EP2580667A2 - Method and device for detecting an incorrect representation of image data on a display unit - Google Patents

Abstract

The invention relates to a method for detecting an incorrect representation of image data (B) on a display unit (10). In order to enable prompt and particularly reliable detection of an incorrect representation of image data (B) on the display unit (10), the method according to the invention occurs in such a way that the image data (B) to be displayed are transmitted to the display unit (10), test data (P) are detected by electronically detecting at least part of the image represented on the display unit (10), and an incorrect representation of the image data (B) on the display unit (10) is detected by electronically evaluating at least part of the detected test data (P). The invention further relates to a device for detecting an incorrect representation of image data (B) on a display unit (10).

Description

description

Method and device for detecting a faulty display of image data on a display unit

A faulty display of image data on a display unit, ie for example a screen, a monitor or a display, can have serious effects depending on the function of the display unit. This applies in particular to those cases where display units are used in safety-related or sicherheitskriti ^¬ rule areas. Examples include applications in the field of rail, aircraft, automotive, military, medical or energy technology, ie, for example, in nuclear power plants, called.

In general, hardware can fail due to aging, wear or foreign influence. Today's secure Sys ^¬ tems operate computerized usually being the supply was of each system on a display unit Darge ^¬ represents is. Since the operations of the personnel often depend on the information displayed on the display unit, it is necessary that errors in the display, ie a faulty state of the system, can be detected promptly and reliably.

One way to achieve this is to have redundant information in the image data to be displayed. This can be done for example in such a way that in the case of a display unit used in a railway engineering interlocking takes place, the visualization of a traveling road on the one hand by a reproduced green color on the track section and on the other hand by a next-standing, also shown in green Far ^¬ be image of a signal. Only if both Similarly, if information is present in the image displayed on the display unit, the operator can assume that the representation of the image on the display unit is correct.

However, the procedure described has the disadvantage that at least the safety-critical information in the form of corresponding image data to be displayed must be generated redundantly. Furthermore, can not be completely excluded concluded that an erroneous representation by the respective operator depending on the particular situation, if not, or only with a time delay deferrers ^¬ is detected. Furthermore, it should be noted that, for example display units in the form of customary today Liquid crystal displays (LCD, Liquid Crystal Display) are ver ^¬ tively complex structure and, for example, its own memory and its own computer unit have to have be ^¬ relationship wise. As a result, for example, there is the danger that under certain circumstances an old image of the memory can be displayed which, although taken in its own right, does not reflect the actual state of the monitored system.

The present invention has for its object to provide a method that allows a particularly reliable and at the same time timely detection of a faulty display of image data on a display unit.

This object is achieved by a method for detecting a faulty display of image data on a display unit, wherein by electronic detection ^{¬ at} least a portion of the image displayed on the display test data are detected and based on an electronic evaluation of at least part of the acquired test data a faulty representation of the image data on the display ^¬ unit is detected.

In the context of the description of the present invention, the display unit is understood to be that component which serves for the actual reproduction of the image data, ie the planar component from which a person can read or view the image represented on the basis of the image data. On the part of the display unit, the image data to be displayed can be received here, for example, by a graphics card or a graphics controller or another control unit. The component from which the Ad ^¬ geeinheit receives the to be displayed image data may be formed together with the display unit or to a common component as separate, merely communicatively connected to the display unit component.

When the image data is those informa- NEN, the part of the display unit, the input signal rela ^¬ hung as the basis for the image bil ^¬ representation. In this case, the image data are preferably a set of individual, preferably digital, data values that respectively indicate image values for individual pixels, ie pixels, of the image to be displayed.

According to the inventive method, at least a portion of the image displayed on the display unit at ^¬ are first recorded test data by electronic detection. This loading indicates that an automated detection or is performed to read back ^¬ the basis of the image data on the image displayed the display unit. Here, one hand He ^¬ grasp the entire image displayed on the display unit carried. On the other hand, it is also conceivable that only a part or several parts of the image displayed on the display unit is detected or read back respectively. This is particularly expedient if a check of the representation of the image data on the display unit is required only for selected parts or areas of the image displayed on the display unit.

A faulty representation of the image data on the display unit is then detected by means of an electronic evaluation of at least part of the acquired test data. This ^¬ be indicated that the electronically captured test data an electronic, ie in particular automated valuation are subjected and an erroneous representation of the image data is detected on the display unit on the basis of the assessment carried out.

The inventive method has the particular advantage that it is an automatic, independent of operating or monitoring personnel review of the representation of

Image data on the display unit allows. In this case, so that generated at any point in this way error can before ^¬ geous enough, the entire path of the transmission of the image to be displayed data to the display unit to eigentli ^¬ chen representation on the display unit to be checked, reliable and due to the electronic detection and evaluation also promptly can be recognized.

Preferably, the method according to the invention can be further developed in such a way that the test data are recorded by means of an electronic camera oriented on the display unit. This offers the advantage that it is by means of an out on the display unit ^¬ oriented electronic camera in which Erfas ^¬ sen of the test data to a particularly simple and comparatively inexpensive feasible method for recording the test data is. In this case, the camera can preferably be attached to the display unit itself. According to a further particularly preferred embodiment of the method according to the invention, the test data are recorded by means of photosensors arranged on the display unit. This means that the photosensors are arranged on the display unit itself, whereby a direct and distortion-free detection of the test data is made possible. ^¬ advance reduction here is that the photo sensors are arranged on the on ^¬ display unit that the picture displayed on the display unit is further recognizable.

Preferably, the inventive method may in this case be wei ^¬ terhin designed such that the test data are recorded by means of a mounted on the display unit light-transmissive photosensitive film. This is advantageous because detection of the test data for any display units is possible by means of a corresponding sensor film, without requiring an adaptation of the display units themselves. The photosensors of the photosensitive film may advantageously be independent of the size and number of pixels, ie the resolution, of the monitor. Due to the fact that a corresponding light-transmissive photo ^¬ sensitive film may be directly placed on the display unit ^¬ introduced, no focusing is advantageously required. According to another particularly preferred embodiment, the inventive method is designed such that the test data are recorded by integrated in the display unit Fo ^¬ tosensoren spatially neighboring for detecting the light from at least one of each photo-sensor th pixels of the display unit are formed. That is, according to this embodiment, the photosensors are arranged in spaces of the pixels of the display unit. In this case, the photosensors are preferably designed such that they are darkened toward the outside, ie towards the front of the display unit, and essentially exclusively detect the light of the at least one pixel spatially adjacent to the respective photosensor. This ensures insensitivity of the method to stray light. The image can be acquired or recorded by acquiring the test data with a resolution corresponding to the resolution of the display unit or else with a lower resolution. By using a display unit having integrated photosensors for detecting the check data, that is, for supplying read back of the displayed image, the advantage is achieved that further comprises a relatively flat structure of the Ad ^¬ geeinheit is made possible and, moreover, in particular egg ^¬ ne impairment of the quality of the Representation of the image data on the display unit by the recording technique, ie the photo sensors, is avoided. It is an optical Fo kussierung not he ^¬ conducive advantageously in this case.

It should be noted that at the same time several of the aforementioned possibilities for capturing the test data can be used. For example, it is conceivable for the test data to be recorded on the one hand by means of an electronic camera aligned with the display unit and, on the other hand, on the other hand, the test data also to be recorded by means of photosensors integrated in the display unit. Depending on the particular application and the particular circumstances, the quality or the speed of the electronic rating can be increased in particular by a corresponding redundant detection of the test data. According to a further particularly preferred embodiment, the method according to the invention is configured such that the electronic evaluation of the at least one part of the acquired test data comprises a comparison of the at least one part of the acquired test data with at least one part of the image data. With the aid of suitable hardware and / or software, the recorded test data or at least a part thereof can thus be compared with the respective image data. It should preferably be ensured that the hardware components used for the display of the image data and the acquisition of the test data are independent of one another in that the data used for the comparison with the image data can be given exclusively by the electronically recorded test data. If, in the comparison, which can in different ways it ^¬ follow and include, for example, a processing of the image data and / or the test data, a match is found, the display of image data on the display unit is error free; on the other hand, in the case of a deviation from a faulty representation of the image data on the display unit is assumed. The interpretation Bezie ^¬ hung as interpretation of the deviation depending on the type and purpose of illustrating the image data on the display unit may be different.

Preferably, the inventive method can also be designed in such a way, additionally or alternatively, that the electronic evaluation of the at least one part of the sensing ^¬ th test data comprises a comparison of the at least one part of the detected test data with the respective image data associated with the reference data. This is advantageous since this simplifies the comparison of the at least one part of the acquired test data with the respective image data. If certain image data occur more frequently, it is thus here It is possible to determine and record reference data for this image data, which allow a particularly simple and rapid comparison of the at least part of the acquired test data with the reference data. For this, the refer- ence data can divorce under ^¬ of the respective image data, both in terms of the data format and in terms of its content. For example, the reference data may be "target test data" determined from the corresponding image data.

According to a further particularly preferred embodiment of the method according to the invention, the electronic ^{evaluation of} the at least one part of the acquired test data comprises a content-related interpretation of the test data. This means that in the context of the electronic evaluation of the test data, as an alternative or in addition to a comparison between desired and actual, it is also possible to interpret the content of the image read back, ie the test data. In this case, as in ^¬ game as OCR (Optical Character Recognition), and / or automatic image recognition, an interpretation of the test data corresponding content examples play, by means of automatic character recognition, be made. In this case, it is thus less aimed at the representation of the image data itself, but at the information reproduced by means of the representation. This offers the advantage that using a entspre ^¬ sponding image interpretive unit, the image displayed on the display unit without knowing the concrete pi ^¬ xelgenauen image contents of the target display, ie the image data can be used to hedge technically meaningful review of representable th information , Advantageously, this is also possible in the case of complex, changing representations. According to a further particularly preferred embodiment, the method according to the invention is configured such that the detection of the test data and the electronic evaluation of the at least one part of the recorded test data is carried out continuously or at regular time intervals. This is advantageous, since in this way a faulty representation of the image data on the display unit can be detected particularly promptly. According to a further preferred development of the method according to the invention, image data to be displayed are transmitted in the form of a test pattern to the display unit. This offers the advantage that the use of test patterns facilitates electronic evaluation of at least one part of the erfass- th test data, since in this case the expected Prüfda ^¬ th are known. In addition, the use of a test pattern can also be used to test those functions of the display unit which may not be used at the given time, but may be required in possibly future situations. This can relate, for example, to the display of specific colors or the activation of specific areas of the display unit. Preferably, corresponding test patterns can re ^¬ transmitted regularly for very short times and advertising displayed to, the duration of the display may be below the perceptual ability of the human eye, preferably, so that a viewer of the display unit by the transmission of the test pattern is not or only disturbed insignificantly , By a corresponding synchronization of the transmission or display of the test pattern and the Erfas ^¬ sens or readback here the erforder ^¬ clear representation of time of the test pattern can be reduced, for example, to periods of time of less than 0.1 seconds. With regard to the device, the object of the present invention is to specify a device which ^{enables a} particularly reliable and at the same time timely recognition of a faulty display of image data on a display unit.

This object is inventively achieved by a Einrich ^¬ processing for detecting an incorrect display of image data on a display unit, the device having the display unit for displaying an image, first means for acquiring test data by electronic detecting at least a portion of the displayed on the display unit Image and second means for detecting a faulty representation of the image data on the display unit based on an electronic evaluation of at least part of the acquired test data.

The advantages of the device according to the invention essentially correspond to those of the method according to the invention, so that in this regard reference is made to the corresponding explanations above. The same applies with regard to the following preferred developments of the device according to the invention, so that reference is also made in this regard to the corresponding statements in connection with the respective preferred development of the method according to the invention.

Preferably, the device ^{according to} the invention is designed such that the first means comprise an electronic camera aligned with the display unit.

According to a further particularly preferred development of the device according to the invention, the first means comprise photosensors arranged on the display unit. Preferably, the device and the art ^¬ invention may be pronounced that the first means comprise a mounted on the display unit at ^¬ transparent photosensitive Fo ^¬ lie.

According to another particularly preferred embodiment, the inventive device is designed such that the first means comprise integrated Fo ^¬ tosensoren in the display unit, the minimum for detecting the light of to-one are formed adjacent to the respective photo-sensor spatial pixel of the display unit.

According to a particularly preferred development of the inventive device for carrying out the method of the invention or for carrying out the procedural ^¬ Rens formed in accordance with one of the aforementioned preferred embodiments of the inventive method.

In the following the invention will be explained in more detail by means of exemplary embodiments. This shows

Figure 1 is a schematic representation of a first

 Embodiment of the device according to the invention,

Figure 2 is a schematic representation of a second

 Embodiment of the device according to the invention,

Figure 3 is a schematic representation of a third

Embodiment of the device according to the invention and Figure 4 in a schematic representation for explaining an embodiment of the inventive method ^¬ on a display unit ^¬ displayed image.

For reasons of clarity, identical reference symbols are used in the figures for identical or essentially identically acting components. Figure 1 shows a schematic representation of a first

Embodiment of the device according to the invention. Shown is a display unit 10, which may be a screen, a monitor or a display. Furthermore, a control unit 20 is provided, which can be designed, for example, as a graphics card, graphic controller or other control computer. Displayed image data B are transmitted from the control unit 20 to the display unit 10, which displays or reproduces an image on the basis of the received image data B.

In order to be able to recognize a faulty representation of the image data B on the display unit 10, the device furthermore has first means for acquiring test data P in the form of a camera 30. As indicated in FIG. 1, the camera 30 is aligned with the display unit 10 in this case.

In the context of the exemplary embodiment described, it is assumed that the test data P relating to the entire image displayed on the display unit 10 is detected by means of the camera 30. The acquired test data P are transmitted from the camera 30 to the control unit 20 and subjected there to an electronic evaluation. In the context of the exemplary embodiment described here, it is assumed that with regard to the concrete use of the display unit 10 in FIG the present situation, the representation of the image only in the parts or areas 40, 50 is security-relevant or safety-critical. For this reason, the electronic evaluation of the acquired test data P takes place exclusively with respect to the test data P recorded for the parts 40, 50 of the image. Alternatively or in addition to this, it would of course also be conceivable that the test data would already be related from the outset to capture part of the picture. This could be done, for example, by ^simply aligning the camera 30 with a part of the display unit 10 or of the image displayed thereon.

The device shown in FIG. 1 as well as the method described in this context have the particular advantage that the flat image displayed on the display unit 10 is essentially detected on the basis of the test data P, as it is also seen by an operator. This means that especially those display errors that arise on the way to the display unit 10 or in the Ad ^¬ geeinheit 10 itself can be detected. In this case, the check is advantageously carried out independently of an operator of the display unit 10, the complete path being from the output of the image data B to be displayed, ie from the transmission of the image data B from the control unit 20 to the display unit 10, until the actual display on the display unit 10 the exam is included.

Preferably, the test can be carried out continuously or cyclically, ie regularly recurring. In this context, the monitoring of the representation of the image data in the context of the method advantageously relates to the target image content, ie not exclusively to the check as to whether the display image unit 10 is in principle capable of displaying image data.

In addition or optionally also as an alternative, a comprehensive functional test of the representation of the image data on the display unit 10 can be carried out by possibly only very briefly ^{taking into} play test samples. This offers the advantage that error sources, in particular also within the display unit 10 itself, can be detected or disclosed in a timely manner.

A certain disadvantage of the embodiment of the device according to the invention shown in FIG. 1 can be seen in the fact that the field of view on the display unit 10 in front of the camera 30 for a correct and reliable function of the

Procedure should be free at all times. To this end, flattest possible viewing angle of the camera 30 on the display unit to ^¬ 10 is desirable. However, this can lead to a distorted image in the geometry, so that, if necessary, an equalization of the image, recorded in the form of the test data, of the image displayed on the display unit 10 by means of subsequent image processing may become necessary. In this case, the camera 30 should preferably have a resolution that still allows an image interpretation after the image equalization.

In addition to possible distortions, in the embodiment of FIG. 1, depending on the particular circumstances, reflections on the display unit 10 may under certain circumstances also include image recognition, i. capturing the

Test data P by the camera 30 and the subsequent electro ^¬ niche evaluation of the test data P, complicate. Figure 2 shows a schematic representation of a second embodiment of the device according to the invention. In contrast to Figure 1, only a portion rela ^¬ hung as section of a display unit 10 is shown here.

In the embodiment of Figure 2, the detection of the test data by means of first means which comprise arranged on the display unit 10 photo sensors. It would be conceivable game at ^¬ that photo sensors are provided on or in a arranged in front of the display unit 10 glass. In the context of the embodiment of Figure 2 had ever ^¬ but assumed that the first means comprise an attached on the display unit 10 ^¬ transparent photosensitive film 60th The light-transmitting film 60 has Fotosenso- ren 61, 62, 63 and 64, which are arranged such that for example, the photo sensor 61 of pixels or image points 71 to 79 of the display unit surrounded 10 is rela ^¬ hung example adjacent to these. The photosensitive film or layer 60 covers part of the displayed on the display unit 10 of the Bil ^¬, so that are usually a darkening of the image content. The photocells of the photosensitive film 60 are facing the display unit 10 and therefore much less sensitive to stray light of the environment than for the light of the display unit 10, ie for the light emitted by the pixels.

In the embodiment of Figure 2, the photo sensors 61 detect to 64 are each a group of pixels beziehungswei ^¬ se pixels of the display unit 10, so that the detection of the check data by the photosensors 61 to 64 with a lower accuracy or resolution than the egg ^¬ gentliche Image output of the display unit 10 takes place. To one To ensure sufficiently reliable evaluation of misrepresentations of graphical elements on the display unit 10, the resolution of the captured image, ie the acquired test data should, if possible, be at least sufficient for a rating of approximately 10 mm ² image content (ie, information as "point"). In this case, text recognition by means of, for example, OCR is still possible, at least for fonts of correspondingly large size.

In order to avoid any impact of photosensors by lying further away pixels of the display unit, beneficial ^¬ way legally shields can be provided. This is indicated in Figure 2 by shields 81, 82, the rule in the intermediate spaces between the photo-sensors 61 and 63 and the pixels 77 and 78 or 78 and 79 are vorgese ^¬ hen.

Due to the reduced resolution of the detection of the test data, i. the smaller number of photo sensors compared to

Number of pixels, it is advantageously ensured that the image displayed on the display unit 10 is still recognizable to the operating or monitoring personnel using the display unit 10. Advantageously, the planar application of the translucent film 60 avoids distortions during image acquisition, whereby focusing for acquiring the test data is not necessary.

Preferably, a calibration of the arrangement based on the respective screen position and image geometry can be performed software ^¬ based. Here, for example, significant representations can be detected in a Lernpha ^¬ se and the positions of the respective images are stored. Figure 3 shows a schematic representation of a third embodiment of the device according to the invention. In this case, the representation of Figure 3 is substantially that of Figure 2 corresponds to give 2 the first means comprise basic difference to the embodiment of the figure in the on ^¬ display unit 10 integrated photosensors that spatially adjacent for detecting the light from at least one of each photo-sensor Pixels of the display unit 10 are formed. Specifically, in FIG. 3, photo sensors 61a to 64a are designated by way of example, which are arranged in the spaces between the pixels or pixels 71 to 79 and are integrated in the display unit 10 itself. This offers the advantage that a darkening of the displayed image is reduced or completely avoided.

In the exemplary embodiment of FIG. 3, the image data is displayed and the read or read back of the displayed image in the form of the test data advantageously takes place by means of two independent electronic processing units. This ensures that errors in the image representation do not also affect image acquisition, as would be the case, for example, in case the same processing unit is used for image output and image acquisition. Preferably, therefore, the image acquisition - with the exception of the integrated photo sensors - realized independently of the image output.

The photosensors 61a to 64a are such that they are darkened to the outside and capture only the light of the surrounding pixels. With regard to their other construction, the display unit 10 according to the exemplary embodiment of FIG. 3 can be constructed similarly to the display known from the published application US 2006/0007222 A1. However, the familiar display has the fundamental difference that the photo-sensors are oriented toward the front of the display unit out to detect as a camera, for example, the image viewer ei ^¬ nes of the relevant display unit. As part of the embodiment of Figure 3, the constitutional He ^¬ the test data can be performed with a similar resolution as the resolution of the display unit or with a lower resolution. Generally, the display unit according to the Ausführungsbei ^¬ game of Figure 3 has the advantage that the overall structure is flat and the quality of the presentation is not hindered by the technical components required to capture the test data. At the same time advantageously no focusing or complex geometrical caliber ^¬ tion is necessary, since this is already fixed by the design or construction of the display unit itself. Figure 4 shows an image displayed on a display unit image in a schematic view for explaining an embodiment of the procedural ^¬ proceedings of the invention. Specifically, an example of a representation of image data of an operational control display of an interlocking of the railway automation technology is shown here. Visible here are various tracks and switches and indicated signals.

Regardless of which of the types described in connection with the exemplary embodiments of FIGS. 1 to 3, the acquisition of the test data takes place, an electronic evaluation of the at least one part of the acquired test data is necessary in order to detect a faulty representation of the image data on the display unit can. For this purpose, preferably carried out a comparison of at least one part of the sensing ^¬ th test data with at least a portion of the image data. Alternatively or in addition to this, it is possible to interpret the content of the image read using the acquired test data.

In principle, it is desirable that the detection of the test data and the electronic ^¬ valued intervals continuously or at regular time the at least one portion of the test data. The determination of the test interval and the areas to inspect the display unit be ^¬ relationship example of the displayed image can be made dependent on the jeweili ^¬ gen application and the respective underlying risk ^¬ considerations. The test interval will generally be based on the hazard caused by a possible misrepresentation. So it is conceivable example ^¬ that the goal is to avoid incorrect image data for a time period of more than 1 second. In this case, a standard test interval of 1 second with regard to the acquisition of the test data and the subsequent electronic evaluation could be used as a basis.

As already mentioned above, the region may of be to überprüfen- set the image area in dependence on the respective An ^¬ case of use respectively determined so that the image data displayed on the display unit may comprise a mixture of to be tested and not to be tested Informatio ^¬ NEN. This advantageously avoids an excessive reaction of the system in the event that faults are detected in safety-critical uncritical areas of the display, ie the illustrated image data. By capturing or reading back the test data an interpretive interpretation of the content is provided ^¬ is possible advantageously. On the one hand, this may include text recognition, for example in the form of OCR or even a general image recognition. This offers the advantage that even without knowledge of the concrete pixel-accurate image content of the target display, ie the image data to be displayed, a fuse-technically meaningful verification of the information displayed is possible. An example of this is a speedometer unit that displays a speed on a display unit in the form ei ^¬ nes displays. Here read back the speed displayed by image analysis of the recorded Prüfda ^¬ th would make sense being only checked whether actually to be displayed to a viewer speed is recognizable bar displayed on the display unit.

By using reference data or reference image patterns assigned to the respective image data, electronic evaluation of the test data is possible with little computational effort. Here advantageously eliminates the aufwän ^¬ vivid correlation matching of image interpretation, as the comparison image is already available, matched to the Method of Erfas ^¬ sens of test data. Through the use of test patterns, the examination of the display unit can be particularly comprehensive, fast and reliable with regard to its ability to image. Here ^¬ at test patterns or test pattern image can be switched to the display unit so long that a Erfas- solution of the corresponding test data is made possible. Such a use of test samples or test images is expedient, since a currently displayed image does not ^{necessarily use} the complete display options. This means that, for example, in a normal state of a Systems a displayed image may not include the color red. So if the display option respects ^¬ Lich the color red for a long time be unused and because ei ^¬ nes fault, the corresponding display option does not work be reliably, so a regular check is useful to eg provide, as required, a warning in red to be granted ^¬ and not only to recognize in a hazardous situation that a corresponding display is not possible due to a failure.

In the context of the embodiment of Figure 4, is angenom ^¬ men that the image displayed with respect to the illustrated tracks is determined statically and Wesent ^¬ Liche for an operator information signals only by changing colors in a stable position shown picture elements ^¬ the. Thus, the respective condition of the track system is recognizable by a colored illumination of routes and signals. This makes it possible to define individual regions of the displayed image for which a check of the displayed image data is expedient or necessary. In Figure 4 this is indicated by the fact that, for example ^¬ way parts of the image displayed on the display unit are designated 90-118, is provided for a review of the Dar ^¬ position. This applies on the one hand to test areas for routes 90 to 109 and on the other hand to test areas for signals 110 to 118.

In the context of a method for detecting an incorrect display of image data on a display unit can be detected or, if the test data are recorded based on the entire displayed image, only for the relevant parts of the now only for the parts of the picture 90-118 Prüfda ^¬ th Figures 90 to 118 an electronic assessment of the recorded test data are made. In the- sem connection it should be emphasized again that the check ^¬ the parts or regions of the image, ie, the test ^¬ ranges from 90 to 109 for roadways or 110-118 for signals are indicated in Figure 4 merely exemplary, so that in practice other and / or additional test areas can be defined.

The image data transmitted from a control unit, in the form of a control ^¬ computer, to the display unit, which are shown in Figure 4, the control unit as the number of individual identifiable elements with their attributes, that is, for example, their color is known. Since the elements ^¬ se with a change of the display do not change their ^¬ positi on, but only their attributes in the context of the embodiment described an electronic Be ^¬ evaluation of the test data with respect to the respective color of the display is sufficient.

Can according to the related explanations above furthermore additionally be a review of options of the display unit by means of briefly given from ^¬ test samples which can also be referred to as a complete test images at regular time intervals.

Furthermore, it can be seen from FIG. 4 that, by evaluating text contents, for example in the lower screen area, it is also possible, for example, to check the representation of the currently released commands, provided this is appropriate for security purposes.

In addition to an application in the field of railway signaling or railway safety technology, ie, for example, in connection with control room displays of signal boxes or show in the cab of trains, the method described above, in principle, in any other fuse-related areas find application in which the reliable and timely, independent of human influence detection of a faulty display of image data on a display unit of importance.

Claims

claims

A method of detecting a misrepresentation of image data (B) on a display unit (10), wherein

- By electronic detection of at least a portion of the image displayed on the display unit (10) test data (P) are detected and

- based on an electronic evaluation of at least one

 Part of the detected test data (P) a faulty DarStellung the image data (B) on the display unit (10) is detected.

2. The method according to claim 1,

d a d u r c h e c e n c i n e s that

the test data (P) are detected by means of an electronic camera (30) aligned with the display unit (10).

3. The method according to claim 1 or 2,

d a d u r c h e c e n c i n e s that

the check data (P) by means on the display unit (10) is arranged ^¬ photo sensors (61, 62, 63, 64) are detected.

4. The method according to claim 3,

d a d u r c h e c e n c i n e s that

the test data (P) are detected by means of a light-transmissive photosensitive film (60) mounted on the display unit (10).

5. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

the check data (P) by means of the display unit (10) integ ^¬ tured photosensors (61a, 62a, 63a, 64a) are recognized from at least one of each for detecting the light Photosensor (eg 61a) spatially adjacent pixels (71, 72,

73, 74) of the display unit (10) are formed.

6. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

the electronic evaluation of the at least one part of the acquired test data (P) comprises a comparison of the at least one part of the acquired test data (P) with at least one part of the image data (B).

7. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

the electronic evaluation of the at least one part of it ^¬ summarized test data (P) includes comparing the at least one part of the detected check data (P) to the respective image data (B) associated with the reference data.

8. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

the electronic evaluation of the at least one part of it ^¬ summarized test data (P) includes an interpretation of the test data (P) content.

9. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

the detection of the check data (P) and the electronic Be ^¬ evaluation of at least one part of the detected check data (P) takes place continuously or at regular time intervals.

10. The method according to any one of the preceding claims,

d a d u r c h e c e n c i n e s that

to be displayed image data (B) in the form of a test pattern to the display unit (10) are transmitted.

11. Device for detecting a faulty display of image data (B) on a display unit (10), the device with

 the display unit (10) for displaying an image,

- First means for detecting test data (P) by electronically detecting at least a part of the on ^¬ display unit (10) represented image and

 second means for detecting a faulty representation of the image data (B) on the display unit (10) based on an electronic evaluation of at least part of the acquired test data (P).

12. Device according to claim 11,

d a d u r c h e c e n c i n e s that

the first means comprise an electronic camera (30) aligned with the display unit.

13. Device according to claim 11 or 12,

d a d u r c h e c e n c i n e s that

the first means on the display unit (10) arranged photo sensors (671, 62, 63, 64) include.

14. Device according to claim 13,

d a d u r c h e c e n c i n e s that

the first means comprise a on the display unit (10) is interrupted ^¬ te transparent photosensitive film (60).

15. Device according to one of claims 11 to 14,

d a d u r c h e c e n c i n e s that

the first means in the display unit (10) integrated Fo ^¬ tosensoren (61a, 62a, 63a, 64a) include, for detecting the light from at least one of the respective photosensor (eg 61a) spatially adjacent pixels (71, 72, 73, 74) of the display unit (10) are formed.

16. The device according to claim 11, wherein the device for carrying out the method according to one of claims 1 to 10 is designed.