JP2007156044A - Spontaneous light emission display device, gray scale value/deterioration rate conversion table update device, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To calculate variation in deterioration rate (deterioration speed) due to display of an input gray scale value in real time through a measured value of a dummy pixel. <P>SOLUTION: The dummy pixel and a detection sensor which detects its light emission luminance are arranged outside an effective display region. In this case, the dummy pixel is continuously brought into light emission control based fundamentally upon mean gray scale values calculated by basic light emission colors. At a measurement timing point of deterioration information, on the other hand, the dummy pixel is brought under light emission control based upon previously set gray scale values. At this time, transition of the light emission luminance measured by the detection sensor in each measurement timing of the deterioration information is found to find deterioration information of light emission characteristics between measurement timings. Then a measured deterioration rate corresponding to an average gray scale value found in a measurement timing period is calculated based upon the average gray scale value and deterioration information corresponding thereto. At the same time, measured deterioration rates for all gray scale values other than the average gray scale value are calculated by referring to a basic table containing basic correspondence relation between gray scale values and deterioration rates. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

The invention described in this specification relates to a technique for updating a gradation value / deterioration rate conversion table referred to for calculating deterioration information of each pixel.
The invention proposed by the inventors has aspects such as a self-luminous display device, a gradation value / deterioration rate conversion table update device, and a program.

  Flat panel displays are widely used in computer displays, portable terminals, television receivers and other electronic devices. At present, liquid crystal display panels are mainly used for flat panel displays. However, it has been pointed out that the liquid crystal display panel still has a narrow viewing angle and a slow response speed.

For this reason, the appearance of a flat panel display replacing the liquid crystal display panel is expected.
The most promising candidate is an organic EL display panel in which organic EL elements are arranged in a matrix. The organic EL display panel not only has a good viewing angle and responsiveness, but also has excellent characteristics such as no backlight, high brightness, and high contrast.

By the way, it is generally known that the self-luminous elements constituting the organic EL display panel have a characteristic of deteriorating in proportion to the light emission amount and time.
On the other hand, the content of the image displayed on the flat panel display is not uniform. For this reason, deterioration of the light emitter (organic EL element) is likely to partially proceed. For example, the light emitter located in the time display area is more rapidly deteriorated than the light emitters in the other display areas.

The luminance of the light-emitting body that has deteriorated is relatively lowered as compared with the luminance of other display areas. In general, this phenomenon is called “burn-in”. Hereinafter, partial deterioration of the light emitter is referred to as “burn-in”.
Various methods have been proposed for improving “burn-in”. In order to correct burn-in with high accuracy and high performance, it is necessary to correctly detect the actual deterioration state of the light emitter.

Therefore, all the measures for improving the burn-in performed without detecting the deterioration state merely suppress the occurrence of the burn-in.
JP 2003-228329 A JP 2000-132139 A JP 2003-509728 A

  Among these, Patent Literature 1 and Patent Literature 2 disclose a technique for predicting a deterioration state of a light emitter by an integrated value of input display data (gradation value) and correcting the input display data based on the prediction result. That is, these patent documents disclose a technique for correcting burn-in based on a predicted value of deterioration characteristics. For this reason, there is a possibility that burn-in will not be eliminated even after correction based on the prediction result.

  The main factor is that the deterioration characteristics of the light emitter cannot be uniformly determined only by the input gradation value. For example, various conditions such as the surrounding environment, the driving method, the luminance condition, the heat generation condition, and the degree of deterioration have a complicated influence. Moreover, it is necessary to consider individual errors between organic EL display panels. Thus, it is virtually impossible to predict the deterioration state of the light emitter by accurately associating all the conditions.

On the other hand, in the technique disclosed in Patent Document 3, the deterioration characteristics of the light emitter can be detected with high accuracy by the light detection element arranged in the pixel circuit. However, disposing a correction circuit using a photodetection element for each pixel increases the number of transistors per pixel, which is disadvantageous in reducing production yield and increasing resolution.
In addition, the method disclosed in Patent Document 3 has a correction method that only compensates for deteriorated luminance. As a result, the deterioration is promoted, and there is a problem that the limit of correction performance and the luminance half-life come relatively early. is there.

  Therefore, the inventors have shown the gradation value / deterioration rate conversion table to be referred to when measuring the deterioration state of the light emitter (when calculating the deterioration amount of each pixel or the deterioration amount difference between pixels) as the processing function shown below. We propose a method of updating through The display panel here uses a dummy pixel for each basic light emission color that constitutes an effective display area, and a detection sensor that detects the light emission luminance of the dummy pixel outside the effective display area.

(A) While the dummy pixels are continuously controlled to emit light with the average gradation value calculated in units of frames for each basic emission color, the dummy pixels are controlled to emit light with the preset gradation values at the actual measurement timing of the deterioration information. Pixel light emission control unit (b) Deterioration information actual measurement unit (c) for obtaining deterioration information between the actual measurement timings by obtaining the transition of the emission luminance measured by the detection sensor for each basic emission color at each measurement timing of the deterioration information. Based on the average gradation value for each basic emission color and the corresponding deterioration information for the displayed image, the actual deterioration rate corresponding to the average gradation value is calculated for each basic emission color, and the gradation value and deterioration Measured deterioration rate calculation unit that calculates the measured deterioration rate for all gradation values other than the average gradation value for each basic emission color by referring to the basic table that defines the basic correspondence relationship with the rate

According to the invention proposed by the inventors, it is possible to accurately predict the deterioration state of all the light emitters constituting the display panel through the actually measured values of the dummy pixels. That is, the change in the deterioration rate (deterioration speed) due to the display of the input gradation value can be calculated in real time through the actual measurement value of the dummy pixel.
As a result, not only the prior experiment can be greatly reduced, but the prediction accuracy of the actual deterioration state can be further improved. Further, in the invention proposed by the inventors, the arrangement of dummy pixels and detection sensors necessary for measurement of the degradation state is advantageous for application to actual products without manufacturing restrictions.

Hereinafter, embodiments of the self-luminous display device according to the invention will be described.
In addition, the well-known or well-known technique of the said technical field is applied to the part which is not specifically illustrated or described in this specification.
Moreover, the form example demonstrated below is one form example of invention, Comprising: It is not limited to these.

(A) Functional Configuration of Organic EL Display Device FIG. 1 shows a functional configuration example of an organic EL display device equipped with a gradation / degradation amount conversion table update function.
An organic EL display device 1 shown in FIG. 1 includes a video signal conversion unit 3, a deterioration amount calculation unit 5, a gradation / deterioration amount conversion table 7, a cumulative deterioration amount difference calculation unit 9, a cumulative deterioration amount difference accumulation unit 11, and a correction amount. The determination unit 13, the self-luminous panel 15, the dummy pixel light emission detection unit 17, the deterioration amount actual measurement unit 19, the average gradation value (APL: average picture level) calculation unit 21, the conversion table update unit 23, and the dummy pixel light emission control unit 25 Constitute.

  The video signal converter 3 is a processing device that converts an input display data signal into a corrected display data signal. In the case of this embodiment, the video signal converter 3 executes a process of adding / subtracting a correction value to / from the input display data signal. The correction value is given from the correction amount determination unit 13. Further, the display data signal for the dummy pixel provided from the dummy pixel light emission control unit 23 is multiplexed with the corrected display data signal. The corrected display data signal is given to the deterioration amount calculation unit 5, the self-luminous panel 15, and the APL calculation unit 21.

  The deterioration amount calculation unit 5 is a processing device that calculates the deterioration amount of each pixel associated with image display based on the gradation value corresponding to each pixel. In this embodiment, the gradation / degradation amount conversion table 7 is used. FIG. 2 shows an example of the gradation / degradation amount conversion table 7. The gradation / degradation amount conversion table 7 stores all gradation values that can be taken by the input display data signal and the degradation amounts corresponding to these gradation values. The deterioration amount R is given as a product of the deterioration rate (deterioration rate) corresponding to each gradation value and the light emission period t. The light emission period t may be fixed or variable.

The cumulative deterioration amount difference calculation unit 9 is a processing device that calculates a cumulative value of a deterioration amount difference newly generated between a certain reference pixel and each pixel in the effective display area. The reference pixel may be a real pixel or a virtually set pixel. The former includes, for example, a pixel having the smallest cumulative deterioration amount in pixel units and a pixel having the largest cumulative deterioration amount in pixel units. The latter includes a virtual pixel that emits light with an average gradation value of one frame.
The cumulative deterioration amount difference calculation unit 9 calculates a difference between the deterioration amount of the reference pixel and the deterioration amount of each pixel for each frame, and adds the difference to the cumulative deterioration amount difference for each pixel calculated up to the previous period. To do.

The accumulated deterioration amount difference accumulation unit 11 is a storage area or a storage device that stores the accumulated deterioration amount difference of each pixel with respect to the reference pixel. The cumulative deterioration amount difference represents the degree of progress (whether advanced or delayed) of the deterioration of a certain pixel with respect to the reference pixel and the degree of progress.
The correction amount determination unit 13 is a processing device that determines a correction value to be given to the video signal conversion unit 3 for each pixel. The correction amount determination method in the correction amount determination unit 13 includes a method of determining a correction value so as to eliminate the deterioration amount difference, and a method of determining the correction value so that visual luminance differences are uniform.

The self light emitting panel 15 is a display device in which light emitters (self light emitting elements) are arranged in a matrix on a base. In the case of this embodiment, an organic EL element is used as the light emitter.
FIG. 3 shows a plan configuration example of the self-light-emitting panel 15. Note that FIG. 3 is mainly illustrated from the viewpoint of pixel arrangement, and the drive circuit and other peripheral circuits are omitted.
As shown in FIG. 3, the self-luminous panel 15 has a configuration in which dummy pixels 153 are arranged outside the effective display area 151. The effective display area 151 is an area that can be observed from the outside, and displays an image corresponding to the input image data signal. In the case of this example, the effective display area 151 uses three colors of red (R), green (G), and blue (B) as basic emission colors.

On the other hand, the dummy pixel 153 is shielded so that the light source light is not output to the outside. In the case of this example, one dummy pixel 153 is arranged corresponding to each of the basic emission colors constituting the effective display area 151. That is, three for RGB are arranged.
The dummy pixels 153 are controlled to emit light with display data signals for dummy pixels corresponding to red (R), green (G), and blue (B).
In the case of FIG. 3, the number of drive signal lines newly arranged for driving the dummy pixels 153 is only one of the gate drive lines. The data drive line is shared with the effective display area 151.

In this embodiment, the dummy pixel 153 is driven to emit light by using a blanking period of display timing. Thus, the dummy pixel 153 does not require a dedicated or large-scale driving circuit.
The dummy pixel 153 has the same structure as the pixel circuit corresponding to each pixel in the effective display area 151. That is, it is composed of a selection transistor and a drive transistor. Therefore, the difficulty in production of the display panel itself and an increase in cost hardly occur.

The dummy pixel light emission detection unit 17 is a light detection element that detects visible light output from the dummy pixel 153 and converts it into an electrical signal, and is disposed at a position facing the light emission surface of the dummy pixel 153. In the case of this embodiment, one is arranged for each basic emission color, that is, a total of three are arranged.
In general, any detection sensor is applied to the light detection element. However, a visible light sensor using an amorphous silicon semiconductor is desirable, and light amount information detected as a current value is amplified, converted into a voltage value, and output as a detection signal.

The degradation amount actual measurement unit 19 provides the dummy pixel light emission control unit 25 with a timing (measurement timing) for detecting the degradation state of the dummy pixel 153 and a display data signal (gradation value) applied to the dummy pixel 153 at the detection timing. It is a processing device. In the case of this embodiment, the detection of the deterioration state is executed at a constant cycle (every fixed number of frames). Further, the same gradation value is always used for detection of the deterioration state. By illuminating the dummy pixel 153 with the same gradation value, it becomes possible to detect the deterioration of the light emitter as the transition of the light emission luminance.
Note that the gradation value given to the dummy pixel light emission control unit 25 by the deterioration amount actual measurement unit 19 may be set for each RGB, or the same value may be used for any of RGB. For example, a 100% gradation value (“255” when the gradation is 8 bits) is used.

Further, the deterioration amount actual measurement unit 19 uses the difference ΔR between the light emission luminance detected immediately before and the light emission luminance detected this time as the deterioration information generated between the previous detection timing and the current detection timing. It also functions as a processing device given to the calculation unit 231.
It should be noted that the deterioration amount actual measurement unit 19 also provides the actual deterioration rate calculation unit 231 with the time required for degradation of the dummy pixels 153 (in this example, a fixed value).
Of course, when the deterioration amount measurement unit 19 calculates the deterioration rate between the actual measurement timings, only the calculation result is given to the actual measurement deterioration rate calculation unit 231. The deterioration rate is given as a deterioration amount per unit time. Therefore, ΔR can be obtained by dividing by the number of frames between detection timings.

The APL calculating unit 21 calculates the average gradation value for each RGB pixel for each frame of the corrected display data signal, and the average value of the average gradation values for each RGB pixel calculated in the past (hereinafter referred to as “average APL value”). And a processing device that executes a process of calculating.
The average gradation value for each RGB pixel calculated for each frame is given to the dummy pixel light emission control unit 25. The average APL value is given to the conversion table update unit 23.

The conversion table update unit 23 recalculates the current values of the deterioration rates corresponding to all the gradation values based on the deterioration rates actually measured for each RGB pixel and the average APL value of the corrected display data signal during the detection period. It is a processing device that executes processing and processing for calculating a deterioration amount corresponding to each gradation value based on the deterioration rate calculated for all gradation values.
In this specification, the former processing function is referred to as an actually measured deterioration rate calculation unit 231.

  The dummy pixel light emission control unit 25 is a processing device that controls light emission of the dummy pixel 153. The dummy pixel light emission control unit 25 outputs the average gradation value of each frame calculated by the APL calculation unit 21 for each RGB in a period other than the timing of actually measuring the deterioration state of the dummy pixel 153. In addition, the dummy pixel light emission control unit 25 outputs the fixed gradation value for deterioration state detection calculated by the deterioration amount measurement unit 19 for each RGB at the timing of actually measuring the deterioration state of the dummy pixel 153.

(B) Deterioration characteristic correction operation and gradation / deterioration rate conversion table update operation Next, a processing operation executed in the organic EL display device 1 will be described.
When the input image is displayed, the input display data signal corresponding to the organic display area 151 is subjected to correction processing by the video signal conversion unit 3 and then given to the light-emitting panel 15 as a corrected display data signal.
At this time, the APL calculation unit 21 calculates the average gradation value of each frame for each of the RGB, and provides the calculated value to the dummy pixel light emission control unit 25.

  The dummy pixel light emission control unit 25 gives the average gradation value given from the APL calculation unit 21 to the video signal conversion unit 3 as a display data signal for the dummy pixel, unless it is the detection period of the deterioration state of the dummy pixel 153. As a result, the light emission of the dummy pixel 153 for the R pixel is controlled with the average gradation value of all the R pixels constituting the immediately preceding frame. The light emission of the dummy pixel 153 for the G pixel is controlled by the average gradation value of all the G pixels constituting the immediately preceding frame. Similarly, the light emission of the dummy pixel 153 for the B pixel is controlled by the average gradation value of all the B pixels constituting the immediately preceding frame.

FIG. 4 shows an example of a display data signal for the dummy pixel 53 output from the dummy pixel light emission control unit 25 to the video signal conversion unit 3. As a result, each dummy pixel 153 emits light in the same state as each RGB pixel in the effective display area 151. That is, if an individual error between pixels is ignored, the deterioration proceeds in the same manner as in the effective display area.
Eventually, when the deterioration state of the dummy pixel comes to the detection timing, the dummy pixel light emission control unit 25 uses the gradation value for inspection given from the deterioration amount actual measurement unit 19 as the display data signal for the dummy pixel, and the video signal conversion unit 3. To give. FIG. 4 shows a state where a gradation value of 100% is given to the detection timing.

The deterioration amount actual measurement unit 19 inputs information on the emission luminance detected at the detection timing through the dummy pixel light emission detection unit 17.
FIG. 5 shows a transition example of the detection result. In the figure, the luminance indicated by a black circle is the detected value. As shown by connecting the black circles with a solid line, it can be seen that the detected light emission luminance decreases despite the fact that light is emitted at the same 100% gradation value. However, FIG. 5 exaggerates the decrease in luminance, and it is gradually reduced.

The degradation amount actual measurement unit 19 calculates a difference ΔR from the immediately preceding detection value every time the emission luminance of the dummy pixel is newly detected.
FIG. 5 shows how the difference ΔR is obtained for the light emission times t5 and t6.
When the difference ΔR is calculated, the deterioration amount actual measurement unit 19 calculates the change rate of the deterioration amount between the detection timings, that is, the deterioration rate.
FIG. 6 shows the calculation principle of the deterioration rate. FIG. 6 shows a case where the detection luminance at the previous detection timing t (n) is 90% and the detection luminance at the current detection timing t (n + 1) is 85%.

Therefore, the difference ΔR is 5%. Further, assuming that the number of frames between the detection timings t (n) and t (n + 1) is F, the deterioration amount actual measurement unit 19 calculates the deterioration rate corresponding to the RGB pixels as ΔR / F, respectively.
This deterioration rate is given to the conversion table update unit 23 from the deterioration amount actual measurement unit 19.
At this time, the conversion table update unit 23 is also given an average APL value for each RGB pixel between the detection timings from the APL calculation unit 21. In the case of FIG. 6, the average APL is 100 (when the gradation value is 8 bits) in gradation value conversion.

Thus, when the deterioration rate and the average APL value of the immediately preceding detection period are obtained, the actual measurement relationship between the current gradation value and the deterioration rate in the self-light-emitting panel 15 is determined. Since this correspondence is an actual measurement value, the correspondence reflects the content of the display image, the usage environment, and the like. This correspondence relationship accurately represents the current situation between the average APL value and the deterioration rate (deterioration amount).
However, this actually measured is only one of 256 correspondences (when gradation is given by 8 bits).
Therefore, in order to accurately predict the deterioration rate (deterioration amount) corresponding to all input gradation values, it is necessary to calculate the current deterioration rate (actual deterioration rate) for all other gradation values. .

The actually measured deterioration rate calculation unit 231 calculates this correspondence using the basic correspondence between the gradation value and the deterioration rate shown in FIG. The reason for referring to the basic correspondence relationship is that the measured correspondence relationship and other correspondence relationships basically maintain the relationship shown in FIG. 7 even if the actual measurement value of the deterioration rate corresponding to the gradation value changes. Because it is. The basic correspondence shown in FIG. 7 is stored in the measured deterioration rate calculation unit 231 as basic table information.
FIG. 8 shows the principle of calculation of the deterioration rate corresponding to all gradation values by the actually measured deterioration rate calculation unit 231.

Figure 8 is actually measured relationship is 100 gradation values (when the gradation is expressed by 8 bits) represents the actual deterioration rate at that time as X _100. At this time, the actually measured deterioration rate X _a corresponding to the arbitrary gradation value a is obtained by multiplying the actually measured deterioration rate X ₁₀₀ by the ratio α _a / α ₁₀₀ between the deterioration rates specified through the basic table curve shown in FIG. Can be calculated.
As a result, a new correspondence relationship amplified by the deterioration rate (degradation speed) is calculated while maintaining the basic correspondence relationship between the gradation values.

When the actual deterioration rate X _a corresponding to all the gradation values is calculated, the conversion table update unit 23 updates the gradation / deterioration amount conversion table 7 with these values. The deterioration amount is calculated as a product of the actually measured deterioration rate _Xa and the light emission period t. FIG. 10 shows how the deterioration rate is updated for all the gradation values constituting the gradation / degradation amount conversion table 7.
Incidentally, the shorter the detection period (cycle) is, the more generally it can cope with a sudden change in the tendency of the display image. Therefore, the error of the predicted deterioration amount can be reduced accordingly.

(C) Effect As described above, when the dummy pixels 153 corresponding to RGB are arranged outside the effective display area 151, each dummy pixel emits light with the average gradation value of the corresponding emission color. Control to adjust the dummy pixel to the same degree of progress as the degradation in the effective display area. Then, based on periodically detected deterioration information of dummy pixels, the relationship between the gradation value and the deterioration rate (deterioration amount) at the current time point is calculated and updated, so that the signal is also displayed on the panel structure. The prediction accuracy of deterioration information can be improved within a practical range in terms of processing.

That is, no matter how large the screen size is, the structure for detecting the amount of light for all pixels is not required, and the three dummy pixels 153 to be arranged are also on the extension line of the normal panel process (panel process). Can be created with little change.
Further, the dummy pixel light emission detection unit 17 may be disposed only in the dummy pixel 153 portion. Therefore, even if various characteristic variations and manufacturing variations are taken into consideration, the yield and manufacturing cost are hardly affected. That is, a structural load on the self-luminous panel is small, and a structure suitable for commercialization can be realized.

If only the relative basic relationship between the gradation value and the deterioration rate (deterioration speed) is known, the correspondence relationship of the gradation / deterioration rate conversion table can be updated based on one actual measurement value.
For this reason, it is possible to significantly reduce the amount of information to be grasped in advance experiments, and in this respect also, it is possible to realize a significant reduction in manufacturing costs.

FIG. 11 and FIG. 12 schematically show problems that are improved by the processing operation described above.
FIG. 11 shows an operation result when the correction operation is executed so that the deterioration amount of each pixel matches the deterioration amount of the reference pixel within the correction period. The solid line and the broken line in the figure are correction results when the method shown in Patent Document 1 is adopted. The solid line indicates the actual deterioration characteristic, and the broken line is the deterioration characteristic grasped in a state where the prediction accuracy is poor.

  When it is determined that the deterioration of the correction target pixel (broken line) is advanced by 5% with respect to the deterioration of the reference pixel to be matched (broken line), the method disclosed in Patent Document 1 and the like uses the predicted correction period. A control operation that stops light emission of the correction target pixel is executed. As indicated by the broken line, the deterioration characteristic of the correction target pixel should match the deterioration characteristic of the reference pixel at the end of the correction period.

However, when the deterioration characteristic prediction accuracy is poor and the difference in deterioration amount between the correction target pixel and the reference pixel at the start of correction is actually 3% as indicated by the solid line in FIG. 11, the emission of the correction target pixel is stopped. Thus, at the end of the correction period, the deterioration of the reference pixel proceeds in contrast to the correction start time. Thus, if there is a problem in the prediction accuracy of the deterioration amount, the correction operation cannot exhibit the original effect (improving burn-in).
However, if the method proposed by the inventors is adopted, the prediction accuracy of the deterioration amount is greatly improved, so that the deterioration amount of the correction target pixel can be accurately matched to the deterioration amount of the reference pixel, Image sticking can be improved at the end of correction.

  On the other hand, FIG. 12 shows an operation result in the case where the correction operation is executed so that the light emission luminance of each visually recognized pixel matches the light emission luminance of the reference pixel. The solid line and the broken line in the figure are also correction results when the method shown in Patent Document 1 is adopted. The solid line indicates the actual deterioration characteristic, and the broken line is the deterioration characteristic grasped in a state where the prediction accuracy is poor.

  FIG. 12 also shows a case where it is determined that the deterioration of the correction target pixel (broken line) is advanced by 5% with respect to the deterioration of the reference pixel (broken line) to be matched. In this case, according to the method disclosed in Patent Document 1 or the like, a control operation is performed to increase the light emission luminance of the correction target pixel by 5%. As indicated by the broken line, the light emission luminance of the correction target pixel should match the light emission luminance of the reference pixel by executing this correction operation.

However, when the prediction accuracy of the deterioration characteristic is poor and the difference in deterioration amount between the correction target pixel and the reference pixel at the start of correction is actually 3% as indicated by a solid line in FIG. 12, the emission luminance of the correction target pixel is 5%. When it is raised, it becomes 2% larger than the light emission luminance of the reference pixel. Thus, if there is a problem in the prediction accuracy of the deterioration amount, the correction operation cannot exhibit the original effect (improving burn-in).
Also in this case, if the method proposed by the inventors is adopted, the prediction accuracy of the deterioration amount is greatly improved, so that the emission luminance of the correction target pixel can be accurately adjusted to the emission luminance of the reference pixel. The burn-in can be improved at the end of the correction.

(D) Other Embodiments (a) In the above embodiment, the case where the basic emission colors are three colors of RGB has been described. However, the basic emission colors can also be applied to the case of four or more colors including complementary colors. In this case, the dummy pixels 153 and the like need only be prepared for the number of basic emission colors.
(B) In the above-described embodiment, the color generation form of the basic light emission color has not been described. However, an organic EL element having a different light emitting element material for each basic light emission color may be prepared. It may be used to generate a basic emission color.

(C) In the above-described embodiment, a case has been described in which three dummy pixels (a set of dummy pixels) corresponding to one pixel on the display are arranged on the self-luminous panel. In the case of FIG. 3, the case where one gate drive line is newly added for driving the dummy pixels has been described.
However, an optimal number of data drive lines and gate drive lines may be added according to the number and arrangement of dummy pixels.
(D) In the above-described embodiment, the organic EL display panel is illustrated as an example of the self-luminous display device, but the present invention can also be applied to other self-luminous display devices. For example, the present invention can be applied to FED (field emission display), inorganic EL display panel, LED panel, and the like.

(E) In the above-described embodiment, the organic EL display device 1 that implements the update function of the gradation / deterioration rate conversion table 7 has been described.
However, the update function of the gradation / deterioration rate conversion table 7 may be implemented as a part of an image processing apparatus equipped with a self-luminous display device. For example, the update function of the gradation / deterioration rate conversion table 7 includes a video camera, a digital camera, and other imaging devices (including not only a camera unit but also a configuration integrated with a recording device), an information processing terminal ( It may be mounted on a portable computer, a cellular phone, a portable game machine, an electronic notebook, etc.), a game machine, a printer device, or the like.

(F) In the above-described embodiment, the organic EL display device 1 that implements the update function of the gradation / deterioration rate conversion table 7 has been described.
However, the update function of the gradation / deterioration rate conversion table 7 may be installed in an image processing device that supplies an input display data signal to a self-luminous display device or an image processing device equipped with the self-luminous display device. In other words, a method may be employed in which the light emission luminance and deterioration information of the dummy pixels are taken into the self device from the self light emitting display device.

(G) In the above-described embodiment, the update function of the gradation / deterioration rate conversion table 7 has been described from the viewpoint of the functional configuration, but it goes without saying that an equivalent function can be realized as hardware or software.
Further, not only all of these processing functions are realized by hardware or software, but some of them may be realized by using hardware or software. That is, a combination of hardware and software may be used.
(H) Various modifications can be considered for the above-described embodiments within the scope of the gist of the invention. Various modifications and applications created or combined based on the description of the present specification are also conceivable.

It is a figure which shows the function structural example of the self-light-emitting device carrying the update function of a gradation / degradation amount conversion table. It is a figure which shows the structural example of a gradation / degradation amount conversion table. It is a figure which shows the plane structural example of a display panel. It is a figure which shows the light emission control example of a dummy pixel. It is a figure which shows the example of transition of the degradation characteristic about a dummy pixel. It is a figure explaining the measurement principle of a deterioration rate. It is a figure which shows the example of a basic correspondence relationship referred at the time of calculation of an actual deterioration rate. It is a figure which shows the calculation principle of the actual deterioration rate which referred the basic correspondence. It is a figure explaining the relationship between the deterioration rates on a basic table. It is a figure explaining the update operation | movement of a gradation / degradation amount conversion table. It is a figure explaining the reverse image sticking phenomenon which generate | occur | produces with the conventional method. It is a figure explaining the reverse image sticking phenomenon which generate | occur | produces with the conventional method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 3 Video signal conversion part 5 Deterioration amount calculation part 7 Gradation / deterioration amount conversion table 9 Cumulative deterioration amount difference calculation part 11 Cumulative deterioration amount difference accumulation part 13 Correction amount determination part 15 Self-light emitting panel 151 Effective display area 153 Dummy pixel 17 Dummy Pixel light emission detection unit 19 Degradation amount actual measurement unit 21 APL calculation unit 23 Conversion table update unit 231 Actual degradation rate calculation unit 25 Dummy pixel light emission control unit

Claims (6)

A display panel in which a dummy pixel for each basic light emission color constituting an effective display area and a detection sensor for detecting the light emission luminance of the dummy pixel are arranged outside the effective display area;
While the dummy pixel is continuously controlled to emit light with an average gradation value calculated in units of frames for each basic emission color, the dummy pixel is controlled to emit light with a preset gradation value at the actual measurement timing of deterioration information. A light emission control unit;
A deterioration information actual measurement unit that obtains a transition of light emission luminance measured by the detection sensor for each basic emission color at each measurement timing of the deterioration information, and obtains deterioration information between the actual measurement timings;
Based on the average gradation value for each basic emission color related to the image displayed during the actual measurement timing and the deterioration information corresponding thereto, the actual deterioration rate corresponding to the average gradation value is calculated for each basic emission color, An actual deterioration rate calculation unit that calculates an actual deterioration rate for all gradation values other than the average gradation value for each basic emission color by referring to a basic table that defines a basic correspondence relationship between the gradation value and the deterioration rate. And a self-luminous display device. The self-luminous display device according to claim 1,
The measured deterioration rate calculation unit
A correspondence ratio α _q / α _p between the deterioration rate α _p corresponding to the average gradation value p on the basic table and the deterioration rate α _q corresponding to the gradation value q to be calculated is expressed as an average gradation value. from multiplying the actual degradation rate X _p corresponding to p, the self-luminous display device characterized by calculating the actual degradation rate for all tone values other than the mean gray level. The self-luminous display device according to claim 1,
A deterioration information calculation unit that calculates deterioration information associated with display of the input image for each pixel based on the correspondence relationship between the gradation value calculated by the actual measurement deterioration rate calculation unit and the actual measurement deterioration rate;
A correction amount determination unit that determines a correction amount for each pixel so that the difference between the cumulative deterioration information about the reference pixel and the cumulative deterioration information of each pixel is resolved within the correction period;
A self-luminous display device, comprising: a video signal conversion unit that corrects an input gradation value based on the calculated correction amount. The self-luminous display device according to claim 1,
A deterioration information calculation unit that calculates deterioration information associated with display of the input image for each pixel based on the correspondence relationship between the gradation value calculated by the actual measurement deterioration rate calculation unit and the actual measurement deterioration rate;
A correction amount determination unit that determines a correction amount for each pixel so as to eliminate a luminance difference generated through a difference between the cumulative deterioration information about the reference pixel and the cumulative deterioration information of each pixel;
A self-luminous display device, comprising: a video signal conversion unit that corrects an input gradation value based on the calculated correction amount. Reference for calculation of deterioration information of each pixel when dummy pixels for each basic emission color constituting the effective display area and a detection sensor for detecting the emission luminance of the dummy pixel are arranged outside the effective display area An apparatus for updating a gradation value / deterioration rate conversion table,
While the dummy pixels are continuously controlled to emit light with an average gradation value calculated for each basic emission color, the dummy pixels are controlled to emit light with a preset gradation value at the actual measurement timing of deterioration information. A pixel light emission control unit;
A deterioration information actual measurement unit that obtains a transition of light emission luminance measured by the detection sensor for each basic emission color at each measurement timing of the deterioration information, and obtains deterioration information between the actual measurement timings;
Based on the average gradation value for each basic emission color related to the image displayed during the actual measurement timing and the deterioration information corresponding thereto, the actual deterioration rate corresponding to the average gradation value is calculated for each basic emission color, An actual deterioration rate calculation unit that calculates an actual deterioration rate for all gradation values other than the average gradation value for each basic emission color by referring to a basic table that defines a basic correspondence relationship between the gradation value and the deterioration rate. And a gradation value / deterioration rate conversion table update device. Reference for calculation of deterioration information of each pixel when dummy pixels for each basic emission color constituting the effective display area and a detection sensor for detecting the emission luminance of the dummy pixel are arranged outside the effective display area A computer program for updating a gradation value / degradation rate conversion table
While the dummy pixels are continuously controlled to emit light with an average gradation value calculated for each basic emission color, the dummy pixels are controlled to emit light with a preset gradation value at the actual measurement timing of deterioration information. Pixel light emission control processing;
A deterioration information actual measurement process for obtaining a transition of light emission luminance measured by the detection sensor for each basic light emission color for each measurement timing of the deterioration information, and obtaining deterioration information between the actual measurement timings,
Based on the average gradation value for each basic emission color related to the image displayed during the actual measurement timing and the deterioration information corresponding thereto, the actual deterioration rate corresponding to the average gradation value is calculated for each basic emission color, Measured deterioration rate calculation processing for calculating the measured deterioration rate for all the gradation values other than the average gradation value for each basic emission color by referring to the basic table that defines the basic correspondence relationship between the gradation value and the deterioration rate A computer program that causes a computer to execute and.