DE102012011256A1 - Input element for e.g. interactive advertising display in shop to display goods, has infrared sensor detecting infrared radiation reflected by control body, where location-based control signal is generated in response to detected radiation - Google Patents

Abstract

The input element (1) has a control region (3) associated with a detector unit and comprising an infrared emitter for defined emission of infrared radiation and an infrared sensor. The infrared emitter illuminates the associated control region with the infrared radiation. A control body i.e. control pin, reflects the infrared radiation when the control body contacts the control region. The infrared sensor detects the reflected infrared radiation, where a location-based control signal is generated by the input element in response to the detected infrared radiation. An independent claim is also included for a method for operating an input element for a data processing arrangement for an interactive picture screen.

Description

The invention relates to an input element for a data processing arrangement, comprising a user interface, wherein the user interface is divided into a plurality of operating sectors, wherein based on a touch of one of the operating sectors by a control body, in particular a finger or a stylus, generates a location-related operating signal on the touched operating sector becomes.

Data processing systems, such as interactive advertising displays, ticket machines or the like, are often built in public areas and are available to a variety of users. Such data processing arrangements are operated via input elements with which the user can make inputs to the data processing device. At data processing arrangements in public areas a priority requirement is placed: the data processing arrangement and must be robust against vandalism and misuse. This applies in particular to the input element, which represents one of the interfaces to the user.

When using so-called touch-sensitive screens, the capacitive touch sensors have emerged as a suitable option for data input, although they also have their disadvantages. So these capacitive sensors are not suitable for very thick windows. Because shop windows are often equipped for anti-burglary protection with certain reinforcements, partly made of metal.

From the EP 2 229 617 B1 For example, a camera-based system for detecting physical input errors has been proposed. In this case, a screen is arranged behind a transparent pane on which information for the user can be displayed. Furthermore, the arrangement comprises two cameras, which are also arranged behind the disc. Each camera comprises a deflection unit, which directs infrared radiation from the interaction area, ie where the user's touching operation takes place, into the camera. The interaction area is further illuminated stroboscopically with infrared light. The images of the interaction area obtained via the camera are evaluated via an image processing unit.

However, the camera-based operating system is susceptible to mechanical damage due to the required deflection units. Furthermore, the image processing unit sometimes generates erroneous operating signals.

It is therefore an object of the invention to provide an input element for a data processing arrangement that is both robust against external influences and also offers high reliability in the conversion of the user inputs into operating signals.

The object underlying the present invention is achieved that each operating sector is associated with a respective infrared radiator, the defined emission of infrared radiation, and an infrared sensor, the associated infrared radiator illuminates the associated operating sector with infrared radiation, wherein the infrared radiation reflects from the control body is, if the operating body touches the operating sector, and that the infrared radiation reflected at the operating body of the associated infrared sensor, which is assigned to the operating sector, is detected, and that the input element in response to the detected reflected infrared radiation generates the location-related operating signal. Furthermore, a method of operating an input element according to claim 8 is claimed. Preferred embodiments will be apparent from the dependent claims.

The essence of the invention lies in the fact that a kind of touch-sensitive screen is generated, wherein actually not the touch itself is the physical event that generates the operating signal. Rather, by the touch of the user with an object, such as his finger or a separate pointing device, the reflection conditions on the user interface changed, so that an infrared beam, which is generated in front of the input element itself, is now reflected directly to an infrared sensor of the input element. In particular, both the infrared radiator and the infrared sensor are located on the side of the user interface facing away from the user, ie, apparently where an image can also be generated, provided that the input element is used as part of an interactive display.

The advantage of such an arrangement is in particular that all sensitive elements can be arranged behind a shop window and are thus protected against vandalism or other harmful influences from the outside. Nevertheless, the active irradiation of the user interface with the infrared radiator ensures that a sufficiently powerful signal can reach the user surface and also return from there to the infrared sensor.

In this case, the infrared radiator and the infrared sensors, in particular in a detector unit be summarized locally. Already from this local proximity can be made a connection between radiator and sensor, which can contribute to the fact that the accuracy of the control signals is quite high. It is assumed that the infrared rays impinge on the operating surface at a rather steep angle, specifically not less than 85 °, and are reflected back accordingly.

Preferably, the plurality of detector units is to be arranged parallel to and behind the user interface. This parallel orientation may also include slight curvatures of the arrangement of the detector unit, as long as the user interface also includes a certain curvature. "Behind the user interface" means the side of the user interface facing away from the user. The user interface is thus arranged between the detector units and the user.

Preferably, the detector units are held on a common detector housing, wherein the detector housing is connected to a separately formed to the detector housing disc, in particular a shop window, on which the user interface is arranged. In other words, this means that the (window) pane is part of the input element and provides the user interface. The reflection of the infrared radiation then takes place in particular on the outer surface of the disc or takes place on the operating body, for example the finger, when this operating body rests on the user interface.

It is advantageous if the infrared radiator and / or the infrared sensors are held pivotally relative to the user interface. As a result, fine adjustments can be made so that depending on the optical properties of the user interface, the input element can be adjusted accordingly. So the operating and input result can be optimized. In this case, in a first embodiment, the infrared radiator and / or the infrared sensors can be mounted together with the detector housing pivotable relative to the user interface. This means that all infrared radiators and infrared sensors can be pivoted equally with respect to the user interface. Alternatively, it can also be provided that individual infrared radiators and / or individual infrared sensors of the respective same detector unit are held pivotally relative to one another. This means that the detector unit does not have to be pivotable per se; However, the infrared radiator can be pivoted relative to the associated infrared sensor or vice versa, whereby fine adjustments are possible.

The invention further relates to an interactive screen comprising an input element of the aforementioned type. Furthermore, means for outputting an image through the user interface are provided. The means for outputting the image may be a conventional screen whose image-forming elements are arranged in front of or behind the detector units. The pixel-generating elements of the screen can also be arranged in a plane together with the detector units. The spatial assignment of the screen to the detector unit is fundamentally arbitrary within the scope of the invention, for example in the viewing direction next to and / or above one another.

The invention further relates to a method for operating such an input element. It is preferably provided that the infrared emitters of adjacent detector units emit infrared radiation with different characteristics. As a result, the arrangement can be made significantly more robust, since it can be largely avoided that infrared rays of adjacent detector units are erroneously recognized by an infrared sensor as a relevant operating signal.

In a first embodiment, it can be provided that the infrared radiators of adjacent detector units emit infrared radiation with different wavelengths. The received infrared radiation of an infrared sensor can then be examined for its wavelength and then assigned to an infrared radiator. Then, a distinction can be made that only the infrared rays are to be taken into account, which originate from the infrared radiator which is also associated with the receiving infrared sensor. Alternatively or in combination, the infrared radiators of the adjacent detector units can emit the infrared radiation in particularly characteristic pulse shapes (pulse duration and / or clock frequency). The term "pulse duration" in the sense of the invention means the time length of the individual pulse and "clock frequency" the time interval between two consecutive individual pulses. Based on the temporal differences of the radiated infrared signals can then be decided which received infrared rays are ever relevant for the receiving infrared sensor.

Furthermore, a certain movement of the operating body can already be pointed out by a single infrared radiator. Thus, for example, by utilizing the Doppler effect, runtime differences can be determined by which movements of the operating body can be inferred. The control signals can therefore be refined with information about the movement.

The invention will be explained in more detail with reference to the drawing. Herein shows

• a) in Draufsicht,
• b) im Querschnitt,

1 an inventive input element

• a) in plan view,
• b) in cross section,

2 the input element after 1 enlarged in plan view;

3 Details of a preferred embodiment of the input element according to 1 in cross-section;

4 a timing diagram illustrating the frequency modulation of individual detector units;

5 a timing diagram illustrating the time modulation of individual detector units.

In 1 is a shop window 10 shown, the part of an input element according to the invention 1 for a data processing device. The shop window 10 has a display area 2 on, visualized by the term "text", information for a user can be displayed. For this purpose, a screen is attached to the back of the shop window. This display area 2 also provides a user interface 2 in which a user can make inputs to the data processing device by touch. Then the data processing device can adjust the image on the screen accordingly. There is thus an interactive possibility for communication between the one who exhibits goods in the shop window and the person who views those goods.

The user interface 2 has individual operating sectors shown in dashed lines 3 on, extending over the entire user interface 2 to distribute. Exemplary are the operating sectors 3 however, only on a defined area of the user interface 2 shown, though the operating sectors 3 over the entire user interface 2 are arranged distributed. By touching individual operating sectors 3 an operating signal is generated, by means of which the data processing arrangement can initiate further actions. As with respect to 1b can be seen better, distinguish the operating sectors 3 not by a special design of the user interface 2 out; Rather, they represent virtual areas that are created by a multitude of detector units 5 on the back of the shop window 10 To be defined. The detector units 5 can determine if, for example, a touch by a finger or a hand 4 of a user or other object in an operating sector 3 takes place. operating sectors 3 Thus, therefore, only such areas of the user interface 2 for which the detector units seem to be touch-sensitive.

The arrangement of the detector units and their structure results from the 1b and 2 , The detector units 5 are matrix-like behind the entire user interface 2 arranged. Each of the detector units 5 includes an infrared radiator 6 and an infrared sensor 7 , The infrared radiators 6 emit infrared rays 8th' towards the operating sector 3 , Is at, for example, the operating sector 3 ₁ a touch between the finger 4 and the user interface 2 present, then the infrared ray 8th ₁ reflects and hits as a reflected infrared ray 8th ₁ '' on the infrared sector 7 ₁ , the radiating infrared radiator 6 _{1 is} assigned to. At the operating sector 3 ₂ is no contact between finger and user interface 2 given, there is consequently no reflection of the infrared beam 8th ₂ . Strictly speaking, however, a small portion of the infrared beam is reflected on the disk; However, this is not sufficient to generate a corresponding signal and is therefore neglected.

In particular and as in 2 can be seen form the infrared sensors 7 with the infrared radiators 6 Couples leading to a detector unit 5 are summarized. The size of the operating sectors 3 is determined by the range of influence of the infrared radiator and the infrared sensor. The resolution of the user interface 2 is determined by the size of the operating sectors 3 refined. In particular, if very fine operating commands are to be recognized, of course, the resolution must be adjusted accordingly. It is therefore possible that an operating sector then has a size (eg sector diagonal) of a few millimeters or even a few micrometers.

For proper operation, it is beneficial to have an alignment between the infrared sensors, the infrared radiators and the user interface 2 is possible. In 3a a variant is shown in which a housing 9 in which all detector units 5 are arranged, opposite the shop window 10 is pivotable. As a result, adjustments in the sense of optimizations can be made, so that the reflected infrared rays as centrally as possible on the infrared sensors 7 incident. Alternatively, in 3b shown that only the infrared sensors 7 can be pivoted so as to optimally hit the reflected infrared rays 8th on the infrared sensors 7 to enable. Although it can be provided on the one hand, that the infrared sensors 7 each individually in their respective detector unit 5 can be pivoted. Alternatively, as in 3b shown, but also all infrared sensors can be pivoted over an entire pivoting device. This is exemplary in 3b through a push rod 11 visualized. Of course, it can be provided that only individual rows or individual columns are coupled together in their pivoting movement.

In order to achieve an improvement in the spatial resolution, in a preferred embodiment, the infrared rays of adjacent detector units can be equipped with different frequencies. So is in 4 a diagram is shown in which on an infrared sensor both the infrared radiation 8th ₁ '' of a first infrared radiator and the infrared radiation 8th ₂ '' of a second infrared radiator, for example due to the scattering of radiation impinges. Due to the different frequencies f ₁ , f ₂ , which have the two reflected infrared rays, can be easily assigned, either after the first infrared radiation 8th ₁ "or the second infrared radiation 8th ₁ ''. Thus, it can be ensured that an infrared sensor always considers only that radiation as relevant, which was also emitted by the associated infrared radiator. Thus, for the period t _1, a touch in the operating sector 3 ₁ determined; in the period t ₂ is a touch of the operating sector 3 _1, however, not determined because no infrared radiation to the infrared sensor occurs, the associated infrared radiator 6 ₁ comes.

In an alternative embodiment, the distinction of which infrared radiators originate from the infrared radiation is ensured by temporal resolution. An infrared sensor, for example, continuously encounters a reflected infrared beam in the period before t * 8th'' on. However, it is unclear whether this infrared radiation from a first infrared radiator 6 ₁ or from a second infrared radiator 6 ₂ , each containing an infrared radiation 8th ₁ 'or 8th ₂ 'send out. But as above in the 5 it can be seen, the infrared radiation 8th ₁ 'of the first infrared radiator alternating with the infrared rays 8th ₂ ' the second infrared radiator shipped. From the knowledge of when the first or when the second infrared radiator radiates, then can be closed to the respective origin of the reflected infrared radiation, so that the received infrared radiation 8th'' in its components 8th ₁ '' and 8th ₂ '' can be broken down. In the period after t *, for example, only a touch of one of the two operating sectors, since only the infrared radiation of the second infrared radiator 6 ₂ hits the infrared radiator. In the period after t * remains a reflection of the infrared beam 8th ₁ 'off. In this respect, regarding the operating sector 3 ₁ no more contact detected.

LIST OF REFERENCE NUMBERS

1

input element

2

user interface

3

operating sector

4

finger

5

detector unit

6

infrared Heaters

7

infrared sensor

8th

infrared radiation

9

detector housing

10

Shop window

D

detector plane

A

display level

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

• EP 2229617 B1 [0004]

Claims (12)

Input element ( 1 ) for a data processing arrangement, comprising a user interface ( 2 ), whereby the user interface ( 2 ) into a plurality of operating sectors ( 3 ), whereby, based on a touch of one of the operating sectors ( 3 ) by a control body ( 4 ), in particular a finger or stylus, an operating sector ( 3 ) location-related operating signal is generated, characterized in that each operating sector ( 3 ) a detector unit ( 5 ) each with an infrared radiator ( 6 ), for the defined emission of infrared radiation, and an infrared sensor ( 7 ), the associated infrared radiator ( 6 ) the associated operating sector ( 3 ) with infrared radiation ( 8th' ), wherein the infrared radiation from the operating body ( 4 ) is reflected, if the operating body ( 4 ) the operating sector ( 3 ) and that on the operating body ( 4 ) reflected infrared radiation ( 8th'' ) of the associated infrared sensor ( 7 ), which represents the operating sector ( 3 ) is detected, and that the input element ( 1 ) as a function of the detected reflected infrared radiation ( 8th'' ) generates the location-related operating signal. Input element according to the preceding claim, characterized in that the detector units ( 5 ) largely parallel to the user interface ( 2 ) behind the user interface ( 2 ) are arranged. Input element according to one of the preceding claims, characterized in that the detector units ( 5 ) on a common detector housing ( 9 ), wherein the detector housing ( 9 ) with a separately formed to the detector housing disc ( 9 ), in particular a shop window, on which the user interface ( 2 ) is arranged. Input element according to one of the preceding claims, characterized in that the infrared radiators ( 6 ) and / or the infrared sensors ( 7 ) pivotable relative to the user interface ( 2 ) are held. Input element according to the preceding claim, characterized in that the infrared radiators ( 6 ) and / or the infrared sensors ( 7 ) together with the detector housing ( 9 ) are pivotally mounted relative to the user interface. Input element according to claim 4 or 5, characterized in that individual infrared radiators ( 6 ) and / or individual infrared sensors ( 7 ) of the same detector units ( 5 ) are held pivotally to each other. Interactive screen comprising an input element ( 1 ) according to one of the preceding claims, as well as means for outputting an image through the user interface ( 2 ) through. Method for operating an input element ( 1 ) for a data processing arrangement or an interactive screen, which comprises such an input element, wherein the input element ( 1 ) comprises: a user interface ( 2 ), whereby the user interface ( 2 ) into a plurality of operating sectors ( 3 ), whereby a touch of an operating sector ( 3 ) by a control body ( 4 ), in particular a finger or a stylus, a location-based on the operating sector control signal is generated, each operating sector ( 3 ) a detector unit ( 5 ) each with an infrared radiator ( 6 ), for the defined emission of infrared radiation, and an infrared sensor ( 7 ), characterized in that the operating sectors ( 3 ) by an infrared radiator ( 6 ), which represents the operating sector ( 6 ), defined with infrared radiation ( 8th' ) are irradiated, that the infrared radiation at the user interface ( 8th'' ) from a control body ( 4 ) is reflected, if the operating body ( 4 ) the operating sector ( 3 ) that an infrared sensor ( 7 ), which represents the operating sector ( 6 ) associated with the operating body ( 4 ) reflected infrared radiation ( 8th'' ) and that the input element ( 1 ) as a function of the detected reflected infrared radiation ( 8th'' ) generates the location-related operating signal. Method according to the preceding claim, characterized in that the infrared radiators ( 6 ) of adjacent detector units ( 5 ) Infrared radiation ( 8th' ) with different characteristics. Method according to the preceding claim, characterized in that the different characteristic is achieved by different wavelengths. A method according to claim 8 to 10, characterized in that the different characteristics by different pulse shapes, in particular pulse shapes and / or clock frequency of the infrared radiation is achieved. Method according to one of claims 8 to 11, characterized in that due to differences in runtime conclusions on movements of the operating body ( 4 ) to be pulled.

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