DE102011086859A1 - Touch-sensitive picture screen for control system of motor car, has haptic detectable orientation element that is formed by laser processing recessed portion of free surface of visual sensor disc element - Google Patents

Abstract

The touch-sensitive picture screen (2) has a visual sensor disc element that is extended over a display device. A free surface (11) of the visual sensor disc element is arranged facing away from the display device. A haptic detectable orientation element (12) is located in the free surface of the visual sensor disc element. The haptic detectable orientation element is formed by laser processing a recessed portion of the free surface. Independent claims are included for the following: (1) a method for manufacturing touch-sensitive picture screen; and (2) a control system for motor car.

Description

The invention relates to a touch-sensitive screen having at least one display device and with a sight sensor disc extending over the display device, wherein a free, remote from the display device surface of the sensor sensor disc has at least one haptically detectable orientation element.

Furthermore, the invention relates to a method for producing such a touch-sensitive screen.

Furthermore, the invention relates to an operating system, in particular for motor vehicles, which has a computing unit and a touch-sensitive screen for operating the arithmetic unit.

State of the art

Touch-sensitive screens and methods of making the same are known in the art. So-called touch screens are used both in mobile devices as well as permanently installed in motor vehicles to facilitate the user's operation of a computer or a computing unit. While secure operation is already made easy on mobile devices by trigger surfaces shown graphically, it is difficult for the relatively distant user to meet the correct location of the touch-sensitive screen in permanently installed touch-sensitive screens, especially in motor vehicles to trigger a specific function. Usually, a vision sensor disc, which detects the touch point of, for example, a user's finger on the sensor lens and thereby allows an assignment to the virtual keys shown on the display device, made of two superimposed films or a film and a glass or plastic writing, which by spacers in Are kept substantially spaced from each other. It is basically differentiated between resistive screens and capacitive screens.

To facilitate a user's orientation on the screen, for example, sees the publication US 2011/0095994 A1 on a surface facing away from the display device surface of the vision sensor disc haptic tactile orientation elements. It is proposed to provide as orientation elements depressions, elevations or bends.

Disclosure of the invention

The screen according to the invention with the features of claim 1 has the advantage that the at least one orientation element is inexpensive to implement and further the optics of the screen is not affected, so that the elements represented by the display device are still clearly visible and the overall visual impression of the touch-sensitive screen not disturbed. In addition, the orientation element is incorporated directly into the sensor disk, so that an additional, the orientation element providing layer or film is not necessary. The screen according to the invention is characterized in that the at least one haptically detectable orientation element is a region of the surface modified by laser processing, in particular by so-called laser cutting. It is thus envisaged that the surface of the vision sensor disk facing away from the display device is / were changed region by area by laser processing in order to form a haptically detectable difference from the rest of the surface and thus a haptically detectable orientation element. The surface of the visual sensor disc can be either a foil or an at least substantially rigid glass or plastic disc. In addition, the laser-machined region makes it possible to provide orientation elements which have such a small depth that the visual impression, that is to say the light rays guided through the viewing sensor disk, are not or hardly influenced.

Preferably, the haptically detectable orientation element is a region roughened by laser processing. In this case, it is thus provided that the surface of the visual sensor disk is only roughened in the area mentioned by laser processing. By traversing this area, the user can thus grasp a change in the coefficient of friction, which serves as a haptic orientation aid. The roughness can be adjusted by the laser processing such that the light conductivity of the sensor disk or the visual impression of the screen is not or hardly disturbed.

According to an advantageous development of the invention, it is provided that the orientation element is a recessed area by laser processing. The user can feel the depression when passing over the surface and thereby feel the orientation element. Preferably, the recessed area is recessed by a size required for haptic perception.

Particularly preferably, the orientation element is 0.03 mm to 0.15 mm, in particular around 0.05 mm to 0.1 mm deepened. This very small depression is optically not or hardly detectable for the user. However, the fingertip of an average person is so sensitive that roughness or thickness differences of up to 0.03 mm, in particular 0.05 mm, are recognizable. This provides a surface that is barely changed optically but still provides the user with an orientation element that can haptically capture it.

Preferably, the limited edges in the changed area are formed as broken edges. Broken edges are to be understood as meaning edges which, in particular, have no acute angles and are provided, for example, with a phase or a curve which provides a smooth transition from the surface of the vision sensor disk to the orientation element. With a depression of the area as described above, the edges are so small that even broken edges hardly or hardly affect the optics of the touch-sensitive screen, and the transition from the surface to the orientation element is nevertheless haptically perceptible to the user. The image displayed by the display device is thus not affected.

The inventive method for producing a touch-sensitive screen with the features of claim 1 has the advantages already mentioned above, in particular, that a haptic detectable orientation element is offered, which does not affect the view of the behind the view sensor disc display device and the user still sufficient guidance to correct operation of the screen. The method is characterized in that the at least one orientation element is produced by laser machining of a region of the surface. In this way, a single orientation element or a plurality of orientation elements can be produced quickly and inexpensively. By a corresponding control of a corresponding laser beam device, any shapes for the orientation element (s) can be realized in a simple manner, so that the shape and arrangement of the at least one orientation element can be individually adapted to the button represented by the display device.

Preferably, the area is roughened by the laser processing to form the orientation element.

Alternatively or additionally, it is provided that the area is recessed by the laser processing, so that the orientation element is recessed with respect to the remaining surface of the view sensor disc. Preferably, the recessed area is recessed by a size required for haptic perception by the laser processing.

Preferably, the range is deepened by 0.03 mm to 0.15 mm, in particular by 0.05 mm to 0.1 mm by the laser processing. Particularly preferably, the edges delimiting the region are formed by the laser processing as broken edges, so that in particular they have no acute angles and are provided, for example, with a curvature and / or a chamfer. This ensures that the view is not affected by the view sensor disc on the underlying display device.

The operating system according to the invention with the features of claim 9 is characterized by a touch-sensitive screen, as described above.

In the following, the invention will be explained in more detail with reference to the drawings. Show this

1 an operating system of a motor vehicle in a plan view,

2 a sectional view through a sight sensor disc of the operating system,

3 an enlarged detail view of the sectional view and

4 an alternative embodiment of the operating system.

1 shows a control system in a plan view 1 a motor vehicle, wherein the operating system 1 a touch-sensitive screen 2 and an associated, but not shown here, arithmetic unit has. The screen 2 is in 1 shown in a plan view, so that provided by the screen graphical user interface 3 is recognizable. The user interface 3 has multiple virtual keys in addition to a central area in which information is displayed 4 in the present embodiment, at the left and right edges of the screen 2 are arranged one above the other in each case in a row. Furthermore, the user interface shows 3 in the present embodiment in the lower area approximately centrally a status bar 5 as well as a field 6 to adjust the volume 8th , Of course, the invention is not on a user interface 3 as they are in 1 is shown limited. Rather, it is applicable to all displayable user interfaces of a screen, regardless of the number of buttons 4 as well as their shape and arrangement.

2 shows the screen 2 in a longitudinal sectional view along the line AA 1 , As can be seen, the screen 2 a sighting sensor disk 7 on, which is about a display device 8th , by means of which the

user interface 3 is shown extends. Under a sight sensor disc 7 is a transparent, disc-shaped sensor element to understand, which extends over the display device to detect the position of, for example, the finger of a user with respect to the user interface represented by the display. The sight sensor disc 7 has in the present embodiment, two superimposed films nine and 10 on, between which lies a resistance matrix, not shown here, to which a voltage is applied, which drops from one edge to the other edge and when touching the two films nine . 10 generates a "short circuit", whereby a voltage value is transmitted. By this measurement or detection of the voltage value of the trigger or contact point can be determined. So a user presses the slide nine against the foil 10 , the contact point can be determined by detecting the voltage. It is thus a resistive touch-sensitive screen. According to the present embodiment, the visual sensor disk 7 in the display device 8th integrated, so that the display device 8th does not have its own, further (protective) disc, or that the view sensor disc 7 the disc of the display device 8th forms. According to an alternative, not shown embodiment, however, it is also conceivable, the view sensor disc 7 in addition to a (protective) disc of the display device 8th to provide and thus the sight sensor disc 7 subsequently applied to an appropriately trained display device with a (protective) disc.

According to an alternative embodiment, the touch-sensitive screen 2 worked out as a capacitive working screen, in which the mutually facing surfaces of the films nine . 10 are provided with a metal oxide layer, wherein at a corner of the coating, a voltage is applied, which generates an electric field. Capacitive and resistively touch-sensitive screens are generally known, so that it will not be discussed further here at this point.

By touching the free surface 11 the foil nine or the sighting sensor disk 7 that from the display device 8th turned away, can be the operating system 1 operate by taking the detected position of the user's finger on the sighting sensor disk 7 one of the virtual buttons 4 the user interface 3 is assigned. As in particular in the motor vehicle, the touch-sensitive screen 2 further away from the driver, the accuracy is reduced. For the driver it is difficult to find the desired button 4 safe to hit or azuulösen a desired function, without taking the view too long away from the road.

Advantageously, the screen faces 2 therefore several orientation elements 12 on, which are haptically detectable by the user. Conveniently, every key is 4 the user interface 3 associated with a corresponding haptic orientation element.

The orientation elements 12 become by laser processing the surface 11 the sighting sensor disc 7 in the area of the buttons below 4 produced. In particular, by applying a laser cutting process, the orientation elements 12 as wells 13 in the surface 11 formed, which have a depth of 0.05 mm to 0.1 mm. The orientation elements 12 or the respectively recessed area is advantageously by so-called broken edges 14 limited. While 2 the orientation elements 12 schematically as depressions 13 represents shows 3 in an enlarged partial view exemplified one of the broken edges 14 , The broken edges 14 have no acute angles, and are especially provided with curves. Due to the small depth of the orientation elements 12 and the broken edges 14 is the view through the sight sensor disc 7 to the underlying, provided by the display device user interface is not affected. The user will thus visually no difference on the screen 2 while he haptically the orientation elements 12 can capture.

Alternatively or additionally, the surface may be provided 11 in the area of orientation elements 12 roughen by the laser processing, so that the user has a higher coefficient of friction in the area of the orientation elements 12 or the keys 4 recorded and thereby can orient itself, which also provides a correct operation of the operating system 1 in a simple way is possible.

The screen thus produced 2 or the operating system 1 have the advantage that without affecting the optics, the user in a simple way the haptic arrangement of the keys by means of the orientation elements 12 can capture, taking the basic design of the screen 2 or the sighting sensor disk 7 this does not need to be changed. Another advantage is that the sight sensor disc 7 be manufactured in a sufficient thickness / thickness That may be the few spacers between the slides nine . 10 However, at the trigger point due to the reduced strength / sticke still requires a high sensitivity of the vision sensor disc 7 is guaranteed.

4 shows an alternative embodiment in which instead of a laser-processed surface 11 the foil nine the depression 13 for forming the orientation elements 12 is generated by the fact that the film nine in the area between the spacers 15 that the slides nine and 10 always keep them at a distance from each other, in the direction of the film 10 is deformed. The foil nine becomes, so to speak, in the area between the spacers 15 in the direction of the film 10 pulled deeply, so that at the trigger points also creates a depression that is haptically detectable by the user. The spacers 15 are according to this embodiment according to the arrangement of the virtual keys 4 on the user interface 3 arranged and aligned such that the recesses 13 in the area of the respective button 4 lie. By providing spacers 15 with different height, the depression or the provision of the depression is further supported. For example, between two adjacent spacers 15 a smaller spacer 16 be provided, which is the film nine in the area of the depression 13 at a distance to the slide 10 holds. This is especially true for capacitive sight sensor discs 7 advantageous.

Due to the advantageous design or processing of the view sensor disc 2 can be any shape of the orientation elements 12 represent. So can simple buttons and slides or scroll wheels by a corresponding shaping of the respective recess 13 or the respective orientation element 12 be reproduced. Thus, for example, in the field of volume control and a strip-shaped orientation element can be displayed, over which the user can swipe with his finger to adjust the volume. The contour of the respective laser-processed region preferably corresponds to the surface 11 the contour of the button below 4 the user interface 3 , Of course it is also conceivable the surface 11 be provided by laser processing with a haptic detectable grid for forming a plurality of corresponding haptically detectable orientation elements by laser processing. This is particularly useful if the user interface shown 3 is designed as a dynamic user interface in which, for example, the arrangement of the keys 4 changes during operation or additional keys and existing keys can be hidden.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2011/0095994 A1 [0005]

Claims (9)

Touch-sensitive screen ( 2 ) with at least one display device ( 8th ) and with a through the display device ( 8th ) extended view sensor disc ( 7 ), wherein a free, from the display device ( 8th ) facing away from the surface ( 11 ) of the sighting sensor disk ( 7 ) at least one haptic detectable orientation element ( 12 ), characterized in that at least one haptically detectable orientation element ( 12 ) a surface of the surface modified by laser processing ( 11 ). Screen according to claim 1, characterized in that the haptic detectable orientation element ( 12 ) is a laser-roughened area. Screen according to one of the preceding claims, characterized in that the haptic detectable orientation element ( 12 ) is a laser-recessed area. Screen according to one of the preceding claims, characterized in that the recessed area is formed recessed by 0.03 mm to 0.15 mm, in particular by 0.05 mm to 0.1 mm. Screen according to one of the preceding claims, characterized in that the edges bounding the changed area are broken edges ( 14 ) are formed. Method for producing a touch-sensitive screen ( 2 ), in particular according to one or more of the preceding claims, with at least one display device ( 8th ) and with a through the display device ( 8th ) extending view sensor disc ( 7 ), wherein a free, from the display device ( 8th ) facing away from the surface ( 11 ) of the sighting sensor disk ( 7 ) with at least one haptically detectable orientation element ( 12 ), characterized in that the at least one orientation element ( 12 ) by laser processing a portion of the surface ( 11 ) will be produced. A method according to claim 6, characterized in that the area is roughened and / or deepened by laser processing. Method according to one of the preceding claims, characterized in that the range is deepened by 0.03 mm to 0.15 mm, in particular by 0.05 mm to 0.1 mm by the laser processing. Operating system ( 1 ), in particular for motor vehicles, having an arithmetic unit and a touch-sensitive screen ( 2 ) for operating the arithmetic unit, characterized by the design of the touch-sensitive screen ( 2 ) according to one or more of claims 1 to 5.

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