WO2014032713A1

WO2014032713A1 - Production of a graphical user interface

Info

Publication number: WO2014032713A1
Application number: PCT/EP2012/066813
Authority: WO
Inventors: Edgar Frank; Wolfgang Riedl; Jens Ansgar Rosenberg; Frank Volkmann
Original assignee: Siemens Aktiengesellschaft
Priority date: 2012-08-30
Filing date: 2012-08-30
Publication date: 2014-03-06

Abstract

The invention relates to the production of a graphical user interface (1) having static interface elements (2 to 10), wherein a description (12) of the graphical user interface (1) is created, which description contains description segments with descriptions of the static interface elements (2 to 10). The graphical user interface (1) is generated from the description (12) thereof and is presented during a program runtime (B) using a graphics system (18). In this case, static graphics (16) representing all of these static interface elements (2 to 10) are formed from the description segments of a plurality of static interface elements (2 to 10).

Description

description

Generation of a Graphical User Interface The invention relates to a method for generating a graphical user interface with static surface elements.

Under a static surface element one item from the graphical user interface is here understood element whose graphic representation is not changed during program execution, the grafi ^¬ rule user interface and does not Interakti ^¬ onsmöglichkeit available to a user of the graphical user interface. Under a dynamic surface element is a Ele ^¬ ment of the graphical user interface is accordingly hereinafter understood, the graphic display is changeable during program execution the grafi ^¬'s user interface, for example, to represent changes in the program and / or a user of the graphical user interface an interaction ^¬ possibility, for example by triggering ei ^¬ ne reaction to a mouse click of the user. Grafi ^¬ specific user interfaces are often complicated and designed in a wide variety of static and dynamic elements Oberflächenele- constructed. Whether an element is a concrete grafi ^¬ rule user interface behaves dynamically or statically, not generally depends on the type of the element, but on the programmatic use of the element in the program that brings the graphical user interface for display.

For programmatic creation of a graphical user interface is a declarative descrip ^¬ description language (declarative programming language) used today usually, a description of the graphical user interface is created using the software in a preparation phase. Currently ge ^¬ bräuchliche description languages, for example, XAML (Extensible Application Markup Language), XUL (= User Inter- face language), UIML (= User Interface Markup Language) and HTML (= Hypertext Markup Language). The program runtime is the description, or optionally, scored a previous compilation is a compilation of the description by means of a graphics system and displayed as graphical Benutzeroberflä ^¬ surface.

The invention has for its object to provide an improved method for generating a graphical user interface. Furthermore, the invention has for its object to provide a system for carrying out the method.

The object is achieved according to the invention by the features of claim 12 with regard to the method by the features of claim 1 and with respect to the system.

Advantageous embodiments of the invention are the subject of the dependent claims. In the method according to the invention for generating a graphical user interface with static surface elements, a description of the graphical user interface is created, which contains description segments with descriptions of the static surface elements. The graphical user surface is generated from its description and currency ^¬ rend a program run time by means of a graphics system is provided ^¬. In this case, all of these surfaces a ^¬ elements performing static image is formed from the description segments more static surface elements.

In other words, the invention proposes to combine several static surface elements into a single static graphic. This advantageously reduces the computational load and the memory consumption required for the generation and execution of the graphical user interface, as the Be ^¬ sensitive segments of the combined static surface elements do not need to be individually evaluated. In particular, this reduction speeds up computational burden and memory usage, the creation and execution of the graphical user interface on slow Laufzeitsys ^¬ temen such as mobile phones or tablet computers, or allow the creation and execution of the graphical user interface on such a run-time systems in the first place. At the same time it is advantageously achieved that the same description of the graphical user interface on a larger Number of different runtime systems can be used, so that a system-dependent change of the description is eliminated.

A preferred embodiment of the invention provides that the description segments of the static surface elements in the description of the graphical user interface are each marked by a writing element characterizing static surface elements.

According to this embodiment of the invention, the description segments surface static elements so loading in ^¬ scription of the graphical user interface are kiert as such MAR. This advantageously facilitates the evaluation of loading ^¬ scription and further reduces the computational complexity for evaluating the description because the description must not be analyzed only consuming to locate Description Segments stati ^¬ shear interface elements in the description. In addition, this embodiment avoids possible errors in finding descriptive segments of static surfels such as error detections or overlooking such descriptive segments. A further embodiment of the invention provides that are generated from the description of the graphical user interface by means of a filter, a static graphic coding Grafikbe ^¬ letters and a description of the segments of the static Oberflächenelemen- illustrated by the static graphic te reduced description of the graphical user interface. In this case, generated as a graphic description of a separate graphic file or graphic description embedded in the reduced Be ^¬ rewriting of the graphical user who ^¬.

According to this embodiment of the invention a reduced Be ^¬ letters and a graphic description from the description thus formed by a filter, wherein the graphic description together the static surface elements fere the reduced specification, the dynamic

Interface elements, but no longer describes the results summarized in the Grafikbe ^¬ write-static interface elements. The graphic description can thereby fikdatei as a separate graphic file, such as a vector graphic or Rastergra- be formed or embedded into the reduced descrip ^¬ advertising graphical user interface.

This advantageously means that the reduced loading case must be evaluated to generate the graphical user interface only, to generate therefrom the dynamic interface elements, while the static upper ^¬ surface elements together in a separate graphic Description quantitative construed that directly in the representation the graphical user interface can be used.

A further embodiment of the aforementioned embodiment of the invention provides that the graphic description and the reduced description of the graphical user interface are generated during the program runtime and transferred to the graphics system, and that the reduced description of the graphical user interface is evaluated by the graphics system.

This design further allows, for example, carry case adapted for ver ^¬ different graphics systems evaluations of Grafikbe-, which are analyzed by matching existing program runtime expression of the graphics system. An alternative development of the aforementioned embodiment of the invention provides that the graphic description and the reduced description of the graphical user interface are generated before the program runtime, and that the reduced description of the graphical user interface is evaluated by the graphics system.

This refinement is to be preferred if lower-performance runtime systems are used for generating and executing the graphical user interface, since the generation of the graphic description and the reduced description of the graphical user interface does not take place during the program runtime and thus does not cause any computational load or memory requirement during the program ^runtime .

Another alternative further development of the aforementioned embodiment of the invention provides that the graphic description and the reduced description of the graphical user interface are generated before the program runtime, that the reduced description of the graphical user interface is compiled before the program runtime, and that the graphic description and the compiled reduced description ^¬ the graphical user interface are passed to the graphics system. In the case that the graphic description is embedded in the reduced description of the graphical user interface, it is embedded after compilation into the compiled file generated and is passed to the corresponding ^¬ with the compiled file to the graphics system. In contrast to the aforementioned refinement, this further development therefore also provides for a compilation of the reduced description of the graphical user interface before the program runtime and the processing of the compilation by the graphics system during the program runtime. This corresponds to the runtime system utilized for the generation and execution of the graphical user interface further, as only the compilation of reduced descrip ^¬ environment must be processed during the Pro ^¬ gram maturity. Therefore, this further tion particularly advantageous when particularly high Ge ^¬ speed demands on the creation and Ausfüh ^¬ tion of the graphical user interface and / or the runtime system used is particularly poor performance.

A refinement of the embodiment of the invention, in which the description segments of the static surface elements in the description of the graphical user interface are each marked by a description element, provides that this description element as a language element in a

Description language in which the description of the graphical user interface is written.

This further simplifies the design analysis of the loading case, since an identification of segments Description of the static surface elements has already been created in the descrip ^¬ description language and can be accordingly used for the generation of the static graphics. Particularly in this design, the Next Grafiksys ^¬ system can be configured to direct evaluation of the description language and graphical user interface are generated from their description directly by means of the graphics system. This variant is particularly advantageous if the Grafiksys ^¬ tem can be adapted to the description language accordingly.

Alternatively, the description of the graphical user interface before the program run-time by means of a compiler, a static graphic coding graphics description, and generates the description segments of the static surfaces ^¬ elements reduced and compiled description of grafi ^¬'s user interface and the Grafikbe- case and the reduced and compiled description of the graphical user interface are passed to the graphics system. Again, the graphic description can be generated as a separate graphics file or in the reduced and compiled Description of the graphical user interface.

This variant requires that a compiler is used, which is able to distinguish static and dynamic surfaces ^¬ elements. It is particularly advantageous ^¬ way, therefore, when the compiler used can be adjusted according to the Be ^¬ description language so that it can generate the sta ^¬ tables graphics.

A further embodiment of the invention provides that a surface of a dynamic element descriptive descrip ^¬ advertising segment the description of graphic Benutzeroberflä ^¬ surface is divided into sub-segments, wherein at least one UN tersegment is a description of a static segment Oberflä ^¬ chenelementes.

This embodiment relates to complex dynamic surfels containing static content and provides to separate static content from the descriptor segments of such dynamic surfels and to treat them as descriptive segments of static surfels. This simplifies the handling of complex dynamic UI elements and further reduces the computational load and memory consumption. For example, a mouse-clickable button of a graphical user interface may include many individual elements, such as e.g. a frame, a caption, and / or an icon, each of which can be treated as static UI elements, and the description of the dynamics of the button can be reduced to the response to a mouse click.

An inventive system for carrying out the Invention ^¬ the method according to the above-mentioned properties and advantages least includes a graphics system for displaying the graphical user interface. Depending on the configuration of the method, it further comprises a filter or a compiler for generating a graphic that encodes the static graphic. Description of the graphical user interface and a description of the graphical user interface reduced by the description segments of the static UI elements.

The above-described characteristics, features and advantages of this invention as well as the manner in which they are achieved will become clearer and more clearly understood in connection with the following description of embodiments which will be described in connection with the drawings. Showing:

1 shows a graphical user interface, FIG 2 schematically shows a first embodiment of a

Generation of a graphical user interface,

3 shows schematically a second embodiment of a

Generation of a graphical user interface,

4 shows schematically a third embodiment of a

Generation of a graphical user interface,

5 shows schematically a fourth embodiment of a

Creation of a graphical user interface, and

6 shows schematically a fifth embodiment of a

Creation of a graphical user interface. Corresponding parts are provided in all figures with the same reference numerals.

Figure 1 shows an example of a graphical Benutzeroberflä ^¬ che 1 showing a current level of a Fuel- development of a boiler. The boiler is shown in a Schnittdarstel ^¬ ment. The graphical user interface 1 comprises nine static interface elements 2 to 10 and a Dynami ^¬ ULTRASONIC surface element. 11 In this case, a side wall of the boiler by a first static surface element 2, a lid of the boiler by a second static surface element 3, a bottom of the boiler by a third static surface element 4 and six Füllhöhenmarkierungen each represented by one of the other static surface elements 5 to 10.

The current level of the boiler is represented by the dynamic surface element 11.

FIG. 2 schematically shows a first ^exemplary embodiment of a generation of a graphical user interface 1. In this case, a description 12 of the graphical user interface 1 is initially created in a software creation phase A.

The description 12 is written in a declarative description language and contains description of segments each ^¬ describe weils one of the surface elements 2 to. 11 A graphics description generated 14 and the descrip ^¬ bung segments of the static interface elements 2 to 10 re ^¬-induced Description 15 the graphical user interface 1 of the description 12 of the graphical user interface 1 by means of a filter 13 in the Softwareerstellungs ^¬ phase A. The graphic description 14 is formed from the Be ^¬ sensitive segments of the static interface elements 2 to 10 and encodes an all static Oberflächenele ^¬ elements 2 to 10 representing static graphic 16. The graphic ^¬ description 14 can be generated as separate graphic file as shown in FIG. 1 Alternatively, however, it may also be embedded in the reduced description 15 of the graphical user interface 1, as demonstrated below by way of example. Subsequently, the description is compiled reduced 15 in the soft ware ^¬ creation phase A by means of a compiler 17th The generated by the compiler 17 compilation 21 of the redu ^¬ ed Description 15 Description 14 and the graphics are transferred to a graphics system eighteenth In the case that the graphic description 14 is embedded in the reduced description 15, it is also embedded in the compilation 21 after the compilation and is transferred to the graphics system 18 together with the compilation 21.

The graphics system 18 evaluates the compilation 21 of the redu ^¬ ed Description 15 during a programming period B of the graphical user interface. 1 Here, the Grafiksys ^¬ system 18 instantiates the dynamic surface elements 11, arranging them hierarchically in an element tree 19 and generates its dynamics 20. Further, generates the graphics system 18, the graphic user interface 1, by 16 is ^¬ represents the static graphics and the element tree 19 superimposed.

A written in description language XAML descrip ^¬ bung 12 of the graphical Benutzerober- shown in Figure 1 surface 1 is, for example:

<Window x: Class = "ReductionApp MainWindow"

xmlns = "http: / / schemas .microsoft.com/winfx/ 2006 / xaml / presentat ion"

xmlns: x = "http: // schemas .microsoft .com / winfx / 2006 / xaml"

Title = "boiler" Height = "350" Width = "525">

<Grid>

<! - passive ->

<Rectangle Height = "172" HorizontalAlignment = "Left" Margin = "94, 73, 0, 0" Stroke = "Black" VerticalAlignment = "Top"

Width = "112" StrokeThickness = "l" Clip = "M0.5, 1.5 Llll.5,1.5 Llll.5,170.5 L0.5, 170.5 z" />

<! - passive ->

<Ellipse Height = "28" HorizontalAlignment = "Left" Margin = "94, 62, 0, 0" Stroke = "Black" VerticalAlignment = "Top"

Width = "112" Clip = "M0.5, 12.5 Llll.5,12.5 Llll.5, -32.5 L0.5, -

32.5 z "/>

<! - passive -> <Ellipse Height = "28" HorizontalAlignment = "Left" Margin = "94, 226, 0, 0" Stroke = "Black" VerticalAlignment = "Top"

Width = "112" Clip = "M0.5, 27.5 Llll.5,27.5 Llll.5,16.5 LO.5,16.5 z" />

<Rectangle Height = "88" HorizontalAlignment = "Left" Margin = "94, 153, 0, 0" VerticalAlignment = "Top" Width = "112" Stroke- Thickness = "l" Clip = "M0.5, 1.5 Llll.5,1.5 Llll.5,170.5

L0.5, 170.5 z "Fill =" LIGHTBLUE "/>

<! - passive ->

<! - passive ->

<! - passive ->

<! - passive ->

<Rectangle HorizontalAlignment = "Left" Height = "6" Margin = "87, 123, 0, 0" StrokeThickness = "1" VerticalAlignment = "Top"

Width = "14" Fill = "Black" />

<! - passive ->

<Rectangle HorizontalAlignment = "Left" Height = "6" Margin = "87, 143, 0, 0" StrokeThickness = "1" VerticalAlignment = "Top"

Width = "14" Fill = "Black" />

<! - passive ->

</ Grid>

</ Window>

In this description 12, the static surface elements 2 to 10 are each marked by a descriptive element formed as a comment <! - passive ->, which the description segment of a static surface element 2 to 10 is prefixed.

The first static surface element 2 is described by the following first description segment:

The second static surface element 3 is described by the fol ^¬ constricting second description Segment: = <Ellipse Height "28" Horizontal Alignment = "Left" Mar- gin = "94, 62, 0, 0" Stroke = "Black" Vertical Alignment = "top"

Width = "112" Clip = "M0.5, 12.5 Llll.5,12.5 Llll.5, L0.5 -32.5, - 32.5 z"/> The third static surface element 4 is described by the fol ^¬ constricting third Description Segment:

The further static surface elements 5 to 10 are each described by one of the further description segments, preceded by the comment <! - passive ->. The only dynamic surface element 11 is described in this example by the following description ^segment : <Rectangle Height = "88" HorizontalAlignment = "Left" Margin = "94, 153, 0, 0" VerticalAlignment = "Top" Width = " 112 "Stroke- Thickness =" l "Clip =" M0.5, 1.5 Llll.5,1.5 Llll.5,170.5

L0.5, 170.5 z "Fill =" LIGHTBLUE "/> A generated from the above description 12 reduced Be ^¬ scription 15 14 includes two each formed as a vector graphic Description graphic descriptions of several static surface elements is 2 to 10, for example:

<Window x: Class = "ReductionApp MainWindow"

xmlns = "http: / / schemas .microsoft.com/winfx/ 2006 / xaml / presentat ion"

xmlns: x = "http: // schemas .microsoft .com / winfx / 2006 / xaml"

Title = "boiler" Height = "350" width = "525">

<Grid>

<Path StrokeThickness = "l .0" Stroke = "# ff231f20" StrokeMiter- Limit = "l .0"

Fill = "# ffffffff" Data = "Fl M 59,281.0,500 C 30,510.0,500 7,186.3,717 7,186.7,686 L 7,186,171,757 C 7,186,175,725

30,510,178,943 59,281,178,943 C 88,053,178,943

111,377,175,725 111,377,171,757 L 111,377.7.686 C

111,377.3,717 88,053.0,500 59,281.0,500 Z "/>

<Rectangle Height = "78" HorizontalAlignment = "Left" Margin = "94, 153, 0, 0" VerticalAlignment = "Top" Width = "106" Stroke Thickness = "l" Clip = "M0.5, 1.5 Llll.5,1.5 Llll.5,170.5

L0.5, 170.5 z "Fill =" LIGHTBLUE "Canvas. Left =" - 88 "Canvas. Top =" - 68 "/>

<Path Fill = "# ff231f20" Data = "Fl M 118.563,82.967 L

104,191.82.967 L 104.191,78.176 L 118.563,78.176 L

118,563.82.967 M 118.563.105.721 L 104.191.105.721 L

104,191,100,931 L 118,563,100,931 L 118,563,105,721 M

14.372,60.212 L 0.000.60.212 L 0.000.55.422 L 14.372,55.422 L 14.372.60.212 M 14.372.82.967 L 0.000.82.967 L 0.000.78.176 L 14.372.78.176 L 14.372.82.967 M 14.372.105.721 L

0.000,105,721 L 0.000,100,931 L 14,372,100,931 L

14.372,105.721 M 118.563,60.212 L 104.191.60.212 L

104,191.55.422 L 118.563,55.422 L 118.563,60.212 Z "/>

</ Canvas>

</ Grid> </ Window>

Therein a first graphic description 14 describes a first static graphic 16, which summarizes the static surface elements 2 to 4. This first graphic description 14 is embedded in the reduced description 15 as the following first Path object:

<Path StrokeThickness = "l .0" Stroke = "# ff231f20" StrokeMiter- Limit = "1.0"

30,510,178,943 59,281,178,943 C 88,053,178,943

111,377,175,725 111,377,171,757 L 111,377.7.686 C

111,377.3,717 88,053.0,500 59,281.0,500 Z "/>

A second graphics description 14 describes a second sta ^¬ graphic diagram 16 that summarizes the static surface elements 5 to 10. This second graphic description 14 is embedded in the reduced description 15 as the following second path object:

<Path Fill = "# ff231f20" Data = "Fl M 118.563,82.967 L

104,191.82.967 L 104.191,78.176 L 118.563,78.176 L

118,563.82.967 M 118.563.105.721 L 104.191.105.721 L

104,191,100,931 L 118,563,100,931 L 118,563,105,721 M

0.000,105,721 L 0.000,100,931 L 14,372,100,931 L

14.372,105.721 M 118.563,60.212 L 104.191.60.212 L

104,191.55.422 L 118.563,55.422 L 118.563,60.212 Z "/>

In addition to the two graphic descriptions 14, the reduced description 15 contains only the description segment of the single dynamic surface element 11 as well as a Canvas element. The reduced description 15 of this example, therefore, contains only four graphics objects remaining in memory a runtime system on which the graphic is executed Benutzeroberflä ^¬ che 1 must be applied. In contrast, the corresponding original description contains 12 to ^¬ total ten graphic objects (eight Rectangle- and two Ellipse objects). The reduced description 15 thus advantageously reduces the number of graphics objects to be created in the memory of the runtime system from ten to four.

Figure 3 shows a second embodiment of a generating a graphical user interface 1. This Ausführungsbei ^¬ game from the one shown in Figure 2 the first embodiment only in that the redu ^¬ ed Description 15 the graphical user interface 1 to the graphics system 18 is directly transferred to and during from this differs the program runtime B is evaluated without being compiled ^¬ lated. This reduces the complexity in the software ^¬ creation phase A, but increases the demands on the Gra ^¬ fiksystem 18 and the computational effort during the program execution time ^¬ B compared to the first embodiment.

FIG. 4 shows a third exemplary embodiment of a generation of a graphical user interface 1. This ^exemplary embodiment differs from the second exemplary embodiment shown in FIG. 3 only in that the reduced description 15 of the graphical user interface 1 and the graphic description 14 from the filter 13 the program ^runtime B and not in the software ^creation phase A are generated. This increases the computational effort and storage requirements during the program runtime B compared to the second embodiment. However, the effort in software development phase A is reduced.

Figure 5 shows a fourth embodiment of a generating a graphical user interface 1. In this embodiment, the static surface elements are from 2 to 10 marked in the description 12 of the graphical user interface 1 by a description element that is a Sprachele ^¬ ment of the description language in which the Description 12 is written or the description language is REQUIRED ^¬ chenfalls this language element. By means of a compiler 17 formed for processing of the description language in the software development phase A from the description 12 of the graphic user interface 1 is a Gra ^¬ fikbeschreibung 14 for displaying the static interface elements 2 to 10 and a compilation 21 reduced to the specific segments of the static interface elements 2 to 10 Description 15 of Graphical User Interface 1 is generated. From the graphic description 14 and the

Compilation 21, the graphical user interface 1 is generated by a graphics system 18 during the program runtime B as in the first embodiment shown in FIG. Figure 6 shows a fifth embodiment of creating a graphical user interface 1. As in the fourth embodiment, also in this fifth embodiment, the static surface elements 2 to 10 in the description 12 of the graphical user interface 1 are marked by a description element which is a language element of the description language, or the description language is extended if necessary by this language element. In this fifth embodiment, the graphics system 18, is tert such expanded in contrast to the fourth embodiment that generates the static image 16 and the element tree 19, the dynamic surface elements 11 from the descrip ^¬ bung 12 of the graphical user interface 1 while the Pro ^¬ frame runtime B directly , While the invention has been further illustrated and described in detail by way of preferred embodiments, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention. Which exemplary embodiment is chosen in a concrete application example depends on the available graphics system and the associated compilers. Reference sign list

1 user interface

2 to 10 static surface element 11 dynamic surface element

12 Description

13 filters

14 Graphic description

15 reduced description

16 static graphics

17 compilers

18 graphics system

19 element tree

20 dynamics

21 compilation

A software creation phase

B program runtime

Claims

claims

1. A method for generating a graphical user interface (1) with static surface elements (2 to 10), wherein - is created a description (12) of graphical user interface (1), the description segments with Be ^¬ overrides the static surface elements (2 to 10) contains

and the graphical user interface (1) is generated from its description (12) and is displayed during a program runtime (B) by means of a graphics system (18),

- wherein the segments description more static surface elements (2 to 10) is a static surface, all these elements (2 to 10) performing static Gra ^¬ fik (16) is formed from.

2. The method according to claim 1,

characterized in that the specific segments of the static surface elements (2 to 10) in the descrip ^¬ bung (12) of graphical user interface (1) in each case by a static surface elements (2 to 10) characteristic descriptor be marked.

3. The method according to any one of the preceding claims, characterized in that from the description (12) of the graphical user interface (1) by means of a filter (13) a static graphic (16) encoding Grafikbeschrei ^¬ advertising (14) and one to the description segments that of the static graphic (16) shown static surface elements (2 to 10) reduced description (15) of grafi ^¬'s user interface (1) are generated.

4. The method according to claim 3,

characterized in that a separate graphic file is generated as a graphic description (14), or that the Grafikbe ^¬ case (14) is embedded in the reduced description (15) of graphical user interface (1).

5. The method according to claim 3 or 4,

characterized in that the graphical description (14) and the reduced description (15) of the graphical user interface (1) are generated during the program runtime (B) and transferred to the graphics system (18), and that the reduced description (15) of the graphical user interface (1) is User interface (1) by the graphics system (18) is evaluated.

6. The method according to claim 3 or 4,

characterized in that the graphic description (14) and the reduced description (15) of the graphical user interface (1) are generated before the program run time (B), and that the reduced description (15) of the graphical user interface (1) is generated by the graphics system (18) is evaluated.

7. The method according to claim 3 or 4,

characterized in that the graphic description (14) and the reduced description (15) of graphical user interface (1) before the program period (B) are generated, that the reduced description (15) of the graphical Benut ^¬ zeroberfläche (1) before the program run-time ( B) is compiled, and that the graphic description (14) and the compiled reduced description (15) of the graphical user interface (1) are transferred to the graphics system (18).

8. The method according to claim 2,

characterized in that the static surface elements (2 to 10) characterizing descriptive element is recorded as a speech ^¬ element in a description language in which the Beschrei ^¬ advertising (12) of the graphical user interface (1) is written.

9. The method according to claim 8,

characterized in that the graphics system (18) is designed for direct evaluation of the description language, and that the graphical user interface (1) is produced from its descrip ^¬ bung (12) directly by means of the graphics system (18).

10. The method according to claim 8,

characterized in that the description (12) of graphical user interface (1) before the program run ^¬ time (B) by means of a compiler (17) includes a static Gra ^¬ fik coding (16) Graphic description (14) and to the specific segments of the static surface elements (2 to 10) reduced and compiled description of grafi ^¬'s user interface (1) are generated, and that the graphic description (14) and the reduced and compiled description of the graphical user interface (1) to the graphics system (18) are passed.

11. The method according to any one of the preceding claims, characterized in that a dynamic surface ^¬ element (2 to 10) descriptive descriptive segment of the description (12) of the graphical user interface (1) is divided into subsegments, wherein at least one subsegment is a description segment of a static Surface element (2 to 10) is.

12. System for carrying out the method according to one of the preceding claims, comprising a graphics system (18) for displaying the graphical user interface (1).

13. System according to claim 12,

characterized by a filter (13) for generating a graphic description (14) which codes the static graphic (16) and a description (15) of the graphical user interface (1) reduced by the description ^{segments of} the static upper surface elements (2 to 10) from the description (12) the graphical user interface (1).

14. System according to claim 12,

characterized by a compiler (17) for generating a graphic description which codes the static graphic (16) bung (14) and a description of the segments of the stati ^¬ rule surface elements (2 to 10) reduced and Kompi ^¬ profiled description of the graphical user interface (1) from the description (12) of graphical user interface (1).