DE10004918A1 - Computer display arrangement for three-dimensional medical imaging techniques, such as computer tomography, has an arrangement that allows two limiting borders, e.g. of a section of interest to a doctor, to be moved as a pair - Google Patents

Abstract

A part of a two-dimensional computer depiction of volume elements (8) of a record set can be selected by entering limiting surfaces (13, 14). The two surfaces (13, 14) can be moved using either mouse and or keyboard. The surfaces can be coupled so that the surfaces can be moved as a pair using mouse or keyboard or if desired coupling between the two can be deleted.

Description

The present invention relates to a device for displaying a volume data set with a large number of volume data elements as a two-dimensional image, with at least one data memory for storing the volume data set, a computing unit for determining the two-dimensional image from the volume data elements of the volume data set, a display unit, e.g. . B. a monitor, at least for displaying the two-dimensional image and at least one input device, z. B. a keyboard and / or a mouse control,

• - With each volume data item a position in the volume and a data value is assigned,
• - The computing unit via the input device Base interface can be specified, on the basis of which the volume data set into a basic selection data set and a reference of the volume data set complementary basic residual data sentence is divided,
• - The computing unit via the input device Additional interface can be specified, on the basis of which the reason selection data record into an additional selection data record and one complementary to the basic selection data set record remaining record is split,
• - whereby only Volu to determine the two-dimensional image Data elements are used in the additional selection record are included.

Such display devices are generally known. They are used mainly for medical purposes development of tomograms or other three-dimensional reconstruction structures of patient images, e.g. B. in the X-ray angi ographie, used. It can be done by appropriate the basic interface and the additional interface in a simple manner  A particularly relevant area of the Volumenda select sentence.

The object of the present invention is the Se lesson of areas of interest even easier to design ten.

The object is achieved in that the basic interface and the additional interface are coupled to one another in such a way that if a shift of one of the interfaces over the Input device the other of the interfaces from the right Chen unit automatically shifted accordingly becomes.

The coupling of the interfaces to one another can be rigid. However, the coupling of the interfaces is preferred Interactive input of a control command via the input direction can be triggered or canceled.

If the two-dimensional image is a perspective representation development of the volume data elements of the additional selection data record and the interfaces from the display unit together with the displayed two-dimensional image can be displayed immediately see which area was selected.

The shift can be a rotation or a shift his.

If the position of the volume data items three coordinates a Cartesian coordinate system with three coordinates includes axes, the interfaces are shifted in usually parallel to one of the coordinate axes.

In principle, the interfaces can be arbitrary, even curved te, areas. As a rule, however, they are levels.  

The planes can form an angle with each other. Usually, however, they run parallel to each other. In particular a thin area can be created using parallel planes say a slice to select the volume data set.

In principle, the levels can be oriented anywhere in the room his. But preferably they run perpendicular to one of the Coordinate axes.

Further advantages and details emerge from the following description of an embodiment. Here zei in principle

Fig. 1 shows a display device,

Figure is a perspective two-dimensional image of a volume data set and. 2

Fig. 3 in a highly simplified form a flow chart.

Referring to FIG. 1, a display device to a data storage medium 1 and a memory 2, the unit area with a Re 3 are connected. A display unit 4 , a mass storage device 5 and input devices 6 , 7 are also connected to the computing unit 3 .

A volume data record is stored in data memory 1 . This has a large number of volume data elements 8 . Each volume data element 8 is assigned three coordinates x, y, z of a Cartesian coordinate system and a data value d. The coordinates x, y and z each volume element 8 is thus assigned a position (x, y, z) in the volume. For the sake of clarity, some of the volume data elements 8 are also shown in FIG. 2.

In the working memory 2 , an operating system for the computing unit 3 , application programs for the computing unit 3 and other data are stored, for. B. also image data for the display unit 4 .

The display unit 4 is usually a monitor. A two-dimensional image can be displayed on the display unit 4 . The mass storage 5 is usually formed as a hard drive. The input devices 6 , 7 generally comprise a keyboard 6 and a mouse control 7 . Control commands entered via the input devices 6 , 7 are queried by the computing unit 3 and processed in accordance with the application program currently running.

The volume data record can be represented as a two-dimensional image on the display unit 4 by means of the application program. The image data corresponding to this are determined by the computing unit 3 from the volume data elements 8 of the volume data set. The determined image data, which in their entirety result in the two-dimensional image, are then displayed on the display unit 4 .

Referring to FIG. 1, the display unit 4 has an image area 9 which is in turn divided into three sections 10-12. The subarea 10 serves for the actual representation of the two-dimensional image. A subdivision 11 shows a frequency distribution of the occurring data values d. The section 12 serves as a control panel.

The two-dimensional image shown in the sub-area 10 is usually a perspective view of the Volumenda tenelemente 8 , ie a parallel or perspective pro jection. Such an illustration is shown by way of example in FIG. 2. In practice, the volume data sets are often self-documenting. They represent, for example, a body part of a human or an animal. The coordinate axes of the Cartesian coordinate system shown in FIG. 2 are therefore usually not shown in practice.

A basic interface 13 and an additional interface 14 can be given to the computing unit 3 via the input devices 6 , 7 . Referring to FIG. 2, the boundary surfaces 13, 14 extending in parallel planes perpendicular to one of dinatenachsen coor are x, y, z, where y is the coordinate axis, duri fen. In principle, however, a different orientation would also be used, e.g. B. perpendicular to a surface diagonal or perpendicular to the space diagonal. The interfaces 13 , 14 are, as can be seen from FIG. 2, also displayed by the display unit 4 together with the two-dimensional image shown.

As can be seen from FIG. 2, the volume data record is divided into a basic selection data record 15 and a basic residual data record 16 on the basis of the basic interface 13 . The basic selection data set 15 comprises all volume data elements 8 of the volume data set which lie in the basic interface 13 or to the right thereof. The basic residual data record 16 comprises all other volume data elements 8 of the volume data record.

On the basis of the additional interface 14 , the basic selection data record 15 is divided into an additional selection data record 17 and an additional residual data record 18 . The additional selection data set 17 comprises all volume data elements 8 of the basic selection data set 15 , which are in the additional interface 14 and to the left thereof. The additional residual data set 18 includes all other volume data elements 8 of the basic selection data set 15 .

To determine the two-dimensional image, which is shown in the partial area 10 , only volume data elements 8 are used which are contained in the additional selection data record 17, that is to say between the two interfaces 13 , 14 .

Because of their effect, namely the cutting off of non-interested parts of the volume data set, the boundary surfaces 13 , 14 are often also referred to as clip planes. The specification of the clip planes and their - mostly interactive - relocation is common and well known. It is even known to specify not only two clip planes in total, but two clip planes per coordinate axis. This means that any cuboid can be extracted from the volume data record and displayed. By way of example, this is indicated in FIG. 2 by two wide boundary surfaces 19 , 20 , by means of which the volume to be represented can be further delimited.

The interfaces 13 , 14 , 19 , 20 can be individually moved interactively, as indicated by double arrows AD. According to the invention, however, it is also possible to couple at least the basic interface 13 and the additional interface 14 , if appropriate also the further interfaces 19 , 20 . In this case, z. B. the basic interface 13 via the input devices 6 , 7 also the other interfaces 14 , 19 , 20 , but at least the additional interface 14 , automatically shifted from the computing unit 3 here with corresponding. This is indicated in Fig. 2 by a curly bracket and a double arrow E. In this case, a layer of the same thickness is always selected.

As a rule, the relocation is a postponement. she can done in any direction, is not a Ver limited parallel to one of the coordinate axes. Possibly. each shift can result from a maximum of three in succession partial shifts are composed, of which each is parallel to another of the coordinate axes.

The shift can also be a rotation. This can e.g. B. around the center M of the respective interface 13 , 14 , 19 or 20 , which is indicated in Fig. 2 for the basic interface 13 by the rotation arrow R.

A coupling of all interfaces 13 , 14 , 19 , 20 is particularly useful if a rotation is carried out or the effective total displacement is not parallel to any of the interfaces 13 , 14 , 19 , 20 .

The coupling of the interfaces 13 , 14 , 19 , 20 to one another can be rigid. However, it can preferably be triggered or canceled by interactive input of a control command via the input devices 6 , 7 .

The flowchart shown in FIG. 3 is limited to the displacement of the basic interface 13 and the additional interface 14 . However, it is apparent to any person skilled in the art that the procedure can be easily extended to the further interfaces 19 , 20 .

FIG. 3 is first determined and displayed on the display unit 4 in a step 21 from the Volu mendatenelementen 8 of the volume data set a zweidimensio dimensional image. The positions of the interfaces 13 , 14 are then queried in steps 22 and 23 . In a step 24, a query is then made as to whether the interfaces 13 , 14 should be coupled to one another. Depending on the input, a flag F is then set in a step 25 or reset in a step 26 .

If, for example, a shift of the basic interface 13 is entered in a step 27 , the arithmetic unit 3 queries the value of the flag F in a step 28 . Depending on the value of the flag F, a step 29 or a step 30 is carried out. In step 29 , along with the basic boundary surface 13 , the additional boundary surface 14 is simultaneously shifted in a corresponding manner. At the same time, the two-dimensional image is determined, which results from the then selected volume elements 8 . Otherwise, only the basic interface 13 to be moved is moved, but the additional interface 14 is not. Again, the image to be displayed is immediately redetermined.

If the user selects a corresponding option WUR de may further after the completion of displacing the base surface 13 and the interfaces 13, 14 are rotated, the image to be detected in a step 31st

Reference list

1

,

2

,

5

Storage

3rd

Arithmetic unit

4

Display unit

6

,

7

Input devices

8th

Volume data items

9

Image area

10-12

Sub-areas

13

,

14

,

19th

,

20th

Interfaces

15-18

Records

21-31

steps
AE double arrows
d data value
F flag
M center
R rotation arrow
x, y, z coordinates

Claims (8)

1. Display device for displaying a volume data set with a plurality of volume data elements ( 8 ) as a two-dimensional image, with at least one data memory ( 1 ) for storing the volume data set, a computing unit ( 3 ) for determining the two-dimensional image from the volume data elements ( 8 ) the volume data set, a display unit ( 4 ), z. B. a monitor ( 4 ), at least for displaying the two-dimensional image and at least one input device ( 6 , 7 ), for. B. a keyboard ( 6 ) and / or a mouse control ( 7 ),

• - Each volume data element ( 8 ) is assigned a position (x, y, z) in the volume and a data value (d),
• - wherein the computing unit ( 3 ) can be given a basic interface ( 13 ) via the input device ( 6 , 7 ), on the basis of which the volume data record is divided into a basic selection data record ( 15 ) and a basic residual data record ( 16 ) complementary to the volume data record,
• - The computing unit ( 3 ) can be given an additional interface ( 14 ) via the input device ( 6 , 7 ), on the basis of which the basic selection data record ( 15 ) is converted into an additional selection data record ( 17 ) and an additional residual data record complementary to the basic selection data record ( 15 ). 18 ) is divided,
• - Only volume data elements ( 8 ) that are contained in the additional selection data record ( 17 ) are used to determine the two-dimensional image,

characterized in that the basic boundary surface ( 13 ) and the additional boundary surface ( 14 ) are coupled to one another in such a way that when a displacement of one of the boundary surfaces ( 13 , 14 ) is specified via the input device ( 6 , 7 ) the other of the boundary surfaces ( 13 , 14 ) is automatically shifted accordingly by the computing unit ( 3 ). 2. Display device according to claim 1, characterized in that the coupling of the interfaces ( 13 , 14 ) by interactively entering a control command via the input device ( 6 , 7 ) can be triggered or canceled. 3. Display device according to claim 1 or 2, characterized in that the two-dimensional image is a perspective representation of the volume data elements ( 8 ) of the additional selection data set ( 17 ) and that the interfaces ( 13 , 14 ) of the display unit ( 4 ) together with the shown two-dimensional image can be displayed. 4. Display device according to claim 1, 2 or 3, characterized, that the shift is a shift or a rotation is. 5. Display device according to claim 4, characterized in that the position (x, y, z) of the volume data elements ( 8 ) comprises three coordinates (x, y, z) of a Cartesian coordinate system with three coordinate axes and that the displacement of the interfaces ( 13 , 14 ) takes place parallel to one of the coordinate axes. 6. Display device according to one of the above claims, characterized in that the basic interface ( 13 ) and the additional interface ( 14 ) are planes. 7. Display device according to claim 6, characterized in that the planes ( 13 , 14 ) run parallel to one another. 8. Display device according to claim 6 or 7, characterized in that the position (x, y, z) of the volume data elements ( 8 ) comprises three coordinates (x, y, z) of a Cartesian coordinate system with three coordinate axes and that the planes ( 13th , 14 ) run perpendicular to each of the coordinate axes.