WO2009024112A2

WO2009024112A2 - Display device with image surface

Info

Publication number: WO2009024112A2
Application number: PCT/DE2008/001156
Authority: WO
Inventors: Johannes Angenvoort
Original assignee: Navigon Ag
Priority date: 2007-08-22
Filing date: 2008-07-21
Publication date: 2009-02-26
Also published as: DE102007039669A1; EP2181383A2; WO2009024112A3

Abstract

The invention relates to a display device (02) with an image surface (04) on which image contents (05, 06, 07, 11, 12) can be displayed in an electronically controllable fashion, wherein the image surface (04) has a two-dimensional extent in the X direction and in the Y direction, wherein the display device (02) interacts with a proximity sensor system, wherein the distance and/or the change in distance between an operator control element or body part (03) from the image surface (04) in the Z direction and the relative position and/or the changes in relative position of the operator control element or of the body part (03) relative to the image surface (04) in the X direction and in the Y direction can be detected by means of the proximity sensor system, and wherein the image content (06, 07, 11, 12) which is displayed on the image surface (04) can be changed under programme control as a function of the position of the operator control element or body part (03) which is detected by means of the proximity sensor system.

Description

'Display device with image area ¹

The invention relates to a display device with a picture surface according to the preamble of claim 1.

Generic display devices have an image surface on which image contents can be displayed electronically controllable. The image surface has an extension in the X direction and in the Y direction. Such displays are used on all types of electronic devices to display specific image content to the user. For example, navigation devices are equipped with corresponding display devices.

In many cases, the display device also serves as an input device. For this purpose, the display device is designed in the manner of a touch screen. By touching certain areas of the display devices associated with the corresponding areas operating commands can be triggered. As a result, it is possible, for example, for a control element to be displayed in a certain image area of the image area and to be selected and executed on touching this subarea of the control command assigned to the control element. Depending on the size of the display device, only a limited number of image contents of limited size can be displayed on the image area. This poses a problem, in particular with mobile devices, for example mobile navigation devices, since the display devices present on these mobile devices are kept relatively small in order not to restrict mobility. Due to the relatively small display device, the displayed image contents can only be displayed with a relatively small scale. Although a change in the display scale of the displayed image content is possible, but requires the operation of appropriate controls, which is cumbersome and limits the ease of use.

Based on this prior art, it is therefore an object of the present invention to provide a new display device, with the ease of use can be increased.

This object is achieved by a display device according to the teaching of claim 1.

Advantageous embodiment forms of the invention are the subject of the subclaims.

The display device according to the invention is based on the basic idea that the display device cooperates with a proximity sensor. By the proximity sensor, the distance or the change in distance of a control element, such as a stylus, or a body part, such as a finger, can be detected in the Z direction. At the same time, the proximity sensor makes it possible to detect the relative position or relative position change of the operating element or of the body part relative to the image area in the X direction and in the Y direction. Depending on the detection result of the proximity sensor, the image content displayed on the screen is programmatically changed.

The type of program-controlled modification of the image content displayed on the screen is basically arbitrary. After a In a preferred embodiment, as a function of the position of the control element or body part detected by the proximity sensor, a partial image area of the image area is selected, and this partial image area is shown enlarged after the selection.

There are various strategies for selecting the enlarged displayed partial image area conceivable. In order to enable a particularly simple and intuitive operation of the display device, it is particularly advantageous if the image area is divided into predefined partial areas as a whole. When using the display device, the partial image area is then always selected and enlarged, which has the smallest distance to the operating element or to the body part in the Z direction. Thus, it is intuitively recognizable to the user that he selects by the approach of the control element or one of his body parts, for example, his index finger, each of the sub-image area and brings to enlarged representation, which has the smallest distance to the control element or to the body part.

According to a further preferred embodiment, it is provided that the enlargement factor, by which the partial image area to be enlarged is enlarged, can also be changed by the approach of the operating element or body part. For this purpose, the distance of the control element or body part to the image surface in the Z direction is detected by the proximity sensor system and derived from this distance in accordance with a predetermined control strategy, the magnification factor.

The operation of the display device is particularly simple and intuitive when the magnification factor is linearly proportional to the distance of the operating element or body part to the image surface in the Z direction.

In addition, an intuitive use of the display device is supported when the magnification factor is greater, the smaller the distance of the operating element or body part to the image surface in the Z direction. In other words, that means extra Approximation of the control or body part to the image area of the magnification factor can be increased.

When a certain threshold distance between operating element or body part to the image surface in the Z direction is exceeded, an enlargement of individual partial image areas should no longer be undertaken. This is achieved by the fact that the magnification factor is equal to 1 when a predefined limit distance is exceeded.

The structural design of the proximity sensor for determining the relative position of the control element or the body part relative to the image surface is basically arbitrary. According to a first preferred embodiment, the proximity sensor system consists of a plurality of proximity sensors, which are arranged below the image surface and are respectively assigned to exactly one predefined partial image area. Each of the individual proximity sensors is set up to detect the distance of the operating element or of the body part from the image surface. Subsequently, a comparison is carried out in the control of the display device and the proximity sensor is determined which has detected the smallest distance to the operating element or body part. Subsequently, the partial image area is displayed enlarged, which is associated with the proximity sensor with the smallest distance.

Alternatively, the proximity sensor can be formed by a stereo optical camera system. To realize the proximity sensor, for example, two cameras may be provided in the display device, which interact as a stereo camera.

The geometry of the enlarged image area to be displayed is in principle arbitrary. Any shapes are possible, in particular those which correspond to the shape of a control element, such as a button. For most applications, it is advantageous if the partial image area to be enlarged is rectangular or circular. There are different variants for the type of enlargement of the partial image area to be enlarged. According to a first variant, the partial image area to be enlarged is enlarged in the X direction and in the Y direction with the same magnification factor. As a result, distortions are excluded in the enlargement to be displayed partial image.

Alternatively, it is also conceivable that the magnification factor in the X direction and in the Y direction is different in each case. As a result, the partial image to be enlarged is stretched in one direction or compressed in one direction. According to a further alternative, it is conceivable that the magnification factor in each case depends on the position of the corresponding pixel in the sub-image area. In this way, the magnification factor can thus vary in the sub-image area.

For variation of the magnification factor in the partial image area to be displayed enlarged, it is conceivable, for example, that the magnification factor is greatest in the center of the partial image area to be displayed and smallest at the edge of the partial image area to be displayed. As a result, it is possible to realize an enlargement which gives the user a lenticular image impression.

Which partial image areas of the image areas of the display device are enlarged is fundamentally arbitrary. Of particular importance is the enlargement of partial image areas, which represent a switching element, a text field or a graphic field. Switching elements are characterized in that they each have a specific operating function assigned. In text fields, text contents are displayed, whereas graphic fields are provided for displaying certain graphic contents.

In order to realize the preferred enlargement of certain sub-image areas even in those cases in which the approximation of the operating element or body element would not trigger an enlargement of the sub-image area per se, these sub-image areas may be assigned a surrounding supplementary area. Will now the control or the Body part approximated to the supplementary surface, so this already causes an enlarged view of the supplementary surface associated Teilbildfläche. This type of preferred magnification has particular importance in frequently used controls. Due to the supplementary surface, the frequently used operating elements are assigned an enlarged catchment area for the detection of the approach of the operating element or body part.

To extend the function of the display device according to the invention, this display device can be used as part of an input device. By appropriate input elements or input functions, the user then has the option to make certain inputs depending on the image content on the display device.

According to a first variant for integrating the display device in an input device, it can be provided that a plurality of contact sensors are seconded below the image surface. By the contact sensors, the contact of the operating element or the body part can be detected on associated partial image areas. Depending on the detected partial image area, an operating command assigned to the partial image area is selected or triggered. This ultimately corresponds to the function of a classic touch screen.

Alternatively, it is also conceivable to use the proximity sensor itself to select or trigger the operating command. In this case, the position of the control element or body part is first detected by the proximity sensor, thereby selecting a specific partial image area. The selected partial image area can preferably be displayed enlarged in order to display the corresponding selection to the user. In addition, the distance of the operating element or body part to the image area in the Z direction is monitored. If this distance falls below a predefined limit distance, an operating command assigned to the selected sub-image area is triggered. In other words, this means that by the approach of the operating element or body part, a selected operating command, that of the selected Part image area is assigned, can be confirmed by the user and thus triggered.

In which device class the display device is integrated is basically arbitrary. The display device according to the invention offers particularly great advantages in navigation systems, in particular mobile navigation devices. In these navigation devices, a large number of image contents must be displayed on a relatively small screen, so that in particular the enlargement of individual image components is of great importance. This enlargement of individual image contents is considerably simplified by using the display device according to the invention.

In particular when displaying maps, the display device according to the invention is advantageous. If the map of a navigation system is displayed on a display device according to the invention, the position of the operating element or body part can be detected by the proximity sensor and the map can be shifted as a function of the detected position of the operating element or body part. This allows intuitive operation of the navigation system when displaying and moving maps.

Alternatively or in addition thereto, it is also advantageous if the zoom magnification factor of maps displayed on the navigation system can be changed by approaching or removing the operating element or body part. In this case, the zoom magnification factor should be increased as the operating element or body part approaches the image surface and be reduced when removed.

Various aspects of the invention are shown schematically in the drawings and are explained below by way of example.

Show it: 1 shows a navigation device with display device according to the invention when approaching a body part to the display device.

2 shows the image content of a display device according to the invention without an enlarged partial image area;

FIG. 3 shows the display device according to FIG. 2 upon approach of a body part to a partial image area to show a control element; FIG.

FIG. 4 shows the display device according to FIG. 2 when a body part approaches a graphics field; FIG.

Fig. 5, the display device of FIG. 2 when approaching a body part to a text box.

Fig. 1 shows schematically a navigation device 01 with a display device 02 for program-controlled electronic display of image content. In the navigation device 01, a proximity sensor, such as a stereo camera, installed, with the position of a body part, namely a forefinger 03, relative to the display device 02 can be determined. In this case, on the one hand, the distance in the Z direction and, on the other hand, the relative position of the index finger 03 in the X direction and Y direction is detected.

The image area 04 of the display device 02 is divided into a multiplicity of predefined partial image areas 05. When approaching the index finger 03 to the display device 02, the sub-image area 05 is considered to be selected, which has the smallest distance in the Z direction to the index finger 03. The respectively selected partial image area 05 is then enlarged. The mode of operation of the display device 02 will be explained by way of example with reference to the examples in FIGS. 2 to 5.

FIG. 2 shows the image content on the image surface 04 of the display device 02 without approaching the index finger 03. Elements, text fields and graphics fields are displayed electronically in the usual way.

Fig. 3 shows the display device 02 at a vertical approach of the index finger 03 to a control element 06. The control element 06, which normally (see Fig. 2) is displayed according to the size of the other controls, is enlarged and at the same time selected when approaching the index finger 03 , By further approximation of the index finger to the now enlarged control element 06 to below a predefined threshold distance of the control element associated control command can be triggered. Alternatively, it is also conceivable that the display device 02 is formed in the manner of a touch screen and is triggered by touching the enlarged control element 06 of the control element 06 associated control command.

By way of example, the point 10 with the shortest distance to the index finger 03 determines the center of a loupe-like enlarged partial image area 1 1, which is indicated by dashed lines in FIG. 4 , The magnification factor in the partial image area 1 1 varies depending on the location. The largest magnification factor is applied to the center in the area of the center 10, whereas the magnification factor at the edge of the partial image area 11 is the smallest. In this way, a lens-like magnification effect is achieved.

FIG. 5 shows the approach of the index finger 03 to a text field 12. The text field 12 for the numerical display of the geographical position of the navigation system is enlarged on the display device 02 when the index finger approaches. In this case, a different magnification factor has been made between the X and Y directions, yet readability is maintained. LIST OF REFERENCE NUMBERS

Navigation device Display device Index finger Picture area Picture area Control element Map

Center point graphic box text box

Claims

claims

1. display device (02) having an image surface (04) on which image contents (05, 06, 07, 1 1, 12) are electronically controllable display, wherein the image surface (04) has a two-dimensional extent in the X direction and in Y Having direction, characterized in that the display device (02) cooperates with a proximity sensor, wherein by the proximity sensor, the distance and / or the change in distance of a control element or body part (03) to the image surface (04) in the Z direction and the relative position and / or the relative position changes of the control element or the body part (03) relative to the image surface (04) in the X direction and in

Y direction can be detected, and wherein the displayed on the image surface (04) image content (06, 07, 1 1, 12) depending on the detected by the proximity sensor position of the control element or body part (03) is program-controlled variable.

2. Display device according to claim 1, characterized in that in dependence on the detected by the proximity sensor position of the operating element or body part (03) a sub-image area (05, 06, 1 1, 12) can be selected and displayed enlarged.

3. Display device according to claim 2, characterized in that the image surface is divided into predefined partial image areas (05, 06, 1 1, 12), wherein the partial image area (05, 06, 1 1, 12) is selected and enlarged, which represents the has the smallest distance to the control element or body part (03) in the Z direction.

4. Display device according to claim 2 or 3, characterized in that the magnification factor by which the zoomed image area to be displayed (05, 06, 1 1, 12) is increased, from the detected by the proximity sen sensor distance of the operating element or body part (03) to the image surface (04) in the Z direction depends.

5. Display device according to one of claims 2 to 4, characterized in that the magnification factor is linearly proportional to the distance of

Operating element or body part (03) to the image surface (04) in the Z direction depends.

6. Display device according to one of claims 2 to 5, characterized in that the magnification factor is greater, j e is smaller than the distance of the operating element or body part (03) to the image surface (04) in the Z direction.

7. Display device according to one of claims 2 to 6, characterized in that the magnification factor when exceeding a predefined

Limit distance of the control element or body part (03) to the image surface (04) in the Z direction is equal to 1.

8. Display device according to one of claims 2 to 7, characterized in that a plurality of proximity sensors are arranged below the image surface, each of which is associated with exactly one predefined partial image area, wherein with j edem proximity sensor, the distance of the control element or body part to the image surface is detectable, and wherein the partial image area is displayed enlarged, the assigned proximity sensor detects the smallest distance to the operating element or body part.

9. Display device according to one of claims 2 to 7, characterized in that the proximity sensor is formed by an optical stereo camera system.

10. Display device according to one of claims 2 to 8, characterized in that the enlarged to be displayed partial image area (05, 06, 1 1, 12) is rectangular or circular.

1 1. Display device according to one of Claims 2 to 10, characterized in that the partial image area (06, 12) to be displayed enlarged in X-

Direction and in the Y direction with jEweils same large magnification factor is increased.

12. Display device according to one of claims 2 to 10, characterized in that the zoomed image area to be displayed is enlarged in the X direction and in the Y direction with in each case different magnification factor.

13. Display device according to one of claims 2 to 10, characterized in that the magnification factor varies within the zoom image area to be displayed (1 1).

14. Display device according to claim 13, characterized in that the magnification factor in the center of the zoomed image area to be displayed (1 1) largest and at the edge of the partial image area to be displayed is smallest.

15. Display device according to one of claims 2 to 14, characterized in that the enlarged partial image area

- An operating element (06) to which an operating function is assigned, and / or - a text field (12), which is associated with a text content, and / or

- Represents a graphics field (1 1), which is associated with a graphic image content.

16. Display device according to one of claims 2 to 15, characterized in that the partial image area to be enlarged is associated with the sub-image area at least partially surrounding supplementary surface, wherein an approximate representation of the sub-image surface is effected by approaching the operating element or the body part to the supplementary surface.

17. Display device according to one of claims 1 to 16, characterized in that the display device is part of an input device, wherein a plurality of contact sensors are arranged below the image surface, each associated with exactly one sub-image area, and wherein with the contact sensors of the contact of the operating element or body part can be detected on the associated sub-image area, and wherein by detecting the contact of the operating element or body part on a sub-image area, an operating command assigned to the sub-image area can be selected and / or triggered.

18. Display device according to one of claims 1 to 16, characterized in that the display device is part (02) of an input device, wherein in dependence on the Detected by the proximity sensor position of the operating element or body part (03) a sub-image area (05, 06 , 1 1, 12) is selected, and wherein by falling below a predefined limit distance of the operating element or body part (03) to the image surface (04) in the Z direction one of the selected sub-image area (05, 06, 1 1, 12) assigned operating command. can be solved.

19. Display device according to one of claims 1 to 1 8, characterized in that the display device (02) is part of a navigation system, in particular part of a mobile navigation device (01).

20. Display device according to claim 19, characterized in that on the display device (02) of the navigation system (Ol) the section of a map (07) shown in dependence on the detected by the proximity sensor position of the control element or body part (03) can be moved.

21. A display device according to claim 19 or 20, characterized in that on the display device (02) of the navigation system (01), the zoom magnification factor, in particular a part of a section of a map shown (07), in dependence on the detected by the proximity sensor position of the control element or body part (03) can be changed.

22. Display device according to claim 21, characterized in that the zoom magnification factor is increased when the operating element or body part (03) approaches the image surface (04).