EP1634247A2 - Method for representing graphic objects and communications equipment - Google Patents

Abstract

The invention relates to a method for representing graphic objects. According to said method, the graphic objects are located on a virtual surface field, which is larger than a display field, on which a section of said virtual surface is represented. Graphic objects that are located outside the represented section of the virtual surface field are projected onto the border of the display field.

Description

description

Process for displaying a graphic object and communication device

The invention relates to a method for displaying a graphic object and a corresponding communication device, in particular a mobile phone or a computer.

The constantly advancing development in the field of mobile phones leads to a constant miniaturization of these mobile phones on the one hand and to constantly improved graphics capabilities of these mobile phones on the other hand. This results in the desire of the users of such mobile phones to use the graphics capabilities of the mobile phones efficiently despite the limited available area of the display device.

For this purpose, it is known to arrange graphic objects, such as symbols, which indicate a function or a program, on a virtual surface field that is larger than an available display field. By moving the display field over the virtual surface field, the proportion of the virtual surface field shown on the display field can be varied and selected by the user, so that the user can select all graphic objects displayed on the virtual surface field, for example by means of a marker.

It turned out to be a disadvantage of this solution that only part of the virtual user interface is visible to a user. The user can therefore only guess at the presence and location of the graphic objects that are not currently shown on the display field, but which are arranged on the virtual surface field.

The invention is based on the object of specifying a technical teaching, the comfortable selection of graphics projects that are arranged on a virtual surface field that is larger than an available display field. This object is solved by the features of the independent claims. Advantageous and expedient further developments result from the dependent claims. Further developments of the device claim, which correspond to the dependent method claims, are also encompassed by the invention.

According to the invention, graphic objects which are arranged on a virtual surface field that is larger than an available display field are projected onto the edge of the display field if they lie outside the section of the virtual surface field shown.

This ensures that all graphic objects arranged on a larger virtual surface field can be displayed on a small available display field. In this case, only that part of the virtual surface field that is selected by the user by positioning the display field above the virtual surface field is preferably displayed to scale. The graphic objects that are not arranged on the portion of the virtual surface field covered by the display field, on the other hand, are only projected onto the edge of the display field. In the context of this application, graphic objects are also understood to mean symbols, symbol parts, icons, leonteile, display windows, display window parts, images, image sections or texts or text elements. The display panel is preferably a display device, such as a graphic display, or part of a display establishment formed. In particular, a display field can be realized by a graphics window.

The virtual surface field is preferably formed by information stored in a storage device, which describes the positions of graphic objects relative to a reference point on the virtual surface field. In addition, this information can also describe the graphic objects themselves or a display scale. This or other information can also determine which section of the virtual surface field is currently to be displayed in which display size on the display field. The representation size or the representation scale of the virtual surface field and the graphic objects arranged thereon can be changed by the user, for example, so that the case can also occur that the representation of the virtual surface field becomes smaller than the display field. In this case, a projected representation of graphic objects can be omitted.

The virtual surface field is preferably larger than a display field if the current length and / or width dimensions of the display field are smaller than the current length or width dimensions of the virtual surface field, with the dimensions of the virtual being calculated The display scale currently applicable for this is used.

Depending on the design variant, a graphic object is preferably outside the section of the virtual surface field shown if it is entirely or partially outside the section of the virtual surface field shown, or if its center lies outside the section of the virtual surface field shown.

The projection onto the edge of the display field includes in particular the case that the graphic object is wholly or partially is shifted from its actual position on the virtual surface field in the direction of the center of the section of the virtual surface field shown and is shown in whole or in part in the edge region of the display field. The edge area is particularly to be interpreted broadly.

Graphic objects that are projected are preferably shown in a reduced size, distorted and / or shown as simple geometric shapes, such as lines, compared to the display scale that currently applies to the virtual surface field.

The marginal areas occupied by the projected graphic objects take up a minimum of space when displaying a line and even when displayed using scaled semicircular projections or "half" object projections, the space required is very small a minimum of additional space is required (in extreme cases, it is only a pixel line of the edge area) in order to be able to visualize all graphic objects and their spatial relationship to one another The reference point used for the calculation of the distance representing the section shown is preferably through the center of the section shown or the display field , a corner point of the section or the display field shown, the intersection of a corresponding projection line with the edge region of the display field or another point of the section shown. The invention is described in more detail below with the aid of preferred exemplary embodiments, the figure listed below serving to explain this:

Figure 1 block diagram of a mobile phone;

Figure 2 first embodiment of the representation and projection of graphic objects; FIG. 3 second embodiment of the representation and projection of graphic objects;

Figure 4 third embodiment of the representation and projection of graphic objects;

FIG. 5 fourth exemplary embodiment of the representation and projection of graphic objects;

FIG. 6 fifth exemplary embodiment of the representation and projection of graphic objects;

FIG. 7 sixth exemplary embodiment of the representation and projection of graphic objects;

FIG. 8 seventh exemplary embodiment of the representation and projection of graphic objects;

FIG. 9 eighth embodiment of the representation and projection of graphic objects.

FIG. 1 shows a mobile telephone MS which contains an operating device MMI, a high-frequency device HF and a processor device PE. The operating device MMI comprises a display device ANZE, such as a graphic display, and actuating elements, such as buttons or softkeys. To control the mobile phone MS, the operating unit MMI of the mobile phone MS and the processes which are carried out by the mobile phone, a program-controlled processor device PE, such as a microcontroller, is provided, which can also include a processor CPU and a memory device SPE.

Depending on the design variant, further components, such as a digital signal processor or other memory devices, whose basic function is related, can be arranged inside or outside the processor device PE, such as a digital signal processor or other memory devices, which are assigned to the processor device, belong to the processor device, are controlled by the processor device or control the processor device with a processor device for controlling a mobile phone is well known to a person skilled in the art, and which is therefore not dealt with in more detail at this point. The different components can exchange data with the processor CPU via a bus system BUS or the input / output interfaces and, if appropriate, suitable controllers.

The program data, such as, for example, the control commands or control procedures, etc., which are used to control the mobile telephone and the MMI control unit, and information for describing the virtual surface field, including graphic objects, are stored in the storage device SPE.

FIG. 2 shows a virtual surface field VOF and a smaller display field ANF, in which a section of the virtual surface field VOF is shown. Graphic objects GO arranged on the virtual surface field VOF are projected along the lines shown onto the edge of the display field ANF, the graphic objects PGO thus projected are shown there as lines. For clarification, the display field ANF is shown enlarged again on the right. According to an embodiment of the invention, the user can do this by actuating a navigation key Move the display field ANF above the virtual surface field VOF or move the virtual surface field VOF below the display field ANF. In addition, there is a change in the display scale or the zoom factor that relates to the virtual surface field VOF, in particular to the portion of the virtual surface field VOF represented by the display field ANF.

FIG. 3 corresponds to FIG. 2 with the exception that the projected graphic objects PGO are not shown as lines, but rather reduced and halved.

FIG. 4 serves to explain the following method for calculating projection edges in the case of a rectangular display field:

If Abs (oX / oY)> dsp.Width / dsp.Height Then 'right and left pY = oY / oX * dsp.Width / 2 If oX> 0 Then

'right pX = dsp.Width / 2 Otherwise' left pX = -dsp.Width / 2 pY = -pY End if disP = Sqr (pX * pX + pY * pY) rP = rθ / disO * disP s {i). Width = 30 s (i) .Height = 2 * rP Otherwise 'above and below pX = oX / oY * dsp.Height / 2 If oY> 0 Then

'below pY = dsp.Height / 2 Otherwise 'above pY = -dsp.Height / 2 pX pX End If disP = Sqr (pX * pX + pY * pY) rP = rθ / diso * disP s (i) .Width = 2 * rP s (i) .Height = 30 end if

FIG. 5 serves to explain the following method for calculating projection margins in the case of a round display field: de = dsp. Width / 2 f = oX / oY cY = de / Sqr (f * f + 1) cX = f * cY if (oX> 0 And cX <0) Or (oX <0 And cX> 0) Then cX = -cX

If (oY> 0 And cY <0) Or (oY <0 And cY> 0) Then cY = -cY rC = rθ / oX * cX s (i) .Width = 2 * rC s (i) .Height = 2 * rC

Figures 6 to 9 show different display variants for the projected graphic objects PGO:

In Figure 6, the graphic object is simply halved in the middle and, after a corresponding reduction, is projected onto the edge.

In FIG. 7, the graphic object is first halved and reduced in accordance with the procedure described in FIG. 6, then is additionally - if it is the threshold with length 1 exceeds - the field on the threshold (only) distorted in the horizontal direction again, if it was previously a left or right projection image, otherwise the field on the threshold (only) is distorted in the vertical direction.

In Figure 8, the graphic object corresponding to the bisection area described in Figure 6 is not shown half but entirely on it. For this purpose, after the operation in FIG. 6, it is shown distorted by a factor of 0.5 and is projected completely visible flush with the edge.

In FIG. 9, the graphic object is hybrid distorted as described under 7 and 8: First, the graphic object is projected onto the edge as a whole in accordance with the halving area and distortion described in FIG. 8 in the horizontal or vertical direction. In addition, when threshold 1 is exceeded, as described in FIG. 7, it is reduced to length 1 only in the horizontal or vertical direction and shown flush with the edge.

In addition to the above-described embodiment variants of the invention, a large number of further embodiment variants are within the scope of the invention, which are not described further here, but can simply be put into practice on the basis of the illustrated exemplary embodiments.

Claims

claims

1. Method for displaying graphic objects (GO), in which the graphic objects (GO) are arranged on a virtual surface field (VOF), in which the virtual surface field (VOF) is larger than a display field (NF), in which a section of the virtual surface area (VOF) is shown in the display field (ANF), in the case of graphic objects (GO) which are outside of the displayed area

Excerpts of the virtual surface field (VOF) are arranged, are projected onto the edge of the display field (ANF).

2. The method according to claim 1, in which projected graphic objects (PGO) are displayed in a reduced size.

3. The method according to any one of the preceding claims, in which projected graphic objects are shown distorted

4. The method according to any one of the preceding claims, in which projected graphic objects are represented as simple geometric shapes.

5. The method according to any one of the preceding claims, are shown in the projected graphic objects as lines along the edge of the display panel.

6. The method according to any one of the preceding claims, in which the size of the display of a projected graphic object is set as a function of the distance between the displayed section of the virtual surface field and the position of the graphic object.

7. Communication device (MS), with a display device (ANZE) for realizing a display field (ANF) on which graphic objects (GO) can be displayed, and with a processor device (PE) which is set up in such a way that graphic objects (GO) are arranged on a virtual surface field (VOF) that the virtual surface field (VOF) is larger than a display field (ANF), that a section of the virtual surface field (VOF) is shown on the display field (ANF), and that graphic objects (GO) are outside the displayed section of the virtual surface field (VOF) are arranged, are projected onto the edge of the display field (ANF).