of points on the image respectively correspond to the 21 mark points and the 31 mark points on the positioning scale.

The calculation method of the cross ratio comprises the following steps: referring to fig. 6, the one-to-one correspondence transformation between two straight lines defined by the product of finite-order central projection is called one-dimensional projection transformation, a, B, C, D respectively represent four collinear mark points, a ', B ', C ', D ' respectively represent the corresponding points after projection transformation of the four collinear mark points a, B, C, D, L1 represents the straight line where a, B, C, D are located, and L2 represents the straight line where a ', B ', C ', D are located. For projective transformation, there is a basic invariant, called the cross-ratio invariant, denoted by R. For one-dimensional projective transformation, the expression of the cross ratio is:

wherein R represents the cross ratio, A, B, C and D respectively represent four collinear mark points, and R (A, B, C and D) represents the cross ratio of the mark points A, B, C and D; AC represents the distance between the marker points A and C; BC represents the distance between landmark points B and C; AD represents the distance between landmark points a and D; BD represents the distance between marker points B and D.

Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods described in the embodiments or some parts of the embodiments.

It should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (7)

1. A positioning scale is characterized by comprising a first flat panel, a second flat panel and a connecting panel; the first and second flat panels do not intersect; the first flat panel and the second flat panel are connected through the connecting panel;

the first flat panel, the second flat panel and the connecting panel are all transparent to X-rays; the first flat panel and the second flat panel are respectively provided with four mark points, and each mark point is an X-ray opaque component.

2. A positioning scale according to claim 1, wherein the connecting face plate, the first planar plate and the second planar plate are all the same thickness; the connecting panel is a plane plate or a curved plate.

3. The positioning scale according to claim 2, wherein a lower surface of the bottom surface of the connection panel is provided with a first connection interface for connecting a multi-degree-of-freedom grip device.

4. A positioning scale according to claim 1, wherein one side of the connection panel is provided with a second connection interface for connection to an optical tracking device.

5. A positioning scale according to claim 1, wherein each marker point is a hard X-ray opaque bead.

6. A positioning scale according to claim 5, wherein the four marker points provided on each of the planar plates are arranged at different pitches from any two of the four marker points.

7. A positioning scale according to claim 1, wherein the intersection ratio corresponding to the marker point provided on the first flat plate is different from the intersection ratio corresponding to the marker point provided on the second flat plate.

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