JP2003280591A - Organic electroluminescence display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an EL display device reducing variation in emitted light brightness as the temperature changes. <P>SOLUTION: A brightness calculation part 42 calculates a time-integral value of the brightness component of a data signal, and a temperature calculation part 46 calculates an estimated temperature of the display device 10 based on this time-integral value. When the estimated temperature with ambient temperature taken into consideration tends to increase, a correction part 50 adjusts the data signal so as to suppress the emitted light brightness, and supplies the data signal to a D-A converter 54. Although a light emitting part 20 has a brightness-temperature characteristic increasing the emitted light brightness as the temperature rises, it is made possible for the light emitting part 20 to emit light with the set brightness by adjusting the data signal to suppress an increase in the emitted light brightness caused by a rise in temperature. The light emission is suppressed less than the set brightness, the life of the element has not to be deteriorated. Contrarily, the estimated temperature with the ambient temperature taken into consideration tends to decrease, the correction part 50 adjusts the data signal to increase the emitted light brightness. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an organic electroluminescence display device, and more particularly to a technique for adjusting the emission brightness of an optical element.

[0002]

2. Description of the Related Art Organic electroluminescence display devices (hereinafter also referred to as "organic EL display devices") are self-luminous and thus have a wider viewing angle than liquid crystal display devices. Yes, in the near future,
It is drawing attention as an alternative to liquid crystal display devices. Generally, an organic electroluminescence element (hereinafter also referred to as “organic EL element”) included in an organic EL display device includes an electron injected from an electron injection electrode into an electron transport layer and a hole injected from a hole injection electrode into a hole transport layer. However, light is emitted by recombination in the interface between the organic light emitting layer and the hole transport layer or inside the organic light emitting layer near the interface. An organic EL element for color display is manufactured by depositing an organic material that emits red, green, and blue to form organic light emitting layers of a plurality of colors.

[0003]

However, it is a fact that many problems remain to be overcome in order to popularize this organic EL display device. One of them has a problem of heat generation of the organic EL display device.

The organic EL element is driven by an electric current,
Not all the electric current contributes to the light emission, and in fact, a part of the electric current generates heat. On the other hand, paying attention to the brightness-temperature characteristics of the organic EL element, the organic EL element tends to have higher emission brightness as the temperature rises. Therefore, when an image is displayed, the temperature of the organic EL display device rises, and as a result of the temperature rise, the organic EL element emits light with a brightness higher than the set brightness. This phenomenon is
This is a factor that causes deterioration of the L element itself and shortens the life of the organic EL element, and is therefore one of the problems to be solved for practical use. On the other hand, when the ambient temperature sharply drops, the emission brightness becomes lower than the set brightness, which causes a problem that the screen display becomes difficult to see.

Therefore, an object of the present invention is to provide an organic EL display device which can solve the above problems.

[0006]

In order to solve the above-mentioned problems, an aspect of the present invention is directed to a light emitting portion having a plurality of optical elements each emitting a predetermined color, and a luminance for time-integrating the luminance component of a data signal. A calculation unit, a temperature calculation unit that calculates and obtains an estimated temperature of the light emitting unit based on the time integral value of the brightness component, and a correction unit that adjusts the correction amount of the brightness component based on the estimated temperature. Provided is an organic electroluminescence display device. Here, the optical element is an organic light emitting diode (OLED).
May be The brightness component is data indicating the set brightness of the optical element. According to this aspect, by estimating the temperature of the light emitting unit, the brightness of the data signal is suppressed so as to suppress the phenomenon that the light emitting unit emits light exceeding the set brightness due to the temperature rise and the phenomenon that the light emitting unit emits light below the set brightness due to the temperature decrease. It is possible to adjust the components. Compared with the case where a thermometer or the like is provided in the organic layer of each optical element to measure the temperature of the light emitting unit and the luminance component of the data signal is adjusted, in this embodiment, the temperature is estimated by calculation processing, It is not necessary to build an element such as a thermometer, and the circuit scale can be reduced. Further, it is very difficult to provide the thermometer in the organic layer of the optical element because the circuit structure becomes complicated, and it is very difficult to measure the temperature of the light emitting portion with such a thermometer.

The brightness calculation section has a brightness addition section for calculating the sum of brightness components for each color in a data signal for one frame, and a brightness integration section for summing the sum of brightness components for each color for a plurality of frames. Good. The temperature calculation unit may calculate the estimated temperature based on the brightness-temperature characteristics of the optical element measured in advance for each color. Generally, the brightness-temperature characteristics of the optical element are different for each color, so it is preferable to calculate the estimated temperature in consideration of the difference in the characteristics. In addition, the estimated temperature may be calculated using the brightness-temperature characteristics of the light emitting unit generated based on the brightness-temperature characteristics of the optical element. Further, it is preferable that the correction unit adjusts the correction amount of the brightness component of the data signal so as to change the light emission brightness of the light emitting unit according to the change amount of the estimated temperature. This makes it possible to maintain the emission brightness at the set brightness.

The organic electroluminescence display device may further include a thermometer for measuring the ambient temperature of the light emitting section, and the temperature computing section may compute the estimated temperature using the ambient temperature. The temperature calculation unit is a temperature rise amount of the light emitting unit estimated based on the time integration value of the luminance component,
By using the ambient temperature measured by the thermometer, it is possible to more accurately estimate the temperature of the light emitting unit.

Any combination or rearrangement of the above components is also effective as an aspect of the present invention.

[0010]

1 shows the structure of an organic EL display device 10 according to an embodiment of the present invention. The organic EL display device 10 includes a light emitting unit 20 that displays an image, a driving unit 30 that drives the light emitting unit 20, and a thermometer 80 that measures the ambient temperature of the light emitting unit 20. The light emitting unit 20 includes a plurality of optical elements 22a to 22n (hereinafter, may be represented by reference numeral "22") that emit light of a predetermined color, and these optical elements 22 are red (R) and green. It may be an organic light emitting diode that emits light of each of (G) and blue (B). Each optical element 22 emits light with a brightness according to the amplitude of the analog signal supplied from the drive unit 30.

The drive section 30 includes a data signal supply section 40, a brightness calculation section 42, a memory 44, a temperature calculation section 46, a characteristic storage section 48, a correction section 50, a timing control section 52 and a DA.
It has a converter 54. The data signal supply unit 40 supplies an input data signal. This data signal is sent to the light emitting unit 2
0 is a video signal forming an image displayed at 0, and may be supplied from the outside through an antenna (not shown) provided in the organic EL display device 10.
Inside the L display device 10, an MPU (Micro Processing
Unit) or the like.

This data signal is supplied to the brightness calculation section 42. The brightness calculation unit 42 time-integrates the brightness component of the data signal. The timing control unit 52 supplies a timing signal for instructing the integration timing of the brightness component to the brightness calculation unit 42. Details of the brightness calculation unit 42 will be described with reference to FIG.

FIG. 2 shows the internal structure of the brightness calculator 42. The brightness calculation unit 42 has a brightness addition unit 60 and a brightness integration unit 70. The brightness adding unit 60 is the R brightness adding unit 6
2, including a G brightness addition unit 64 and a B brightness addition unit 66,
The sum of the luminance components for each color in the data signal for one frame is calculated. Specifically, the R luminance adding unit 62 obtains the total sum of the red luminance components in one frame, and similarly, G
The luminance adding unit 64 obtains the sum of green luminance components, and the B luminance adding unit 66 obtains the sum of blue luminance components. The sum of the luminance components for one frame of each color is recorded in the memory 44. Upon receiving the data signal for one frame, the luminance adding unit 60 obtains the sum of the luminance components of the respective colors and records it in the memory 44.

The brightness integrating unit 70 includes an R brightness integrating unit 72, G
The brightness integration unit 74 and the B brightness integration unit 76 are included, and the sum of the brightness components for each color over a plurality of frames is integrated in the time direction. Specifically, the R luminance integrating unit 72 integrates the sum of the red luminance components, similarly, the G luminance integrating unit 74 calculates the sum of the green luminance components, and the B luminance integrating unit 76 calculates the sum of the blue luminance components. Add up each. The brightness integration unit 70 may perform integration based on the timing signal supplied from the timing control unit 52, and may add up the sum of the brightness components of a predetermined number of consecutive frames, or a predetermined number thinned out at regular intervals. You may add up the sum total of the luminance component of a frame. In the latter case, it is preferable that the luminance adding unit 60 also records only the total sum of the luminance components of the frames thinned out at regular intervals in the memory 44 in order to reduce the used capacity of the memory 44.

The brightness accumulating section 70 needs to sequentially integrate the total sum of the recorded brightness components so that the memory 44 does not overflow. Therefore, the brightness integrating unit 70
Each time the total sum of the luminance components is recorded in the memory 44, the total sum is added up, and when the number of times of addition reaches a predetermined number, the integrated value is supplied to the temperature calculation unit 46. Good. At this time, it is preferable that the integrated value supplied to the temperature calculation unit 46 be subjected to processing such as time averaging according to the calculation processing method of the temperature calculation unit 46.

Returning to FIG. 1, the characteristic storage section 48 holds the first luminance-temperature characteristic of the optical element itself measured in advance for each color. Further, the characteristic storage unit 48 holds the second luminance-temperature characteristic for each color when the light emitting unit 20 is configured as a panel. The second brightness-temperature characteristic is set including the influence of the housing and the like when it is formed into a panel, and even if the screen lighting rate in consideration of the emission brightness and the emission area is used as the brightness component. Good. The second brightness-temperature characteristic may be expressed in the form of a function or a table for each color. Further, the second luminance-temperature characteristic of each color may be aggregated to set the third luminance-temperature characteristic of the entire light emitting unit 20, and even in this case, this characteristic has a function or table format. It is preferably expressed by.

The temperature calculating section 46 calculates and obtains the estimated temperature of the light emitting section 20 based on the time integral value of the luminance component.
At this time, the temperature calculation unit 46 calculates the estimated temperature by using a function or a table stored in the characteristic storage unit 48 and expressing the first to third luminance-temperature characteristics.

In order to facilitate understanding, the method of calculating the estimated temperature will be described using the simplest example. The temperature rise degree of each of the RGB colors at the same emission brightness is represented by Tr: Tg:
When the relationship of Tb (hereinafter, Tr, Tg, and Tb are referred to as temperature coefficients) is established, the temperature calculation unit 46 causes the brightness calculation unit 42.
The brightness integrated value of each of the RGB colors supplied from is multiplied by the temperature coefficient of each color. Then, the temperature calculation unit 46 calculates the estimated temperature of the light emitting unit 20 by substituting this multiplication value into the function stored in the characteristic storage unit 48 or by referring to the table using the multiplication value. The estimated temperature at this time is assumed to be a situation where the ambient temperature does not change. As described above, the temperature calculation unit 46 can perform the calculation process of the estimated temperature, but the calculation method is not limited to the above-described example, and various calculation methods can be performed based on the first to third luminance-temperature characteristics. It is easily understood by those skilled in the art that various methods can be adopted.

It is desirable that the integrated data of the brightness components supplied from the brightness calculation section 42 be easily handled by the temperature calculation section 46. When the temperature calculation unit 46 uses the brightness-temperature characteristic indicating the relationship between the light emission brightness and the temperature rise, the brightness calculation unit 42 calculates the time average value of the total brightness and the like, and the temperature calculation unit 46 May be supplied. The functions of the temperature calculation unit 46 and the brightness calculation unit 42 are realized by a calculation processing unit such as an MPU (not shown), and a circuit element such as a thermometer is added to the organic layer of each optical element 22. Since it is not realized, it is possible to estimate the temperature rise of the light emitting unit 20 without increasing the circuit scale.

The capacity of the memory 44 is preferably large enough to cope with the temperature change due to the time integration of the luminance component. For example, assuming a case where the temperature of the light emitting unit 20 reaches 45 ° C. after 5 minutes from room temperature (25 ° C.) when a white 100% image is lit, if the memory capacity is small and only the luminance component for 2 minutes can be recorded, Although the memory contents will be updated after 2 minutes, the estimated temperature is based on the integrated data for 2 minutes only. Therefore, the estimated temperature rise may be different from the actual temperature rise. In preparation for such a case, it is preferable to design the capacity of the memory 44 to be sufficiently large. If the memory capacity is small, the estimated temperature itself may be recorded in the memory 44, and the temperature calculation unit 46 may calculate a new estimated temperature using the integrated value and the recorded estimated temperature.

The thermometer 80 may measure the ambient temperature of the light emitting section 20 and supply the ambient temperature to the temperature calculating section 46. As described above, the temperature calculation unit 46 can estimate the amount of temperature increase based on the time integral value of the brightness component. However, when the change in ambient temperature is larger than the amount of temperature change due to image display, It can be said that it is difficult to estimate the accurate temperature of the light emitting unit 20. For example, when the organic EL display device 10 moves from a warm place to a cold place, the temperature of the light emitting unit 20 will decrease if the decrease in ambient temperature is larger than the increase in temperature due to image display. Therefore, the temperature calculation unit 46 may calculate and obtain the estimated temperature of the light emitting unit 20 by using the ambient temperature and the estimated temperature calculated based on the time integral value of the luminance. The thermometer 80 need only be provided at a position where the ambient temperature of the light emitting unit 20 can be measured, and need not be provided in the organic layer of the optical element 22. Further, it is sufficient that at least one thermometer 80 is provided, and it is not necessary to be provided for each optical element 22. Temperature calculator 46
Supplies the calculated estimated temperature to the correction unit 50.

The correction section 50 performs gamma correction so that the data signal matches the VT (voltage-light emission luminance) characteristics of the light emitting section 20, or adjusts the white balance by rewriting the gamma table for each RGB. It has a function of adjusting white balance by adjusting an offset value and a gain for each of RGB. The correction unit 50 corrects the brightness component of the data signal by combining these brightness adjustment functions according to the situation. The VT characteristic, gamma table, offset value, gain and the like are stored in the characteristic storage unit 48.

The correction unit 50 adjusts the correction amount of the brightness component of the data signal based on the estimated temperature calculated by the temperature calculation unit 46. The correction unit 50 adjusts the correction amount of the brightness component of the data signal so that the emission brightness of the light emitting unit 20 is changed according to the change in the estimated temperature. Even if the light emitting unit 20 after the temperature rise is supplied with the same analog signal as before the temperature rise, as compared with the light emission brightness before the temperature rise,
It tends to emit light with higher brightness than that. for that reason,
The correction unit 50 preferably adjusts the brightness component of the data signal so as to suppress the increase in the emission brightness due to the temperature rise. On the other hand, if the ambient temperature drops significantly, the light emitting unit 20 will decrease the light emitting brightness due to the decrease in temperature. Therefore, the correcting unit 50 adjusts the brightness component of the data signal so as to increase the light emitting brightness. Is preferred. By constantly performing this brightness adjustment during image display, the light emission brightness of the light emitting unit 20 can be made substantially equal to the set brightness, and a stable image display can be provided. Further, since the brightness control is performed so that the emission brightness does not exceed the set brightness, it is possible to avoid the undesirable deterioration of the organic EL element due to excessive light emission. D
The A converter 54 converts the data signal corrected by the correction unit 50 into an analog signal based on the timing signal supplied from the timing control unit 52, and then the light emitting unit 2
Output to 0.

The optical element 22 receives the analog signal and emits light with a brightness substantially equal to the set brightness. Compared to the conventional case, it is possible to reduce the degree to which the light emission luminance of the light emitting portion 20 becomes larger than the set luminance due to the temperature rise of the light emitting portion 20, so that the life of the optical element 22 is not impaired.
It is possible to maintain stable light emission characteristics for a long period of time.

Although the present invention has been described above based on the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. It is understood by those skilled in the art that the above-described embodiments are mere examples, and that various modifications can be made to the combinations of the respective constituent elements and the respective processing processes, and that such modifications are also within the scope of the present invention. This is where

[0026]

According to the present invention, it is possible to provide an EL display device in which the degree of change in the emission brightness with the temperature change of the light emitting portion is reduced.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of an organic EL display device according to an embodiment.

FIG. 2 is a diagram showing an internal configuration of a brightness calculation unit.

[Explanation of symbols]

10 ... Organic EL display device, 20 ... Light emitting unit, 22
... optical element, 30 ... drive section, 42 ... brightness calculation section, 46 ... temperature calculation section, 50 ... correction section, 60
... Luminance adding unit, 70 ... Luminance integrating unit.

─────────────────────────────────────────────────── ─── Continued Front Page (51) Int.Cl. ⁷ Identification Code FI Theme Coat (Reference) G09G 3/20 G09G 3/20 642P 670 670L H05B 33/14 H05B 33/14 A

Claims (5)

[Claims] 1. A light emitting section having a plurality of optical elements each of which emits light of a predetermined color, a brightness calculating section for time integrating a brightness component of a data signal, and a light emitting section of the light emitting section based on a time integrated value of the brightness component. An organic electroluminescence display device, comprising: a temperature calculation unit that calculates and calculates an estimated temperature; and a correction unit that adjusts a correction amount of a brightness component based on the estimated temperature. 2. The brightness calculation unit includes a brightness addition unit that calculates a sum of brightness components for each color in a data signal for one frame, and a brightness integration unit that sums a sum of brightness components for each color for a plurality of frames. The organic electroluminescence display device according to claim 1, wherein: 3. The organic electroluminescence display according to claim 1, wherein the temperature calculation unit calculates the estimated temperature based on the brightness-temperature characteristic of the optical element measured in advance for each color. apparatus. 4. The correction unit adjusts the correction amount of the brightness component of the data signal so as to change the light emission brightness of the light emitting unit in accordance with the change in the estimated temperature.
4. The organic electroluminescence display device according to any one of 3 to 3. 5. The thermometer according to claim 1, further comprising a thermometer for measuring an ambient temperature of the light emitting unit, wherein the temperature computing unit computes an estimated temperature by using the ambient temperature. The organic electroluminescence display device according to 1.