HUP0900597A2 - Image fusion controller as well as imaging system and method applying the same - Google Patents

Description

*0900597 .

Fusion control, and display system and method using the same

The invention relates to a fusion controller, a display system and a method using the same. The invention relates primarily, but not exclusively, to solutions for selectively fusing 2, 3 or 4 images.

Images generated by medical imaging equipment (usually 2D or 3D reconstructed images) are processed by medical evaluation software, one of the most common operations of which is image fusion. Medical images are usually displayed by reading out 2D slices in a given direction (axial, sagittal or coronal). When two images are taken from the same body part, but both contain important (complementary) information, it is advisable to fuse these images together. Technically, this means adding the two images with the appropriate weight, which is called fusion.

According to the known solutions, during the fusion, both images are given a real number between 0.0 and 1.0, the so-called a value, which can therefore take on any real value in the specified interval. If the a value is 0.0, the given image is invisible in the viewer, if the a value is 1.0, the given image is fully visible. The sum of the a values of the fused images is 1.0, so if for one image a = x where 0.0 <= x <= 1.0 then for the other image a = 1.0 - x.

By modifying the a value, the user performing the evaluation has the opportunity to study both images in a single viewer, fused together, in addition to different a value pairs, which significantly reduces the evaluation time and drastically increases the accuracy of the diagnosis. Such a state-of-the-art solution is shown in Figure 1, where a coronal CT image slice is displayed on the left, a coronal SPECT slice from the same body part is displayed in the middle, and the fusion of the two images with a values of 0.5 - 0.5 a is displayed on the right. The fusion of the two images with a value of 0.5 - 0.5 a is shown.

-2 corresponding sliders are located below the fusion image, where in this case the left section represents the SPECT value and the right section represents the CT value. The length of the slider is considered to be 1 unit.

Figures 2A and 2B show the fusion of Figure 1 for different a value pairs. In the fusion display of Figure 2A, the a values of the SPECT and CT images are 0.75 and 0.25, respectively, while in the fusion display of Figure 2B, the a values of the SPECT and CT images are 0.25 and 0.75, respectively. The slider corresponding to the fusion is located below the fusion in both images, where in this case the left section represents the SPECT a value and the right section represents the CT a value. The length of the slider is also considered to be 1 unit.

The values, or weighting, are modified using a well-known user controller (also known as: control), the slider, by positioning which different value pairs can be generated and thus the two images can be given different weights during fusion (addition).

The classic dual fusion above has been used for many years to study different images at once, although it is increasingly necessary to fuse 3 or even 4 images. However, since a slider can only handle 2 values at a time, it became necessary to develop new alternative controllers.

When creating the invention, I set myself the goal of creating a fusion control, a display system and a method using it, which is free from the limitations and disadvantages of the prior art solutions. My further goal was to create a fusion solution that allows for the efficient, ergonomic simultaneous display of more than two images. My further goal was to create a solution that allows for a simple, efficient selection of the number of images to be fused.

The set objective is achieved by the fusion controller according to claim 1, the display system according to claim 9 and the method according to claim 10. Preferred embodiments of the invention are defined in the subclaims.

-3Exemplary preferred embodiments of the invention are described hereinafter with reference to the drawings, where the

Figure 1 is a drawing showing the operation of a prior art fusion controller, Figures 2A and 2B are images of two types of fusions produced by the solution of Figure 1, Figures 3A and 3B are sketches illustrating a first area-based division method of triple and quadruple fusion controllers,

Figures 4A and 4B are schematics illustrating a second area-based division method for triple and quadruple fusion controllers, the

Figures 5A and 5B are schematics illustrating a third, area-based partitioning method for triple and quadruple fusion controllers, the

Figures 6A and 6B are schematics illustrating a fourth, segment length-based division method for triple and quadruple fusion controllers, the

Figures 7A and 7B are schematics illustrating a fifth, segment length-based division method for triple and quadruple fusion controllers, the

Figures 8A and 8B are schematics illustrating a sixth method of segment length-based division of triple and quadruple fusion controllers, the

Figure 9 is an enlarged view of an example of a triple fusion mode, and Figures 10A, 10B and 10C are schematic diagrams of three modes of a fusion controller according to the invention, allowing fusion display of a selectable number of images between 2 and 4.

In the case of triple fusion, images Α,/ ₂ ,Λ and their corresponding values «ι,« ₂ .α ₃ are given, so the fusion image is obtained with the formula T = /,*«,+/ ₂ *« ₂ +z ₃ *« ₃ , where ^α 1 ^+a 2 ^{+ a} 3 =1·θ .

In the case of four-way fusion, the images Λ,7 ₂ ,ζ ₃ ,ζ ₄ and the values «ι.οτ-ομ,αι belonging to them are given, so the fusion image is obtained by the formula f = i _x *a _t +ι ₂ *a ₂ +i ₃ *a ₃ +z ₄ *s ₄ , where «1 +«2 ^+a 3 ^+a 4 =10.

To modify these values simultaneously, a universal fusion controller has been designed according to the invention, which in one preferred embodiment can have three possible operating modes depending on whether it is a dual, triple or

-4 We have to handle quadruple fusion. As described in detail below, in the case of triple and quadruple fusion, six sub-modes are possible depending on what computational processes the user interactions trigger in the controller.

The fusion controller 10 according to the invention, shown in Figures 3A-10C, is designed for fusion display of images in a manner that is suitable for adjusting the weighting Oi_ ₄ of the images 10 in fusion display. The fusion controller according to the invention is also suitable for fusion display of more than two images 10, and includes

- two-dimensional 13 controller areas, and

- a marker positionable in the controller area 13, with position P suitable for setting the weighting α·|. ₄ in the fusion display of the images 10.

For the fusion control, it is preferably used in a computer display system and displayed on a computer display. By two-dimensional 13 controller area, we preferably mean that a specific area or shape on the display is the fusion controller workspace, on which the marker or cursor is positioned. According to the invention, a marker is any graphic solution that can be used to designate a position P in the controller area. The marker can be, for example, a crosshair that can be dragged with a mouse, or the intersection point of weighting adjustment sections.

According to the invention, in the case of fusion display of more than two images 10, the controller area 13 is preferably a plane shape with equal sides corresponding to the number of images 10 to be displayed in fusion. A particularly advantageous embodiment of the invention is therefore based on a two-dimensional geometric polygon, where the number of sides of the polygon is equal to the number of images to be fused, so in the case of quadruple fusion the basic geometric shape is a square, and in the case of triple fusion it is a triangle. In both cases, any position P can be designated within the shape with a marker, which position P can be located on the sides of the shape or at the vertices A, B, C, D, but cannot be outside it.

The relationship between a given polygon and the position P can be defined in several ways; based on this, we can distinguish between area-based and segment-length-based division.

-5In area-based division, we define sections starting from the marker P position, and use the sections to divide the area of the shape into sub-areas, where the area of the geometric polygon to be divided is considered to be 1 unit. Then the sum of the price areas is 1, so the condition regarding the sum of the a values is met, and the price areas each determine a value between 0.0 and 1.0.

In segment length-based division, we calculate the length of segments placed between the position P and the points defined according to the given rule of the geometric shape, where the sum of the segment lengths is considered to be 1 unit, so each segment length determines a value between 0.0 and 1.0.

In both cases, three subgroups can be defined depending on the relationship between the position P and the shape.

In area-based division, the weighting of the 10 images in Fig. ₄ can be set with the flood areas defined by the following sections:

- sections perpendicular to the sides from position P,

- segments drawn from position P to the vertices, or

- the segments of the lines drawn from the vertices through the position P, which are created by the intersections of the lines on the sides opposite the vertices and the connections of the position P.

In segment length-based division, the weighting of the 10 images can be set using the following segment lengths:

- sections perpendicular to the sides from position P,

- segments drawn from position P to the vertices, or

- the segments of the lines drawn from the vertices through the position P, which are created by the intersections of the lines on the sides opposite the vertices and the connections of the position P.

Figures 3A and 3B show a three- and four-way fusion controller area-based division method, where the price areas 13 are defined by sections 16 perpendicular to the sides from the position P.

-6A Figures 4A and 4B show an area-based partitioning method for a triple and quadruple fusion controller, where the flood areas 13 are defined by segments 16' drawn from the position P to the vertices.

Figures 5A and 5B show a three- and four-way fusion controller area-based partitioning method, where the flood areas 13 are defined by the 16 segments of lines drawn from the vertices through the P position, which are between the intersections of the line with the side opposite the vertex and the P position.

Figures 6A and 6B show a segment length-based division method for a triple and a quadruple fusion controller, where the segment lengths are given by the lengths of the segments 16 perpendicular to the sides from the position P.

Figures 7A and 7B show a segment length-based division method for a triple and a quadruple fusion controller, where the segment lengths are given by the lengths of the 16' segments drawn from the P position to the vertices.

Figures 8A and 8B show a segment length-based division method for a triple and a quadruple fusion controller, where the segment lengths are determined by the 16 segments of lines drawn from the vertices through the P position that are between the intersections of the line on the side opposite the vertex and the P position.

During operation, the universal controller is assigned to at least one display, which can contain, for example, 1, 2, 3 or 4 images. The user has the option to manage these images, i.e. delete an image from the fusion or add a new one.

As shown in Figure 9, the universal controller preferably displays the image identifier or identifiers (e.g., modality type, image name), the current value of the given image, and a toggle button 17 for each of the 10 images. The figure shows an example of a triple fusion mode, where the area-based division according to Figure 3A is the active mode. In the example, the last 10 images are switched off, so

-7 has a value of 0. The active values are generated by the current operating mode of the controller.

The 10 images in the fusion can be switched on and off using the 17 switches, which allows switching between two, three and four fusions as shown in Figures 10A, 10B and 10C. Whenever a 10 image is switched off, its corresponding value becomes 0, and a controller is displayed according to the number of switched on images, with which the values of the switched on images can be controlled. If an inactive 10 image is switched back on, the shape according to the number of switched on images 10 is displayed, and in this way the value of the switched on image can be modified again. In Figures 10A-C, the switched off switch buttons 17 are shown dimly.

Figures 10A-C show three exemplary modes of the universal fusion controller depending on the number of fusions. The controller supports unique identifiers of the 10 images in a given fusion, the current a values, and a switch button 17 for each image. Each mode is generated according to the number of images 10 that are enabled. These examples represent the area-based division according to Figures 4A, 4B, but any other mode can be selected. As shown in Figure 10C, the fusion controller according to the invention can also be used in a conventional dual fusion mode.

The six possible calculation modes for area and segment length-based division can be optionally modified, where the modification can be done e.g. from the drop-down list located close to the controller, from the list that appears when the right mouse button is pressed on the controller, or even from the menu of the given fusion program or from another controller. The variability of the six possible modes is extremely advantageous, since the calculation mode that is advantageous in a given case may vary depending on the structure of the program containing the controller and the nature of the 10 images.

To better illustrate a given fusion situation, the current values can be displayed at the sides or vertices of a given geometric shape, or the divided sub-areas of the shape can be separated with a different pattern or color.

-8 from each other. The indication of the given pattern or color at the 17 switch buttons further increases visual clarity and thus makes work faster.

The invention is of course not limited to the preferred embodiments described in detail above, but further changes, modifications and developments are also possible within the scope of protection defined by the claims.

Claims (10)

-9Patent claims 1. A fusion controller for the fusion display of images (10), which is suitable for adjusting the weighting (ai. ₄ ) of the images (10) in the fusion display, characterized in that it is also suitable for the fusion display of more than two images (10), and comprises - a two-dimensional controller area (13), and - a marker that can be positioned in the controller area (13), and whose position (P) is suitable for setting the weighting (ai. ₄ ) of the images (10) in the fusion display. 2. The controller according to claim 1, characterized in that in the case of fusion display of more than two images (10), the controller area (13) is an equilateral planar shape corresponding to the number of images (10) to be fusion displayed. 3. The control according to claim 2, characterized in that the shape is divided into sub-areas (15) by sections (16, 16', 16) starting from the marker position (P), and the weighting (Qi_ ₄ ) of the images (10) is determined by the area of the sub-areas (15). 4. The control according to claim 2, characterized in that the weighting (Oi. ₄ ) of the images (10) is determined by the length of the sections (16, 16', 16) starting from the marker position (P). 5. The control according to claim 2 or 3, characterized in that the sections starting from the marker position (P) - sections perpendicular to the sides of the shape (16), - segments drawn into the vertices of the shape (16'), or - the sections (16) between the marker position (P) and the side sections opposite the vertices on the lines drawn from the vertices of the shape through the marker position (P). 6. Controller according to any one of claims 3-5, characterized in that it comprises a means, preferably a menu, suitable for selecting the weighting (01.4) method. 7. A controller according to any one of claims 2-6, characterized in that it comprises means suitable for selecting the number of images (10) to be displayed in fusion, and thus the planar shape. 8. Controller according to claim 7, characterized in that the means suitable for selecting the number of images (10) to be displayed in fusion are switch buttons (17). 9. A display system for fusion display of images (10), characterized in that it comprises a fusion controller according to any one of claims 1-8. 10. A method for fusion display of images (10), in which the weighting (a^) of the images (10) in fusion display is enabled, characterized in that the fusion control according to any one of claims 1-8 is used for fusion display of more than two images (10). (9 sheets of drawings, 19 figures)