WO2015124203A1 - Processing of a volume data set, wherein application rules are automatically associated - Google Patents

Abstract

The invention relates to the processing of a volume data set, wherein application rules are automatically associated. A computer (1) associates an object type (T) with objects (7) segmented in volume data set (6), either automatically or with the support of a user (5). The computer (1) associates an application rule (A, Aj) with the particular segmented object (7) and outputs at least the segmented objects (7) to the user (5) in the form of an image (B) by means of a display device (8). In the process of the output of the volume data set (6), the computer (1) processes the segmented objects (7) in accordance with the application rules (A, Aj) associated with the objects (7). Before the application rules (A, Aj) are associated with the segmented objects (7), the computer (1) receives a selection command (C2) from the user (5) and selects a group rule (Gi) on the basis of the selection command (C2). The group rules (Gi) each contain a plurality of application rules (Aj) to be applied to objects (7) of a particular object type (T). The computer (1) automatically determines, for objects (7) segmented in the volume data set (6), the corresponding application rule (Aj) contained the selected group rule (Gi) in accordance with the object type (T) associated with the particular segmented object (7) and associates said application rule with the particular objects (7).

Description

description

Processing a volume data set with automated to ^¬ order of application rules

The present invention relates to a processing method for a volume data set by a computer,

 in which the computer in the volume data record assigns a respective object type to segmented objects automatically or with the assistance of a user,

 wherein the computer assigns an application instruction to the respective segmented object,

 wherein the computer outputs at least the segmented objects of the volume data record to the user in the form of an image via a viewing device,

 - In the context of the output of the volume data set to the user, the computer processes the objects segmented in the volume data record in accordance with the application instructions assigned to the objects.

The present invention further relates to a Computerpro ^¬ program comprising machine code that is processable by a computer, wherein the execution of the machine code effected by the computer that the computer executes processing methods such machining.

The present invention further relates to a computer, wherein the computer is programmed with such a computer program, so that the computer receives a call command in operation and executes derar ^¬ tiges processing method due to the call command.

In the medical image processing of volume data (ie three-dimensional data), the segmentation of body regions or anatomical structures represents an essential processing step. Segmentation hereby means the identification and detachment of the corresponding body regions and anatomical structures from their surroundings. The Segments mentation serves in particular for better visualization, orientation, measurement, navigation (in volume), comparability of results and the like. In the context of the evaluation, it is often necessary to prepare the segmentation specifically for the intended application. This step is often very complex and often consists of often repetitive processes.

In the prior art, the preparation often takes place in such a way that the computer first of all outputs the volume data record - possibly already partly processed - to the user via the viewing device. The user selects a portion of the volume data set (for example, by setting a seed point ^¬), gives the computer an object type before and abuts a segmentation. The computer then segments an object and assigns the specified object type to the segmented object. The computer assigns - automatically or according to a specification by the user - the segmented object to one of many predefined application rules. The predefined application requirements often comprise respective display parameters affecting the nature of depicting ^¬ lung of objects of each object type in the picture. The computer takes into account the respective display parameters when determining the mapping of the objects of the respective object type. Furthermore, the user can call up a menu in which the computer offers the user a variety of predefined application instructions for selection. The user selects one of the predefi ^¬ ned application rules in this case. The computer assigns DA raufhin the selected object, the selected application ^¬ regulations to. Alternatively, the user may modify the application ^¬ regulations. This process is repeated for different objects to be segmented. The procedure of the prior art is cumbersome and time consuming. Further, it is - in particular in order ^¬ sive volume data sets in which the assignment of a particular application protocol for a plurality of Obwalden projects must be carried out, also error prone. This applies in particular if a comparison of a plurality of similar volume data sets (for example volume data sets of ^different persons, in which the same evaluation is to be carried out in each case, or volume data records of the same

Person identified by different modalities and / or recorded at different times). The object of the present invention is to provide opportunities to simplify and standardize the evaluation of volume data sets.

The object is achieved by a processing method having the features of claim 1. Advantageous ^Ausgestaltun conditions of the machining process are the subject of dependent claims 2 to 8.

According to the invention, a machining method of the type mentioned at the outset is configured by

 the computer receives a selection command from the user before assigning the application rules to the segmented objects, and selects one of a plurality of group rules based on the selection command,

- that the group rules each contain a plurality of applicable to objects of a respective object type Applika tion ^¬ tion and

- that the computer automatically segmented in the volume data set according to the objects associated with the respective segmented object object type determines the corresponding Applika ^¬ tion rule contained in the selected group rule and allocates the respective objects to ^¬. As a result, it is possible for the user merely to specify to the computer by the selection command what type of evaluation he would like to make, and the computer then automatically selects the corresponding group rule and the Assigns application instructions contained in the selected group rule according to the object types to the respective segmented objects of the volume data set. The selection commands can have up as "speaking names", like longer be called so for example, as colon cancer, mammography screening and ^¬.

It is possible that the segmentation of the objects is carried out in advance or otherwise outside the machining process. In a preferred embodiment of the present invention, however, the computer accepts from the user the first selection command counter and selected on the basis of Auswahlbe ^¬ fehls the corresponding group provision. Due to the se ^¬ lected group provision the computer knows which objects should be present in the volume data set. The computer can automatically menting for the ent ^¬ preserved in the selected group provision object types in the volume data set or with the support by the user the associated objects segmental therefore, starting from the selected group rule. As a result, in many cases almost the entire preparation of the volume data set can be automated.

In a particularly preferred embodiment, the computer checks whether at least one object is segmented in each case for all object types contained in the selected group instruction in the volume data record. In this case, the computer will give a message to the user if this is not the case. This allows the computer to alert the user to deviations from the standard case, according to which - according to the selected group rule - all corresponding objects should be present in the volume data set. It can - depending on the individual case - be sensible to cancel more Bear ^¬ processing the volume data set, if not jekttypen for all included in the selected group provision Obwalden in the volume data set at least one object is segmented. Alternatively, it may be useful to make the Mel ^¬ dung only as a warning, so that the loading Although the user is made aware of the deviation from the normal case, this can be ignored if necessary.

The application instructions often include display parameters. Display parameters are often very complex. They assign each gray value in the three-dimensional volume of a certain color, transparency, contrast, lighting, sharpness and the like. Generally speaking, the presentation parameters affect the way in which objects of the corresponding object type are displayed in the image output to the user. The representation of parameters define mostly curves (ramps, trapezoids, freehand definition, and others), due to which then a respective gray scale value of each ^¬ weiligen object ness a respective color, transparency, brightness, etc. is assigned. In this case, the computer takes into account the corresponding representation ^parameters when determining the mapping of the objects of the corresponding object type. This general statement also applies, of course, to the application instructions of the selected group instructions. In particular, usually a first application rules includes corresponding first Darstellungspa ^¬ parameters. Often, a second application instruction of the selected group instruction also includes such second presentation parameters. Additionally, it is - and this is in contrast to prior art - as part of the editing process of the invention, however, possible that the selected group provision contains a supplemental prescription for these two types of objects, including which third depicting ^¬ development parameters. The third representation parameters may in this case be determined independently of the first and second representation parameters. In such a case, the third representation parameters influence the way in which the objects of the first and second object types are displayed in the image, provided that the objects of the first and second object types are in the same location in the image or in the volume data set. This is in contrast _r

to the prior art possible that the computer for the objects of the first and the second object type in the Be ^¬ rich, in which the objects of the first and the second object type are in the figure or in the volume data set in the same place automatically instead of the first and the second display parameter uses the third display parameters.

Two objects can be in the same location in the image, even though they are in different locations in the three-dimensional volume, but the image is a two-dimensional image. Two objects can occupy the same place in three ^¬ dimensional volume, such as when multiple volume data sets are superimposed. Such an overlay may be useful, in particular, if the volume data records show the same examination object from the point of view, but a temporal development of the examination subject has taken place. The zeitli ^¬ che development, for example, a rapid development over time his (entry and washing out a means of contrast ^mediums) or a slow time evolution (beispielswei ^¬ se a development of a tumor). It can also happen that certain volume ranges are assigned to multiple objects. For example, on the one hand a tumor can be segmented as a separate object "tumor", on the other hand it can also be segmented as part of the organ surrounding the tumor, for example the liver or the brain.

As an alternative or in addition to the display parameters, the application instructions may each comprise an evaluation specification. En this case, the computer determined based on the respective evaluation rule for the objects of ent ^¬ speaking object type individually or together, a numerical value, and outputs the numerical value on the display device to the user. This general statement also applies, of course, to the application instructions of the selected group instructions. In a further preferred refinement of the machining method, the computer selects at least one object type from the user before specifying the selection ^command and offers the user those group prescriptions for selection which contain an application specification for the objects of the selected object types.

By doing so, the choice of group rules can be limited from the outset to those group rules which are relevant to the user in the present case.

It is possible that the group rules are predefined for the computer as part of its programming. Preferably, however, it is possible for the computer to receive creation commands from the user and to create, modify, extend and / or switch between an activated and a deactivated state on the basis of the creation commands. This allows the user to create, modify and activate / deactivate group rules himself, as required. A (final) deletion is not necessarily excluded. In some cases, however, the user is not allowed to delete group rules. The object is further achieved by a computer program according to claim 9. According to the invention, the execution of the machine code by the computer causes the computer to execute a processing method according to the invention. The object is further achieved by a computer according to claim 10. According to the invention the computer with a modern computer program OF INVENTION ^¬ dung is programmed so that the computer executes an inventive machining ^¬ processing methods due to the call instruction.

The above-described characteristics, features and advantages of this invention, as well as the manner in which they are achieved, become clearer and more clearly understandable in the context of the invention. With reference to the following description of the exemplary embodiments, which are explained in more detail in conjunction with the drawings. 1 shows a computer, FIG.

 2 shows a flow chart,

 3 shows a group rule,

 4 shows an application specification,

 5 shows a flow chart,

FIG. 6 objects and application instructions,

 7 shows a flowchart and

 8 shows a further flowchart.

According to FIG. 1, a computer 1 is programmed with a computer program 2. The computer program 2 can be supplied to the computer 1, for example via a data carrier 3, on which the computer program 2 is stored in machine-readable form - for example in electronic form. The computer program 2 comprises machine code 4, which can be processed by the computer 1. For processing the machine code 4, the computer 1 receives from a user 5 a call command Cl. Due to the call command Cl, the computer ^¬ program 2 is called and thus the processing of the machine code 4 is started. The processing of the machine code 4 by the computer 1 causes the computer 1 to carry out an operating method, which will be explained in more detail below.

As part of the processing of the machine code 4, the computer 1 according to FIG. 2 is known, among other things, for a volume data set 6 in a step S1. The volume data set 6 is a three-dimensionally spatially resolved image of a real structural ^¬ structure, for example a patient. In volume data set 6 1 Whether various projects ^¬ can be segmented 7 as shown in FIG. The objects 7 may, for example, be organs (heart, lungs, liver, kidneys, etc.), blood vessels or a blood vessel system, bones, etc. The volume data record 6 can be generated by means of a corresponding imaging medical technology modality (for example, a a CT system, a C-arm system, an MR scanner, etc.).

In a step S2, the computer 1 assigns a respective object type T to segmented objects 7. For example, the object type T may specify whether the respective segmented object 7 is the heart, the lung, a blood vessel, a bone, and so forth. It is possible for the computer 1 to make the assignment of the respective object type T automatically. For example, the computer can one typical forms he know ^¬ and assign the object type T due to the forms. Alternatively, the user 5 in the computer 1 make a respective default. For example, the computer 1 can sequentially offer the individual objects 7 to the user 5, possibly making a suggestion for the object type T to be assigned, and accept the corresponding reaction of the user 5.

In a step S3, the computer 1 receives from the user 5 a selection command C2. On the basis of the selection command C2 se ^¬ read the computer 1 one of several group rules Gi (i = 1, 2, ...). The group regulations Gi contain - see FIG. 3 - in each case a plurality of application instructions Aj (j = 1, 2,...). Each application instruction Aj is to be applied to objects 7 of a respective object type T. The content of the application instructions Aj will be discussed later.

According to FIG 2, the computer 1 selects, in a step S4 egg nes of the segmented objects 7. In a step S5, the computer 1 ermit ^¬ telt the object type T, is associated with the selected segmented object. 7 In a step S6, the computer 1 checks whether the selected group rule Gi for this object type T contains an application rule Aj. If this is the case, the computer 1 arranges, in a step S7 this application rule Aj to the selected segmen ^¬ formatted object. 7 Otherwise, the computer 1 proceeds to a step S8. In step S8, another reaction is guided. For example, the user 5 can request an assignment of an application rule A or the ent ^¬ speaking object 7, a predetermined application rule A can be assigned. The application instruction A can (but not must) be contained in the selected group instruction Gi. It is also possible to associate no corresponding application rule with the corresponding segmented object 7.

In a step S9, the computer 1 checks whether it has the steps S4 to S8 for all objects already segmented 7 Runaway ^¬ leads. If this is not the case, the computer 1 returns to step S4. Otherwise, the computer 1 goes to egg ^¬ nem step S10 on. The steps S4 to S9 correspond to a possible implementation of the facts that the computer 1 automatically segmented in the volume data set objects 6 7 determines each kor ^¬ respondierende application instructions Aj and assigns the respective objects. 7 The implementation according to the steps S4 to S9 additionally takes into account that not necessarily all segmented objects 7 have an object type T for which an application rule Aj is found in the selected group rule Gi. In step S10, the computer 1 determines an image B. The image B can be, for example, a sectional representation or a perspective projection of the volume data set 6 or of a part of the volume data set 6. In particular, ent ^¬ the image B keeps at least the segmented objects 7 of the volume data set 6. The figure B is the computer 1 in a step S on a visual display unit 8 to the user 5 on. As part of the output of the volume data set 6 (or the segmented objects 7 of the volume data set 6) to a treatment ^¬ user 5 processes the computer 1, the segmented objects 7 in accordance with their associated rules application Aj. According to the illustration in FIGS. 3 and 4, the application instructions Aj can include, for example, display ^parameters D. The display parameters D influence the type of representation of objects 7 of the object type T of the respective application rule Aj in the figure B. In this case, the computer 1 takes into account the corresponding display parameters D when determining the image B of the objects 7 of the corresponding object type T. The display parameters D of the respective application Aj rule can specify the gray value of the Whether ^¬ jekts the manner in which shown in the picture B 7 g, for example, as shown in FIG 4 for the corresponding object. 7 In the case of a color image, for example, three primary colors can be defined in a uniform or different manner. In the case of a representation in gray levels, such a representation parameter can be defined.

Alternatively or additionally, the application instructions Aj may include a respective evaluation rule E as shown in FIG. In this case calculates the computer 1 based on the respective evaluation rule E for the objects 7 of the corresponding object type T individually or together (if specified by the object type T kidneys, for example, for both kidneys together) a numerical value Z and gives the numerical value Z on the screen 8 to the user 5 off. For example, the total number of voxels of the volume data set 6 assigned to the respective object 7 or the respective group of objects 7 can be determined as the numerical value Z. This number makes it possible to ^infer the size of the respective object 7 or the respective group of objects 7. However, other evaluations are also possible. The basic principle of the present invention can be configured in various ways. For example, FIG. 5 shows a modification of FIG. 2. According to FIG. 5, the computer 1 takes the selection command C2 from the user 5 in a step S21 opposite. In a step S22, the computer 1 selects the corresponding Gruppenvor ^¬ script Gi on the basis of the selection command C2. The steps S21 and S22 correspond content ^¬ Lich to step S3 of Fig. 2

Only then, ie after the selection of the group rule Gi, are further steps S23 to S28 carried out. in the

Step S23, the computer 1 selects one of the object types T, for which a respective application instruction Aj is contained in the selected group instruction Gi. In step S24, the computer 1 in the volume data set 6 segments the associated objects 7, that is to say those objects 7 to which the im

Step S23 is to be assigned to selected object type T. It is possible that the step S24 the computer 1 is executed automatically, so that the computer 1 determines the zugehöri ^¬ gen objects 7 itself. For example, the computational ^¬ ner 1 can automatic ^¬ table set a seed point to plausible parts of the volume data set 6 and start from the respective set seed point segmentation. The computer 1 can also determine the objects 7 on the basis of a threshold value recognition, an edge recognition or a more complex shape recognition. Alternatively, it is possible that the respective seed point is set by the user 5. In this case, the segmentation is carried out with the assistance of the user 5. In a step S25, the computer 1 assigns the now segmented objects 7 the respective application instruction Aj.

Optionally, steps S26 and S27 may be present. When the steps S26 and S27 are present, the computer 1 checks in step S26 whether it could be segmented at least one object 7 for the selected at step S23 whether ^¬ jekttyp T. If this is not the case, the computer 1 outputs a corresponding message to the user 5 in step S27. Otherwise, step S27 is skipped.

In a step S28, the computer 1 checks whether it S23 to S25, the pre ^¬ hens, the steps (or S27) for already al le object types T has performed. If this is not the case, the computer 1 returns to step S23. Otherwise, the computer 1 continues the machining process with step S10.

The steps S26 and S27 can also be implemented in the approach according to FIG. In this case, for example, steps S26 and S27 may be interposed between steps S9 and S10. The step S26 is slightly modified in this case in that the

Computer 1 does not check whether he (or more precisely himself) has in each case at least one object 7 seg ^¬ mented for all object types included in the selected group provision Gi T in the volume data set 6 (activity). Rather, the computer 1 checks in this case, whether - by the computer 1 or otherwise - for all contained in the selected group rule Gi object types T in the volume data set 6 at least one object 7 is segmented (state). In this case, all that ^matters is that the corresponding objects 7 are present. On the other hand, it is not necessary for the segmentation to be performed by the computer 1. Generally speaking, the group rules Gi similar to a macro can thus cause additional complex preprocessing of the volume data set 6.

As already mentioned, the application instructions Aj can include display parameters D. As a rule, several of the application instructions Aj of the selected group rule Gi include such display parameters D. It can now happen that two objects 7 of different object types T are located in the image B or in the volume data set 6 at the same location. For example, the following cases are possible:

Although the two objects 7 are located at different locations in the volume data set 6, if the image B is only two-dimensional, they are shown in the image B in the same location in the image B. - There are two volume records 6 superimposed

 (Superposition), so that two objects 7, namely one object 7 each of the one and the other volume data set 6, are in the same location in the volume.

- A first and a second object 7 of the same volume data 6 penetrate each other. This case can occur, for example, when a tumor is segmented within an organ (beispielswei ^¬ se of the brain or the liver). The organ and the tumor may be respective objects 7 in this case. The volume of the tumor may be ^¬ classifies to its segmentation as a tumor as part of the organ is in addition.

Schematically, the case is that two objects 7 of different object types T are located in the image B or in the volume data set 6 at the same location, shown in FIG. In such a case, the first object 7, a first Applika ^¬ tion prescribed Aj be associated with the second object 7, a second application rule Aj. The two Applikationsvor ^¬ writing Aj are designated in Figure 6 with Al and A2. The two application instructions Aj may include respective first and second display parameters D, respectively. As far as a certain part of the first object 7 is located in the image B at a different location than a part of the second object 7, the respective parts of the two objects 7 are processed according to the representation in FIG 6 according to their respective application rule Aj. In particular, the illustration in FIG. B takes place taking account of the presentation parameters D of the respective application specification Aj. In that regard, FIG 6 shows nothing new.

In the event that a certain part of the first object 7 is in the same location in the image B as a part of the second object 7, the basic principle of the present invention - alternatively or additionally to the embodiment according to FIG 5 - continue to be designed as follows : As shown in FIG 6, the selected group provision Gi contains too ^¬ addition to those rules application Aj for the object types T of the objects 7 is a supplemental prescription A '. The comple ^¬ wetting requirement A 'is in its approach a Applikationsvor- writing A. In particular, includes the supplemental prescription A' also display parameters D. The presentation parameter D of the supplemental prescription A 'may be individually defined. If there is a corresponding request of the user 5, they can match the display parameters D of one of the two application instructions Aj for the two objects 7. As a result, it can be determined, for example, that in the case of a corresponding overlap in the overlapping area, one object 7 is displayed and the other object 7 is suppressed. However, you can also deviate from the display parameters D of the two application instructions Aj. It is crucial that the computer 1 for denje ^¬ Nigen part of an object 7 which is located in the picture B or in the volume data set 6 in the same place as the other object 7 (or a part of the other object 7) in the determination of the Figure B uses the display parameters D of the supplemental rule A ', ie neither the Dar ^¬ position parameters D of one nor the display parameters D of the other application rule Aj. The corresponding procedures can also be extended to more than two objects 7.

The machining method according to the invention can also be configured as an alternative or in addition to one of the embodiments of FIGS. 5 and 6 according to FIG.

FIG. 7 shows a possible embodiment of the step S3 of FIG. 2 or of the steps S21 and S22 of FIG. 5. FIG. 7 contains steps S31 to S34. In step S31, the computer 1 receives an object type T from the user 5. If appropriate, step S31 can be executed repeatedly or, in step S31, the computer 1 can be given a plurality of object types T. In step S32, the computer 1 determines those group specifications Gi, which determines the one specified in step S31. NEN object type T (or conditions given in step S31, object types ^¬ T) included. In step S33, the computer 1 offers to the user 5 these group specifications Gi, that is to say those group specifications Gi which for the objects 7 of the selected object types T each contain an application instruction Aj for selection. In step S34, the computer 1 accepts the selection command C2 from the user 5 and selects the corresponding group ^{specification} Gi on the basis of the selection command C2. This procedure ensures that the selected group instruction Gi corresponds to the wishes and needs of the user 5.

The creation of the group regulations Gi and also of the application instructions Aj (and as far as necessary, also of the supplementary regulations A ') can take place as required. It is for example possible that the corresponding rules Gi, Aj, A 'are fixed to the computer 1 and the user 5 can not be changed. Preferably, however, the computer 1 is in the context of the processing of the machine code 4 able to move into an editing mode. Of the

Edit mode is executed by the computer 1 before or after execution of a machining method, as explained above in connection with FIGS. 1 to 7. In the editing mode, it may be permissible for the user to create, modify, expand and, under certain circumstances, also delete application instructions Aj and, if appropriate, supplementary instructions A '. If appropriate, it may furthermore be permissible for the user 5 to switch application instructions Aj and possibly also supplementary instructions A 'between an activated and a deactivated state. These procedures are, if permitted, as in the prior art also. Furthermore, the user 5 can also manipulate group specifications Gi in the editing mode. This will be explained below in connection with FIG.

According to FIG 8, the computer 1 takes from the user 5 in one

Step S41 is opposed by a processing command C3. The bear Processing command C3 may be a command for processing an application instruction Aj or a supplementary instruction A 'or a command for processing a group instruction Gi. In a step S42, the computer 1 therefore checks whether the processing command C3 is a command for processing a group instruction Gi.

If the editing command C3 is not a command for editing a group policy Gi, the computer 1 proceeds to a step S43. In step S43, the computer 1 processes an application instruction Aj or a supplementary instruction A '. The processing can be enabled one to create a new application protocol A, possibly deleting an existing application protocol A, changing an existing application rule Aj or switching an existing application rule Aj between the states and his deakti ^¬ fourth as needed. Analogous procedures are also possible with regard to a supplementary instruction A '. The application procedure Aj or supplemental prescription A 'can - but need not - be ^¬ already part of a group provision Gi.

On the other hand, when the edit command C3 is a command to edit a group command Gi, the calculator 1 proceeds to a step S44. In step S44 of the computer 1, the computer 1 processes a group instruction Gi. If necessary, the processing can be done by creating a new group rule Gi, possibly deleting an existing group rule Gi, adding an additional, but already existing application rule Aj to the group rule Gi, possibly removing an already existing application rule Aj from the group rule Gi or switching an existing group rule Gi between the states and be disabled. If it is at the machining ^¬ processing command C3 is a command to edit a group Gi procedure, thus the corresponding groups Gi ^¬ prescribed by means of the edit command C3 required are switched created, modified, extended or ak ^¬ tivated between the states / deactivated.

In summary, the present invention thus relates to the following facts:

A computer 1 assigns 6 segmented objects 7 in a volume data set automatically or with the assistance of a user 5 a respective object type T. The computer 1 belongs to the respective segmented object 7 is a Applikati ^¬ onsvorschrift A, Aj and returns at least the segmented objects 7 of the volume data set 6 in the form of a B picture on a display device 8 to the user 5 on. As part of the output of the volume data record 6 to the user 5, the computer 1 processes the objects 7 segmented in the volume data record 6 in accordance with the application instructions A, Aj assigned to the objects 7. Before assigning the application instructions A, Aj to the segmented objects 7, the computer 1 accepts from the user 5 a selection command C2 and selects one of several based on the selection command C2

Group Regulations Gi. The group Gi rules each including a plurality of objects 7 of a respective Whether ^¬ jekttyps T applied application rules Aj. The computer 1 determines for segmented in the volume data set objects 6 7 automatically in accordance with the respective segmented object 7 associated object type T the corresponding application rule contained in the selected group provision Gi j and assigns them to the respective Whether ^¬ projects. 7

Although the invention in detail by the preferred embodiment has been illustrated and described in detail, the invention is not limited ^¬ by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention. _{Ί n}

 i y

Reference sign list

1 computer

 2 computer program

3 data carrier

 4 machine code

 5 users

 6 volume data z

 7 O ects

8 viewing device

A, A ', Aj Application Advances A' Supplementary Precursor

B illustration

Cl call command

C2 selection command

C3 Processing command D Display parameter E Evaluation primitive g Gray value

Gi group prescriptions

Sl to S44 steps

 T Whether ect types

 Z numerical value

Claims

claims

1. Processing method for a volume data set (6) by a computer (1),

- wherein the computer (1) in the volume data set (6) segmented objects (7) automatically or with the assistance of a user (5) assigns a respective object type (T),

wherein the computer (1) assigns an application instruction (A, Aj) to the respective segmented object (7),

- wherein the computer (1) at least the segmented objects (7) of the volume data set (6) in the form of a figure (B) via a viewing device (8) to the user (5),

- wherein the computer (1) in the context of the output of Volumenda ^¬ tensatzes (6) to the user (5) in the volume data set (6) segmented objects (7) corresponding to the objects

(7) assigned application instructions (A, Aj) processed,

characterized ,

- That the computer (1) before assigning the application fonts (A, Aj) to the segmented objects (7) from the user (5) receives a selection command (C2) and on the basis of the selection command (C2) one of several group prescriptions ^¬ (Gi) selected,

- that the group regulations (Gi) each contain a plurality of objects (7) of a respective object type (T) to be used ^¬ the application instructions (Aj),

- That the computer (1) automatically for in the volume data set (6) segmented objects (7) corresponding to the jeweili ^¬ gene segmented object (7) associated object type (T) contained in the selected group rule (Gi) kor ^¬ respondierende application rule (Aj ) and assigned to the respective objects (7).

2. Processing method according to claim 1,

characterized ,

that the calculator (1) - First by the user (5) receives the selection command (C2) and based on the selection command (C2) selects the appropriate group rule (Gi) and

 - Then for the object types contained in the selected group rule (G) (T) automatically or with the support of the user (5) in the volume data set (6) the associated objects (7) segmented.

3. Processing method according to claim 1 or 2,

characterized ,

that the computer (1) checks if all in the selected group rule (Gi) contained object types (T) in the volume data set (6) in each case at least one object (7) segmen ^¬ is collapsible, and that the computer (1) to the user (5) issues a message if this is not the case.

4. Processing method according to claim 1, 2 or 3,

characterized ,

that a first of the application instructions (Aj) of the selected group rule (Gi) are first presentation parameters

(D), which influence the way in which objects (7) of a first object type (T) are represented in the image (B), and in that the computer (1) determines the image (B) of the objects (7) of the image first object type (T) takes into account the representation parameters (D).

5. Processing method according to claim 4,

characterized ,

- That at least a second of the application prescriptions (Aj) of the selected group rule (Gi) second Dar ^¬ position parameters (D), which influence the type of illustration ^¬ tion of objects (7) of a second object type (T) in the figure (B) .

- That the selected group rule (GI) contains an amendment rule (A ') for these two object types (7), which comprises third representation parameters (D), wel ^¬ che the type of representation of objects (7) of the first and the second Object type (T) in figure (B). if the objects (7) of the first and second object types (T) are in the same location in the image (B) or in the volume data set (6), and

 that the computer (1) for the objects (7) of the first and the second object type (T) in the area in which the objects (7) of the first and second object type (T) in the figure (B) or in Volume data set (6) are in the same place, instead of the first and the second display parameters (D), the third display parameters (D) used.

6. Processing method according to one of the above claims, d a d u c h e c e n e c e n e,

that at least one of the application rules (Aj) of the selected group of instructions (Gi) comprises a Auswertungsvor ^¬ writing (E), which by means of the computer (1) for the Whether ^¬ projects (7) of the corresponding object type (T) individually or collectively (a numerical value Z), and that the computer (1) outputs the numerical value (Z) via the display device (8) to the user (5).

7. Processing method according to one of the above claims, d a d u c h e c e n e c e n e,

the computer (1) receives a selection of at least one object type (T) from the user (5) before specifying the selection command (C2) and that the computer (1) offers the user (5) those group prescriptions (Gi) for selection, which for the objects (7) of the selected object types (T) each contain an application rule (Aj).

8. Processing method according to one of the above claims, d a d u c h e c e n e c e n e,

that the computer (1) by the user (5) creating commands Gruppenvor- created fonts ent ^¬ against accepts and with reference to the drawing commands, changes, expanded, and / or switched between an activated and a deactivated state.

9. Computer program comprising machine code (4) which can be processed by a computer (1), the processing of the machine code (4) by the computer (1) causing the computer (1) to perform a processing method according to one of the above claims performs.

10. A computer, wherein the computer is programmed with a computer program (2) according to claim 9, so that the computer in Be ^{¬ operation} receives a call command (Cl) and executes a processing method according to one of claims 1 to 8 due to the call command (C2) ,