DE10138004A1 - Display device with an organic electro-luminescent display, especially for public transport use, has improved compensation of pixel brightness irregularities in the screen due to improved identification of such pixels - Google Patents

Abstract

Display device has a display (1) with a light material layer and a transparent substrate (2) as well as control means for controlling the appearance of the light material layer. At least a part of the light transmitted by the light layer is reflected from the outer surface (11) of the substrate and reflected within the substrate until it reaches a perpendicular end surface (5). Here a sensor (6) is used to measure the light intensity originating from pixel elements (3, 4) with control of the display taking into account the measurements. An Independent claim is made for a method for controlling an organic electro-luminescent display whereby display brightness differences are compensated.

Description

The invention relates to a display device and a Method for controlling a display device especially for a vehicle according to the generic terms of Claims 1 and 9.

State of the art

EL displays (displays with a electroluminescent layer) already known. Since For many years, inorganic EL displays have been used for Display functions used, e.g. B. in medical technology or for example on the ICE1 trains. For several years now also organic EL displays (Organic Light Emitting Display = OLED) used, e.g. B. in car radios and mobile phones. The general advantage of EL technology is that a very good contrast over the entire reading angle and over a wide temperature range with extremely short Switching times can be realized. Inorganic EL displays however, have the disadvantage of being comparatively high Control voltage of regularly greater than 180 V. This disadvantage can be achieved by using organic EL displays Avoid (OLED).

Problematic is with EL displays and especially with organic EL displays also that brightness individual segments or image points non-uniformities can have.

To compensate for this effect is in Japanese Laid-open publication JP-2000122598 A a method described, in which the brightness of all image segments or Pixels over a table before the actual use of the display is corrected.

Object and advantages of the invention

The invention is based, the possibilities a correction of differences in brightness when active Light emitting displays, especially EL displays too expand.

This object is achieved by the features of claims 1 and 10 solved.

In the subclaims are advantageous and expedient Developments of the invention specified.

The invention is initially based on a display device, especially for vehicles consisting of a light emitting display that has a phosphor layer and a transparent substrate, preferably a glass substrate or includes plastic and control means for control the phosphor layer, the display being designed in this way is that part of that from the phosphor layer emitted light in the transparent substrate Reflection, preferably total reflection on at least one Surface side of the substrate at an angle to that Surface side of the substrate standing transverse surface, for. B. an end face is forwarded. The essence of the invention is now in that at least one light sensor for measurement the intensity of the light transmitted to the transverse surface the luminescent layer of picture elements is provided, and the Control means are designed to control the Image elements of the display indicate the measurement of the light intensity the transverse area for the respective picture elements consider. Relating to a procedure for the Control of a display device is the essential Aspect of the invention in that the intensity of the Fluorescent layer emitted by picture elements and for Transverse area of light measured and depending on measured intensity value of the respective picture elements Conclusion on changes in the luminosity of this Picture elements is drawn, and that on this basis a Control of the picture elements to bring about the desired luminosity. Usually they will Picture elements are present in the form of picture elements of a matrix. However, it can also involve larger areas of different shapes Act picture elements. The procedure according to the invention is based on the knowledge that especially EL Displays don't just matter, the unevenness of the Brightness of picture elements before the actual one Correct usage recording, but above all that through aging effects of the EL layers, of which in particular Dimensions of organic EL layers are affected, one Brightness correction even during regular operation of an EL display should be possible. The also plays Viewpoint a role that frequently controlled pixels age faster, d. H. an age-related loss of brightness occurs as rarely used pixels. These effects are furthermore depending on different Influencing factors, including temperature and let therefore, if at all, only incompletely about one compensate the computed model.

Due to the possibility of ongoing measurements of the brightness of Pixels of a z. B. EL displays can to such time-changing processes by a constant Correction of the corresponding control data can be reacted to. The The transparent substrate of the display is used as a light guide used, the otherwise undesirable to transverse surfaces scattered light that is reflected further in the display is used to draw conclusions about the brightness of individual To be able to draw pixels.

This way it also becomes possible at color-capable, light-emitting displays by the Combination of several different lighting elements can represent different colors, a compensation unwanted color shifts by measuring the Brightness of individual picture elements, preferably picture elements, to be able to perform. Not only that Homogeneity of colors, but also a desired one Achieve color rendering. For example, the Light intensity for at least two different colors emitting picture elements determined and with setpoints for the light intensity of the picture elements at the respective Color control can be compared. Based on this Comparison can then be made with the help of accordingly designed control means corrected control variables for the respective color representation can be determined.

As a transverse surface on which a brightness determination is performed, an end face of the substrate be used. It is particularly the case with plastic substrates however also possible, e.g. B. a V-shaped recess in To provide edge area of the substrate to light that Surfaces of the V-shaped recess is coupled out measure up.

In a particularly simple embodiment of the invention to place a light sensor directly on a transverse surface, e.g. B. on an end face of the transparent substrate for measurement arrange the light intensity.

In a further particularly preferred embodiment of the Invention can the transverse surface, for. B. the end face of the Substrate via light decoupling means also with a Light sensor are connected. In this way, the Light sensor at a point further away from the display be accommodated, possibly with regard to structural requirements can be an advantage.

In a particularly preferred embodiment of the invention are the control means for carrying out a Gray value adjustment of individual or all picture elements on the Basis of that measured by the light sensor on the transverse surface Light designed for the respective picture element. To this Way, the light-emitting display can be made by a corresponding adjustment of control data of the control means on z. B. an essentially homogeneous light brightness can be set.

In a particularly advantageous embodiment of the invention the control means are intended for this, initially for all Picture elements, e.g. B. matrix pixels, the display desired conditions for the respective picture elements Determine light intensity via the light sensor (Determination of reference value), running by means of the light sensor Carry out measurements for the individual picture elements and a correction of control data of the control means if the current values for the Light intensity from measured reference intensity values differentiate to a desired light intensity to reach. In this way it is sufficient e.g. B. at the End face of a substrate for a matrix display punctually to attach a light sensor, over which then the brightness of all matrix pixels can be corrected. The Light intensity that a pixel depends on its Position on the substrate to the light sensor can "deliver" if necessary also determined in a computational model be so that a correction of control data does not occur based on measured reference intensity values, but calculated reference intensity values.

Furthermore, it is preferred if the reference values for the Light intensity stored in a first virtual table be that based on the following Measurements a second virtual table with corrected Values and that with the correction values the Control data of the control means are adjusted so that the individual picture elements, e.g. B. Matrix pixels Show desired, preferably the same brightness.

The ongoing measurement of the light intensity of individual pixels can be done in different ways.

A very simple procedure is used to measure the Light intensity of individual pixels alternately single pixel and the rest of the image are shown.

However, it is also possible to measure the Light intensity of individual pixels the image display in (n + 2) time units is divided that in the n Units of time the given image is shown, but the to measuring pixel is omitted and in the (n + 1) th Unit of time shown a black image and with the sensor the related brightness for ambient light compensation is determined, and that in the (n + 2) th time unit of the measuring pixel and its light intensity at Sensor is determined.

In order to increase the reliability of such measurements, further suggested that for the respective pixels Average values from a multiple measurement are used.

drawings

Several embodiments of the invention are in the Drawings are shown and below with further details Advantages and details explained. Show it

Fig. 1, an EL display in a perspective simplified view,

Fig. 2 is a sectional view of the EL display device of FIG. 1 for clarity of the light beam path,

Fig. 3 is a block diagram of the control unit with a schematically illustrated EL display and

4 is a timing diagram of driving signals with which the determination of the light intensity will be illustrated by individual pixels of FIG..

Description of the embodiments

In Fig. 1, an EL display 1 is illustrated a display device in a greatly simplified form, in perspective view, comprising a transparent substrate 2 on which a matrix of light-emitting phosphor is disposed with 3.6 pixels by way of example. In Fig. 1 five pixels 3 are driven, the remaining pixels 4 are dark. A light sensor 6 is provided on the end face 5 of the substrate 2 .

The light sensor 6 is advantageously embodied as a photodiode which, when suitably connected, supplies an electrical signal which has good proportionality to the incident luminous flux and also has a high spectral bandwidth. The light sensor can be attached directly to the substrate 2 or optically coupled to a printed circuit board via a light guide (not shown), optionally with light deflection.

The transparent substrate 2 is usually made of glass. However, it can also be implemented in plastic, which has the advantage that a light guide for coupling the light into the sensor 6 can be formed in one piece with the substrate.

Fig. 2 shows the basic light beam path in the substrate 2. The pixels 3 , 4 made of light-emitting phosphor are arranged on the underside of the substrate 2 . Some of the light beams 6 , 7 , 8 , which are emitted by a driven active pixel 3 , emerge from the substrate and can be perceived by the viewer of the display 1 . However, part 10 does not leave substrate 2 because the angle of total reflection is exceeded at its front interface 11 . For these beams 10, the substrate 2 acts as a light guide, some of these beams being passed on to the sensor 6 and converted there into electrical signals 12 .

Fig. 3 shows the block diagram of the drive unit 20 with EL display 1. The signals from the light sensor 6 are converted into voltage signals in a transimpedance amplifier 21 and filtered in a bandpass filter 22 . Then the filtered voltage signals are correlated with the control signals for the display 1 in a correlation unit 23 and the signals of the pixel (s) to be measured are isolated from the brightness signals of the other pixels and the environment. This process is advantageously carried out by the system controller 24 using software. The brightness signals of the individual pixels 25 are evaluated with the aid of a sensitivity table 26 and a brightness table 27 is created therefrom which is used to correct all pixels for the same brightness. With corrected values, the display 1 is controlled via the pixel matrix driver 28 , which is set up to display different brightness levels (gray values).

Various methods are conceivable for specifically measuring the brightness of the individual pixels 25 .

An easy way is to turn on the Systems to generate a test pattern, in which one alternates measuring single pixel and the rest of the image becomes. With normal frame rates of at least 100 Hz, this can ten within two seconds of 20 points Individual measurements can be carried out.

A more universal method will be explained in more detail using the pulse diagram according to FIG. 4. A display with n lines is preferably multiplexed in (n + 2) time units. The selection pulses 30 of the lines for a normal image display are designated Z1 to Zn. This means that in n time units, the normal image is shown, which is written line by line. However, the pixel to be measured is omitted. In the (n + 1) th time unit, a black image is written in and the intensity value measured on the sensor (dark value as reference). In the (n + 2) th time unit, the pixel to be measured is finally activated and the light intensity that is set is determined on sensor 6 . The measuring cycles are illustrated by the bracket labeled 31. This measurement is repeated 32 times with the corresponding multiplex rate, for example, and the individual results are averaged in order to further suppress extraneous light and other interference. Then the measurement is carried out with the next pixel etc., etc. This measurement is not visible to the viewer and can therefore be used continuously for all pixels that are activated at the time in question. Even with several thousand pixels, the measurement can be repeated more quickly than changes occur due to aging effects.

This method can be varied as desired and also with others Characteristic data (e.g. known temperature response of brightness) be linked.

Furthermore, the components can optionally be partially discrete built up and partly in a microcontroller software can be realized or alternatively in an intelligent Display driver IC can be integrated.

The additional hardware effort compared to one conventional EL, OELD control can be best case on a photodiode and one in the controller Reduce integrated simple amplifier circuit.

Claims (14)

1. Display device, in particular for a vehicle, with a light-emitting display ( 1 ), which comprises a phosphor layer and a transparent substrate ( 2 ), and control means ( 21 , 22 , 23 , 24 , 28 ) for controlling the phosphor layer, the Display is designed in such a way that part of the light emitted by the phosphor layer in the transparent substrate ( 2 ) by reflection on at least one surface side ( 11 ) of the substrate ( 2 ) to a transverse surface ( 5 ) at an angle to the surface side ( 11 ) of the substrate is forwarded, characterized in that at least one light sensor ( 6 ) is provided for measuring the light intensity of the light ( 10 ) of the phosphor layer of image elements ( 3 , 5 ) passed on to the transverse surface ( 5 ) and the control means (21, 22, 23, 24 28) are designed to control the measurement of the light intensity on the transverse surface ( 5 ) for the control of the picture elements ( 3 , 4 ) of the display to consider the respective picture elements. 2. Display device according to claim 1, characterized in that the light sensor ( 6 ) is arranged directly on the transverse surface ( 5 ) of the transparent substrate. 3. Display device according to one of the preceding claims, characterized in that the transverse surface ( 5 ) of the transparent substrate ( 2 ) is connected to a light sensor ( 5 ) via coupling-out means. 4. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) for performing a gray value adjustment of individual or all picture elements ( 3 , 4 ) on the basis of the on the transverse surface ( 5 ) from Light sensor measured light ( 10 ) are designed for the respective picture element ( 3 , 4 ). 5. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) are designed to determine the light intensity for at least two differently colored picture elements of a color-capable display, with setpoints for the light intensity compare with corresponding control data, and make a color correction on this basis. 6. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) are designed, first for all picture elements ( 3 , 4 ) of the display ( 1 ) under desired conditions for the respective To determine image elements ( 3 , 4 ) the light intensity at the light sensor ( 6 ) (reference value determination), to carry out current measurements for the individual image elements ( 3 , 4 ) by means of the light sensor ( 6 ), and to correct the control data of the control means ( 21 , 22 , 23 , 24 , 28 ) if the current values for the light intensity differ from the measured reference intensity values. 7. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) are designed such that the reference values for the light intensity can be stored in a first virtual table that on the basis of the following Measurements a second virtual table with correction values can be created, and that the control data of the control means ( 21 , 22 , 23 , 24 , 28 ) can be adjusted with the correction values such that the individual picture elements ( 3 , 4 ) show the desired brightness. 8. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) are designed such that for measuring the light intensity of individual picture elements ( 3 , 4 ) alternately a single picture element ( 3 , 4 ) and the rest of the picture can be displayed. 9. Display device according to one of the preceding claims, characterized in that the control means ( 21 , 22 , 23 , 24 , 28 ) are designed such that, for measuring the light intensity of individual pixels, the image display in (n) lines in (n + 2) Time units can be divided so that the (normal) image can be displayed in (n) time units when the picture element to be measured is omitted and the brightness can be determined in the (n + 1) th time unit with the sensor, and that (n + 2) ten time unit, the picture element to be measured can be controlled and its light intensity can be determined at the sensor. 10. Method for controlling a display device, in particular for a vehicle, with a light-emitting display ( 1 ) which comprises a phosphor layer and a transparent substrate ( 2 ) and with control means ( 21 , 22 , 23 , 24 , 28 ) for control of the phosphor layer, wherein part of the light ( 10 ) emitted by the phosphor layer in the transparent substrate is transmitted by reflection to a transverse surface ( 5 ) at an angle to a surface side ( 11 ) of the substrate, characterized in that the intensity of the phosphor layer light ( 19 ) emitted by picture elements ( 3 , 4 ) and reached the transverse surface ( 5 ) and, depending on the measured intensity value of the respective picture elements, a conclusion is drawn about changes in the luminosity of these picture elements ( 3 , 4 ), and on this basis a control of the picture elements ( 3 , 4 ) to bring about a desired L luminosity is made. 11. The method according to claim 10, characterized in that for all picture elements ( 3 , 4 ) of the display ( 1 ) under desired conditions for the respective picture elements ( 3 , 4 ), the light intensity is determined via at least one light sensor ( 6 ) (reference value determination ) that current measurements for the individual picture elements ( 3 , 4 ) are carried out by means of the light sensor ( 6 ) and that control data of the control means ( 21 , 22 , 23 , 24 , 28 ) is corrected when the current values change for the light intensity from reference intensity values. 12. The method according to claim 10 or 11, characterized in that the reference values for the light intensity are stored in a first virtual table, that on this basis a second virtual table with correction values is created by subsequent measurements and that the control data of the control means with the correction values ( 21 , 22 , 23 , 24 , 28 ) are adjusted so that the individual picture elements ( 3 , 4 ) show the desired brightness. 13. The method according to any one of claims 10 to 12, characterized in that for measuring the light intensity of individual picture elements ( 3 , 4 ) an individual picture element ( 3 , 4 ) and the remaining image are alternately displayed. 14. The method according to any one of claims 10 to 13, characterized in that for measuring the light intensity of individual picture elements ( 3 , 4 ), the image display is divided into (n + 2) time units, that the "normal" image is shown in (n) time units and the picture element to be measured is omitted and a black image is displayed in the (n + 1) th time unit and the brightness is determined by means of the sensor and that in the (n + 2) th time unit the picture element to be measured is driven and its light intensity by means of the sensor ( 6 ) is determined.