JP2016009136A - Display device and manufacturing method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manufacturing method of a display device that allows luminance unevenness to be highly accurately suppressed over an entire display gradation.SOLUTION: A manufacturing method of a display device 1 having a pixel 400 inclusive of an organic EL element 402 and a drive transistor 401 arranged in a matrix manner comprises: a first step of acquiring a representative gradation-luminance characteristic common to a display unit 113 as a whole; a second step of selecting a plurality of computation gradation values not inclusive of a lower limit gradation in a display gradation range; a third step of measuring light emission luminance for each pixel in the plurality of computation gradation values and creating a computation gradation-luminance table; a fourth step of obtaining an amount of shift of the plurality of computation gradation values so that each data on the computation gradation-luminance table agrees with data on the representative gradation-luminance characteristic; and a fifth step of creating a gradation conversion table for correcting arbitrary input gradation data in the display gradation range for each pixel on the basis of correlation data on a plurality of computation gradation values before and after shifting by the amount of shift.

Description

  The present disclosure relates to a display device and a manufacturing method thereof.

  As an image display device using a current-driven light emitting element, an image display device (organic EL display) using an organic EL element is known. Since this organic EL display has the advantages of good viewing angle characteristics and low power consumption, it has been attracting attention as a next-generation FPD (Flat Panel Display) candidate.

  In an organic EL display, usually, organic EL elements constituting pixels are arranged in a matrix. In particular, in an active matrix organic EL display, a thin film transistor (TFT) is provided at the intersection of a plurality of scanning lines and a plurality of data lines. The gate of the driving transistor is connected to the TFT, the TFT is turned on through the selected scanning line, and an input gradation signal is input to the driving transistor from the data line, and the organic EL element emits light by the driving transistor. According to the above configuration, since the organic EL element can emit light until the next scanning (selection), the luminance of the display is not reduced even if the duty ratio is increased. However, in an active matrix type organic EL display, the luminance of the organic EL element differs in each pixel even if the same input gradation signal is given due to variations in characteristics of the drive transistor and the organic EL element, and luminance unevenness occurs. There is a disadvantage that it occurs.

  In a conventional organic EL display, as a method for compensating luminance unevenness due to variations in characteristics of drive transistors and organic EL elements generated in the manufacturing process (hereinafter collectively referred to as non-uniform characteristics), non-uniform characteristics are compensated for each pixel. A method has been proposed.

  In the electro-optical device, the electro-optical device driving method, the electro-optical device manufacturing method, and the electronic apparatus disclosed in Patent Document 1, the luminance of each pixel is measured with at least one type of input current in the current program pixel circuit. The The measured luminance ratio of each pixel is stored in the storage capacity, the image data is corrected based on the luminance ratio, and the current program pixel circuit is driven by the corrected image data. Thereby, uneven brightness can be suppressed and uniform display can be achieved.

JP 2005-283816 A

  However, since the organic EL display is required to eliminate the luminance unevenness over the entire display gradation range from the lowest gradation (black) to the highest gradation, the luminance unevenness correcting method described in Patent Document 1 is used. The accuracy of the luminance ratio of each pixel stored in advance in the storage capacity becomes a problem. For example, when obtaining the above luminance ratio, if there are few types of input current values or if the selection of the input current values is not appropriate, even if the luminance unevenness is eliminated in some input gradations, There arises a problem that luminance unevenness cannot be sufficiently solved over the adjustment range.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a display device and a manufacturing method thereof that can suppress luminance unevenness with high accuracy over all display gradations.

  In order to solve the above problems, a method for manufacturing a display device according to one embodiment of the present invention includes a light-emitting element and input grayscale data that determines light emission luminance of the light-emitting element. A method for manufacturing a display device having a display panel in which pixels including a driving element that supplies a driving current corresponding to tone data to the light emitting element are arranged in a matrix, and represents a correlation between input gradation and light emission luminance A first step of obtaining a representative gradation-luminance characteristic which is a gradation-luminance characteristic common to the entire display panel, which is a target for correcting the gradation-luminance characteristic for each pixel, and correcting the input gradation data A plurality of gradation values for generating a gradation conversion table to be referred to when a plurality of discrete operation levels not including a lower limit gradation in a display gradation range that is a gradation range used as an image Select key value A second step of measuring emission luminance at the plurality of discrete calculation gradation values for each pixel and creating a calculation gradation-luminance table for each pixel; and the calculation gradation-luminance The shift of the plurality of discrete calculated gradation values for each pixel so that each data corresponding to the combination of the calculated gradation value and the luminance in the table matches the data on the representative gradation-luminance characteristic Correlation data between the fourth step for determining the amount, the plurality of discrete calculated gradation values shifted by the shift amount determined in the fourth step, and the plurality of discrete calculated gradation values before the shift And a fifth step of generating, for each pixel, the gradation conversion table for correcting arbitrary input gradation data in the display gradation range.

  According to the method for manufacturing a display device according to the present invention, the number of operation gradation values used when correcting input gradation data can be made the same for each pixel. The accuracy can be suppressed.

It is a figure which shows the calculation gradation-luminance table in the conventional brightness nonuniformity compensation method. It is a block diagram which shows the electrical structure of the display apparatus which concerns on embodiment. It is a figure which shows an example of the circuit structure of the pixel which a display part has, and its connection with the peripheral circuit. It is a functional block diagram of a display device manufacturing system according to an embodiment. It is an operation | movement flowchart explaining the manufacturing method of the display apparatus which concerns on embodiment. It is a figure which shows a display gradation range and the calculation gradation-luminance table in step S30. It is a graph explaining correction | amendment of the calculation gradation value in step S40. It is a figure which shows the gradation conversion table in step S50. It is a figure which compares the correction accuracy of the display apparatus which concerns on embodiment, and the conventional display apparatus. It is a figure which shows the calculation gradation-luminance table which concerns on embodiment. 1 is an external view of a thin flat TV incorporating an organic EL display panel according to an embodiment.

(Knowledge that became the basis of the present invention)
The present inventor has found that the following problems occur with respect to the luminance unevenness compensation method for the display panel described in the “Background Art” column.

  For example, a pixel including an organic EL element and a drive transistor that supplies a drive current corresponding to the input gradation data to the organic EL element when input gradation data that determines light emission luminance of the organic EL element is supplied. As a conventional luminance unevenness compensation method in a display panel in which are arranged in a matrix, the following method is exemplified.

  First, a representative gradation-luminance characteristic common to the entire display panel, which is a target for correcting the gradation-luminance characteristic for each pixel representing the correlation between the input gradation and the emission luminance, is acquired (S51).

  Next, a plurality of calculation gradation values for generating a gradation conversion table to be referred to when correcting the input gradation data are selected (S52).

  The light emission luminance at the selected plurality of calculated gradation values is measured for each pixel, and a calculated gradation-luminance table for each pixel is created (S53).

  A plurality of calculation gradations for each pixel so that each data (calculation gradation value, luminance) of the calculation gradation-luminance table matches the data (gradation value, luminance) on the representative gradation-luminance characteristic. The value is shifted (S54).

  Generates a gradation conversion table for each pixel that corrects arbitrary input gradation data in the display gradation range based on the correlation data between the multiple calculated gradation values and the multiple calculated gradation values before the shift. (S55).

  Finally, the input gradation data reflecting the externally input video signal is corrected by the gradation conversion table, and the corrected input gradation data is supplied to each pixel (S56).

  FIG. 1 is a diagram showing a calculation gradation-luminance table in a conventional luminance unevenness compensation method. Specifically, FIG. 4 is a diagram for explaining step S53 in the above-described conventional luminance unevenness compensation method. In each pixel of the display panel, a plurality of calculation gradation values (D0, 140, 1A0, 200, 260: hexadecimal notation) are selected (S52). The gradation D0 is a lower limit gradation (black display) used as an image, and the gradation 260 is an upper limit gradation used as an image. That is, the gradation from D0 to gradation 260 is a display gradation range used as an image. Then, the light emission luminance at each calculated gradation value is measured (S53). FIG. 1 shows a calculation gradation-luminance table for the pixel P and the pixel Q.

  Here, at the calculation gradation D0 of the pixel A, the pixel luminance is measured as 0.005051. However, this measured luminance value is below the measurement lower limit value of the luminance meter, and does not reflect the exact emission luminance of the pixel P. Therefore, in the pixel P, the gradation D0 is not selected as the calculation gradation for generating the gradation conversion table of the pixel P, and four calculation gradations other than the gradation D0 are selected.

  On the other hand, in the pixel Q, since the measured pixel luminance is within the measurable range of the luminance meter at any of the five calculation gradations, the five calculation gradations are converted into the gradation conversion of the pixel Q. This is selected as a calculation gradation for generating a table.

  As described above, when a gradation conversion table for each pixel is generated based on different numbers of operation gradations, for example, the same input gradation data for all pixels is corrected for each pixel, and the corrected input gradation data Is supplied to each pixel, as shown in FIG. That is, there arises a problem that luminance unevenness cannot be effectively suppressed over the entire display panel.

  In order to solve such a problem, a method for manufacturing a display device according to one embodiment of the present invention includes a light-emitting element and input gradation data that determines light emission luminance of the light-emitting element. A manufacturing method of a display device having a display panel in which pixels including a driving element that supplies a driving current corresponding to grayscale data to the light emitting element are arranged in a matrix, wherein a correlation between input grayscale and light emission luminance is obtained. A first step of obtaining a representative gradation-luminance characteristic, which is a gradation-luminance characteristic common to the entire display panel, which is a target for correcting the gradation-luminance characteristic for each pixel to be represented; A plurality of discrete calculations for generating a gradation conversion table to be referred to when correcting, and not including a lower limit gradation in a display gradation range that is a gradation range used as an image Tone value A second step of selecting light emission luminance at the plurality of discrete calculation gradation values for each pixel, and generating a calculation gradation-luminance table for each pixel; and the calculation gradation- In the luminance table, each of the plurality of discrete calculated gradation values for each pixel such that each data corresponding to the combination of the calculated gradation value and the luminance matches the data on the representative gradation-luminance characteristic. Correlation data between a fourth step for obtaining a shift amount, the plurality of discrete computation gradation values shifted by the shift amount obtained in the fourth step, and the plurality of discrete computation gradation values before the shift And a fifth step of generating, for each pixel, the gradation conversion table for correcting arbitrary input gradation data in the display gradation range.

  According to this, a plurality of calculation gradation values used when correcting the input gradation data are extracted without including the lower limit gradation in the display gradation range, so that an effective measurement luminance value can be obtained. The number of gradation values can be made the same for each pixel. Therefore, luminance unevenness can be suppressed with high accuracy over all display gradations.

  In the second step, the same plurality of discrete calculation gradation values may be selected for all the pixels.

  As a result, the accuracy of the gradation conversion table generated by the selected plurality of calculated gradation values can be matched in all pixels.

  In the fifth step, x is a plurality of discrete calculation gradation values before the shift, y is a plurality of shifted discrete calculation gradation values, α is a correction coefficient, and β is an offset value. The gradation conversion table may be generated as a linear expression represented by y = αx + β.

  As a result, the input gradation data before correction is first multiplied by the correction coefficient α, and the offset value β is added to the multiplied value, thereby generating corrected input gradation data. Therefore, it is possible to suppress luminance unevenness with high accuracy by a simplified correction calculation process.

  In the third step, the light emission luminance at the plurality of discrete calculation gradation values is measured with a luminance meter, and in the second step, the gradation value corresponding to the minimum luminance detectable by the luminance meter is greater than or equal to the luminance value. The plurality of discrete calculation gradation values may be selected.

  As a result, the light emission luminance values measured at the selected plurality of calculated gradation values can all be values that do not include measurement errors as much as possible. Therefore, it is possible to improve the conversion accuracy of the gradation conversion table generated based on these measured light emission luminance values.

  In the first step, as the representative gradation-luminance characteristic, a representative gradation-luminance characteristic acquired in a manufacturing method of another display device manufactured under the same conditions may be used.

  Accordingly, the representative gradation-luminance characteristics obtained by the manufacturing method of one display device are used in the manufacturing method of another display device manufactured under the same conditions as the one display device, so that a plurality of display panels It is possible to save the trouble of setting the representative gradation-luminance characteristics every time the gradation conversion table is generated. As a result, the manufacturing process of the apparatus can be shortened.

  Furthermore, a sixth step of writing the gradation conversion table of each pixel generated in the fifth step into a predetermined memory may be included.

  Thus, the gradation conversion table once generated in the manufacturing process can always be used in the display operation after shipment without generating the gradation conversion table for each video display operation. Therefore, the luminance unevenness compensation process can be simplified.

  In addition, the present invention can be realized not only as a manufacturing method of a display device including such characteristic steps, but also by using a gradation conversion table generated using the characteristic steps included in the manufacturing method as means. The display device having the same effects as described above.

  Hereinafter, an embodiment of a method for manufacturing a display device will be described with reference to the drawings. Note that each of the embodiments described below shows a preferred specific example in the present disclosure. Accordingly, the numerical values, shapes, materials, components, arrangement positions and connection forms of components, steps, and order of steps shown in the following embodiments are merely examples, and are not intended to limit the present invention. Absent. Therefore, among the constituent elements in the following embodiments, constituent elements that are not described in the independent claims indicating the highest concept in the present invention are described as arbitrary constituent elements.

  Each figure is a schematic diagram and is not necessarily illustrated strictly. Moreover, in each figure, the same code | symbol is attached | subjected to the substantially same structure, The overlapping description is abbreviate | omitted or simplified.

(Embodiment)
Hereinafter, a display device and a manufacturing method thereof according to embodiments will be described with reference to the drawings.

[1. Basic configuration of display device]
FIG. 2 is a block diagram illustrating an electrical configuration of the display device according to the embodiment. The display device 1 in the figure includes a control circuit 12 and a display panel 11. The control circuit 12 has a memory 121. The display panel 11 includes a scanning line driving circuit 111, a data line driving circuit 112, and a display unit 113. Note that the memory 121 may be disposed outside the control circuit 12 in the display device 1.

  The control circuit 12 has a function of controlling the memory 121, the scanning line driving circuit 111, and the data line driving circuit 112. The memory 121 stores a gradation conversion table generated by the display device manufacturing method according to the present embodiment after the manufacturing process according to the present embodiment is completed. During the display operation, the control circuit 12 reads the gradation conversion table written in the memory 121, corrects the input gradation data reflecting the video signal input from the outside based on the gradation conversion table, and outputs the data. Output to the line drive circuit 112. In other words, the control circuit 12 functions as a correction unit that reads the gradation conversion table from the memory 121 for the video signal and corrects the input gradation data.

  In the manufacturing process, the control circuit 12 has a function of driving the display panel 11 in accordance with an instruction from the information processing apparatus by communicating with an external information processing apparatus.

  The display unit 113 includes a plurality of pixels, and displays an image based on a video signal input from the outside to the display device 1.

[2. Pixel circuit configuration]
FIG. 3 is a diagram illustrating an example of a circuit configuration of a pixel included in the display portion and connection with peripheral circuits thereof. The pixel 400 in the figure includes a scanning line 424-427, a data line 434, a driving transistor 401, an organic EL element 402, a storage capacitor element 403, a selection transistor 404, an enable transistor 405, a reference transistor 406, And an initialization transistor 407. The peripheral circuit includes a scanning line driving circuit 111 and a data line driving circuit 112.

  The scanning line driver circuit 111 is connected to the scanning lines 424 to 427, and controls conduction and non-conduction of the selection transistor 404, the enable transistor 405, the reference transistor 406, and the initialization transistor 407.

  The data line driving circuit 112 is connected to the data line 434, reflects input video signals, outputs input gradation data (input gradation voltage) for determining the light emission luminance of the organic EL element 402, and drives the transistor 401. Is determined.

The drive transistor 401 has a gate connected to the data line 434 via the selection transistor 404, a source connected to the anode of the organic EL element 402, and a drain connected to the positive power supply line (V _TFT ) via the enable transistor 405. Drive element. Accordingly, the drive transistor 401 converts the input gradation voltage into a drive current corresponding to the input gradation voltage, and supplies the converted drive current to the organic EL element 402.

The organic EL element 402 functions as a current-driven light emitting element, and the cathode of the organic EL element 402 is connected to a negative power supply line (V _EL ).

  The storage capacitor element 403 is connected between the gate and source of the drive transistor 401. For example, the storage capacitor element 403 maintains a previous gate-source voltage even after the selection transistor 404 is turned off, and continuously supplies a drive current from the drive transistor 401 to the organic EL element 402. Have.

  The selection transistor 404 is a switch transistor that has a gate connected to the scanning line 424 and controls the timing of supplying the input gradation voltage of the data line 434 to the gate of the driving transistor 401.

The enable transistor 405 is a light-emitting transistor that has a gate connected to the scanning line 425 and controls the timing of supplying the power supply voltage _VTFT of the positive power supply line to the drain of the drive transistor 401.

The reference transistor 406 has a gate connected to the scanning line 426 and is a switch transistor that controls the timing of supplying the reference voltage _VREF of the reference power supply line provided to detect the threshold voltage to the gate of the driving transistor 401. is there.

The initialization transistor 407 has a gate connected to the scanning line 427 and controls the timing of supplying the initialization voltage V _INI of the initialization power supply line to the source of the driving transistor 401.

  Although not shown in FIG. 3, the positive power supply line is connected to a power supply. The negative power supply line is connected to another power supply or grounded.

[3. Pixel circuit operation]
Next, a driving sequence of the pixel circuit shown in FIG. 3 will be described.

First, only the initialization transistor 407 is turned on, and the source potential of the drive transistor 401 is set to the initialization voltage V _INI (initialization period).

Next, the reference transistor 406 is turned on. As a result, the storage capacitor 403 is charged with a differential voltage between the reference voltage V _REF and the initialization voltage V _INI .

  Next, the initialization transistor 407 is turned off, the reference transistor 406 is kept on, and the enable transistor 405 is turned on. At this time, the drain current flows in the state where no current flows through the organic EL element 402 due to the voltage setting in the initialization period, and the source potential of the driving transistor 401 changes. The potential difference between both electrodes of the storage capacitor element 403 (the gate-source voltage of the driving transistor 401) is a potential difference corresponding to the threshold voltage Vth of the driving transistor 401. Next, the enable transistor 405 is turned off. Thereby, the supply of the drain current is stopped, and the threshold voltage detection operation is completed (threshold voltage detection period).

  Next, the reference transistor 406 is turned off and the selection transistor 404 is turned on to prepare for the write operation. In this state, the corrected input gradation voltage is applied to the first electrode of the storage capacitor element 403 through the data line 434. Accordingly, the storage capacitor element 403 is obtained by adding a voltage corresponding to the voltage difference between the corrected input gradation voltage and the reference voltage to the threshold voltage Vth of the drive transistor 401 held in the threshold voltage detection period. Is stored (held) (writing period). The corrected input gradation voltage is input gradation data corrected based on the gradation conversion table generated by the display device manufacturing method according to the present embodiment.

  The selection transistor 404, the reference transistor 406, and the initialization transistor 407 are turned off, and the enable transistor 405 is turned on. Accordingly, a drive current flows through the organic EL element 402 in accordance with the voltage stored in the storage capacitor element 403, and the organic EL element 402 emits light corresponding to the drive current (light emission period). The organic EL element 402 emits light with a light emission luminance corresponding to the corrected input gradation voltage. For example, the organic EL element 402 does not emit light at the lower limit gradation voltage (black display), and emits light at the maximum brightness at the upper limit gradation voltage.

[4. Configuration of manufacturing system]
Next, a manufacturing system that realizes the display device manufacturing method according to the present embodiment will be described.

  FIG. 4 is a functional block diagram of the display device manufacturing system according to the embodiment. The manufacturing system described in the figure includes an information processing device 2, a luminance meter 3, a display panel 11, and a control circuit 12.

  The information processing apparatus 2 includes a calculation unit 21, a storage unit 22, and a communication unit 23, and has a function of controlling a process until a gradation conversion table is generated. For example, a personal computer is applied as the information processing apparatus 2.

  The luminance meter 3 images the display panel 11 according to a control signal from the communication unit 23 of the information processing apparatus 2 and outputs the captured image data to the communication unit 23. As the luminance meter 3, for example, a CCD camera or a luminance meter is applied.

  The information processing device 2 outputs a control signal to the control circuit 12 and the luminance meter 3 in the display device 1 via the communication unit 23, acquires measurement data from the control circuit 12 and the luminance meter 3, and obtains the measurement data. The data is stored in the storage unit 22 and is calculated by the calculation unit 21 based on the stored measurement data to calculate various characteristic values and parameters. The control circuit 12 may use a control circuit that is not built in the display device 1.

  More specifically, when setting the representative gradation-luminance characteristic, the information processing apparatus 2 controls the input gradation voltage value to be applied to the measurement pixel and receives the measurement luminance value from the luminance meter 3. Further, at the time of generating a gradation-luminance table that represents the correlation between the calculated gradation and emission luminance for each pixel 400, which will be described later, the information processing device 2 controls the calculated gradation voltage value applied to the measurement pixel and the luminance meter 3 Control and receive the measured brightness value.

  The computing unit 21 computes for each pixel 400 so that each data (calculated gradation value, luminance) in the gradation-luminance table matches data (gradation value, luminance) on the representative gradation-luminance characteristic. Shift the gradation value. In addition, the calculation unit 21 sets a gradation conversion table that corrects arbitrary input gradation data in the display gradation range based on correlation data between the shifted calculated gradation value and the calculated gradation value before the shift. Generate every 400.

  The control circuit 12 controls the gradation voltage value applied to the pixel 400 included in the display panel 11 by a control signal from the information processing apparatus 2. The control circuit 12 has a function of writing the gradation conversion table generated by the information processing apparatus 2 into the memory 121.

[5. Production method]
Next, a method for manufacturing the display device according to the present embodiment will be described.

  FIG. 5 is an operation flowchart illustrating a method for manufacturing the display device according to the embodiment. In the drawing, steps until a highly accurate gradation conversion table for correcting luminance unevenness of the display panel included in the display device 1 are described are described. The high-accuracy gradation conversion table is generated in a state where the number of calculation gradation values used for correcting input gradation data is the same for each pixel. In order to generate the correction parameter, in the present manufacturing method, a plurality of calculated gradation values are selected without including the lower limit gradation in the display gradation range. Hereinafter, the manufacturing process will be described with reference to FIG.

  First, the information processing apparatus 2 acquires representative gradation-luminance characteristics that are common to the entire display unit 113 and represent the correlation between the input gradation and the light emission luminance (S10). Here, the representative gradation-luminance characteristic is a gradation-luminance characteristic that is a target for correcting the gradation-luminance characteristic representing the correlation between the input gradation of each pixel 400 and the light emission luminance. Step S10 corresponds to the first step. Specifically, representative gradation-luminance characteristics are acquired as follows.

  First, measurement pixels for determining representative gradation-luminance characteristics are extracted from a plurality of pixels included in the display unit 113. The number of pixels for measurement may be one, or may be a plurality of pixels selected according to regularity or randomly. The information processing apparatus 2 causes the control circuit 12 to apply the input gradation voltage to the measurement pixel to cause the organic EL element 402 of the pixel to emit light. Next, the information processing apparatus 2 causes the luminance meter 3 to measure the light emission luminance of the measurement pixel. The application of the input gradation voltage to the measurement pixel and the light emission luminance measurement are executed a plurality of times at different input gradation voltage values. Note that the application of the input gradation voltage to the measurement pixel and the emission luminance measurement may be performed simultaneously for a plurality of measurement pixels, or may be repeatedly performed for each measurement pixel. As a result, the information processing device 2 obtains the gradation-luminance characteristics for each measurement pixel in the calculation unit 21. Next, the information processing apparatus 2 obtains the representative gradation-luminance characteristics by averaging the gradation-luminance characteristics obtained for each of the plurality of measurement pixels.

  Since the representative gradation-luminance characteristic acquisition process does not measure the current of all pixels included in the display unit 113, the emission luminance is measured only for a plurality of measurement pixels. The time required to set the representative gradation-luminance characteristics can be greatly shortened.

  Note that the process for obtaining the representative gradation-luminance characteristics may not be performed for each display device 1. For example, as the representative gradation-luminance characteristic, the representative gradation-luminance characteristic acquired in the manufacturing method of another display device manufactured under the same conditions is used as the representative gradation-luminance characteristic of the display device itself. Also good. As a result, the representative gradation-luminance characteristics obtained by a manufacturing method of a certain display device are used in a manufacturing method of another display device manufactured under the same conditions as the device, so that the correction parameters of a plurality of display panels are used. It is possible to save the trouble of setting the representative gradation-luminance characteristics each time measurement is performed. As a result, the manufacturing process of the apparatus can be shortened.

  Next, the information processing apparatus 2 selects a plurality of discrete calculation gradation values that do not include the lower limit gradation within the display gradation range (S20).

  FIG. 6 is a diagram showing a display gradation range and a calculation gradation-luminance table. As shown in the upper part of FIG. 6, the luminance level of the pixel 400 by light emission of the organic EL element 402 is subdivided into 401 gradations of gradations 0D0h to 260h (h represents a hexadecimal number), for example. Here, the gradations 0D0h to 260h are a display gradation range that is a luminance range that the pixel 400 can display, and the gradation 0D0h is a lower limit display gradation (black display gradation) that indicates a lower limit of the light emission luminance. The gradation 260h is an upper limit display gradation indicating the upper limit of the light emission luminance.

  In the conventional correction method, the plurality of calculation gradation values are selected so as to include the lower limit display gradation (0D0h) and the upper limit display gradation (260h). In this case, the measured luminance value of the pixel A measured by supplying the lower limit display gradation (0D0h) to the pixel P as the calculated gradation value is, for example, 0.005051 as shown in the lower part of FIG. . This measured luminance value is a value below the measurement lower limit of the luminance meter 3, and does not represent the exact emission luminance of the pixel A. Therefore, as the calculated gradation value, 0D0h is not selected, but four values of 140h, 1A0h, 200h, and 260h are selected. As a result, the calculated gradation-luminance table of the pixel P is composed of combinations of the four calculated gradation values and the measured luminance corresponding to them.

  In contrast, in the manufacturing method according to the present embodiment, the plurality of calculated gradation values are selected so as not to include the lower limit display gradation (0D0h). For example, as calculation gradation values, 0D0h is not included, and five values 0D4h, 140h, 1A0h, 200h, and 260h are selected. Here, the measured luminance value of the pixel P at the gradation 0D4h is 0.022729. This measured luminance value is an effective value that exceeds the measurement lower limit of the luminance meter 3 and represents the exact emission luminance of the pixel P. Thereby, in step S20 according to the present embodiment and step S30 described later, the calculation gradation-luminance table of the pixel P is configured by a combination of the five values of the calculation gradation values and the measurement luminance corresponding to them. It will be.

  Next, the information processing apparatus 2 measures the light emission luminance at a plurality of discrete calculation gradation values selected in step S20 for each pixel 400, and generates a calculation gradation-luminance table (S30). In the above-described conventional correction method, when the luminance is measured using the lower limit display gradation as the operation gradation, the luminance value lower than the measurement limit of the luminance meter 3 is measured in the pixel P shown in FIG. In the pixel Q shown, a luminance value higher than the measurement limit of the luminance meter 3 is measured. This is due to variations in circuit characteristics of the pixels 400 included in the display portion 113. As a result, the number of data in the calculation gradation-luminance table of each pixel varies.

  On the other hand, since the plurality of discrete calculated gradation values selected in step S20 according to the present embodiment do not include the lower limit gradation in the display gradation range, all the measured luminance values in each calculated gradation value are It is a valid value. Therefore, the number of data of the calculation gradation-luminance table of each pixel 400 can be made the same.

  Next, the information processing apparatus 2 determines that each data (calculated gradation value, luminance) corresponding to the combination of the calculated gradation value and the luminance in the calculated gradation-luminance table generated in step S30 is a representative gradation. -The shift amount of the calculated gradation value in the calculated gradation-brightness table is determined so as to be data on the luminance characteristics (gradation value, luminance) (S40).

  FIG. 7 is a graph for explaining the shift of the calculated gradation value in step S40. In the graph of the figure, the horizontal axis represents the input gradation voltage supplied to the pixel 400, and the vertical axis represents the light emission luminance of the pixel 400. Further, the graph of FIG. 3 shows representative gradation-luminance characteristics and measured data (calculated gradation values, luminance values) of five points of the pixel P. The information processing apparatus 2 compares the representative gradation-luminance characteristics shown in FIG. 7 with the actual measurement data (calculated gradation value, luminance value) of the pixel P. For example, the information processing apparatus 2 sets the shift amount (a2-a1) of the calculation gradation so that the actual measurement data (a1, A) of the pixel P becomes the data (a2, A) on the representative gradation-luminance characteristic. Ask. In the same manner for the other four points of measured data, shift amounts (b2-b1), (c2-c1), (d2-d1), (e2-e1) of the operation gradations b1, c1, d1, and e1 are expressed as follows. Calculate each.

  Next, the information processing apparatus 2 generates a conversion table for correcting arbitrary input gradation data in the entire display gradation range from the correlation data of the calculated gradation values before and after the shift by the shift amount calculated in step S40 ( S50).

  FIG. 8 is a diagram showing the gradation conversion table in step S50. In the graph of the figure, the horizontal axis represents the input gradation voltage before correction, and the vertical axis represents the input gradation voltage after correction. In step S20, first, the calculation unit 21 correlates the calculated gradation value correlation data (a2, a1), (b2, b1), (c2, c1), (d2, d1) before and after the shift acquired in step S40. , And (e2, e1) are plotted on the graph. Specifically, the calculated gradation value (a2, b2, c2, d2, e2) after the shift is used as the horizontal axis indicating the input gradation voltage before correction, and the calculated gradation value (a1, b1, c1, d1, e) are plotted as a vertical axis indicating the corrected input gradation voltage.

  Next, the calculation unit 21 generates a gradation conversion table to be referred to when correcting the input gradation voltage in the display gradation range from the five points of correlation data. For example, the calculation unit generates a gradation conversion table represented by a linear expression (y = αx + β) from the five points of correlation data. Here, y is an input gradation voltage after correction, x is an input gradation voltage before correction, α is a correction coefficient, and β is an offset value.

  Note that after step S50, the information processing apparatus 2 writes the gradation conversion table of each pixel obtained in step S50 in the memory 121 of the display apparatus 1 (step S60). This step S10 corresponds to the sixth step. Specifically, in the memory 121, for example, gradation conversion data composed of (correction coefficient α, offset value β) for each pixel corresponds to a matrix of the display unit 113 (M rows × N columns). Stored.

  By executing the above steps S10 to S60, luminance unevenness of the display panel according to the present embodiment is eliminated. For example, the following processing is performed in the video display operation of the display device 1 after the manufacturing process is completed.

First, the control circuit 12 generates input gradation data for each pixel with respect to a video signal input from the outside. For example, it is assumed that all pixels are displayed with a uniform luminance A. At this time, the control circuit 12 determines that the input gradation voltage value to be supplied to all the pixels is a2 based on the representative gradation-luminance characteristics shown in FIG. However, when the same input gradation voltage a <b> 2 is supplied to all the pixels, luminance unevenness occurs due to characteristic variation for each pixel. Therefore, the control circuit 12 corrects the input gradation voltage a2. For example, in order to cause the pixel P to emit light with the luminance A, the input gradation voltage may be set to a1, as shown in FIG. The control circuit 12 performs conversion of the input gradation voltage using a gradation conversion table stored in the memory 121. If the gradation conversion data of the pixel P is (α _P , β _P ), the corrected input gradation voltage is calculated as a1 = α _P × a2 + β _P.

  FIG. 9 is a diagram comparing the correction accuracy of the display device according to the embodiment and the conventional display device. This figure shows a gradation conversion table generated when the lower limit gradation value a3 in the display gradation range is included in the plurality of calculated gradation values selected in step S20. Since the luminance measured at the calculation gradation value a3 is a measurement value including a large error, the calculation gradation value a4 after the shift of a3 based on the measurement value also includes a large error. For this reason, the accuracy of the gradation conversion table generated in step S50 is also low. For example, as shown in FIG. 9, the gradation conversion linear expression is not uniquely determined, and the correction coefficient α has a variation of α1 to α2 and the offset value varies from β1 to β2. Thereby, luminance unevenness cannot be suppressed with high accuracy.

  On the other hand, in the method for manufacturing display device 1 according to the present embodiment, the lower limit gradation value in the display gradation range is not included in the plurality of calculated gradation values selected in step S20. Therefore, since the luminance measured in the calculated gradation value does not include an error, the calculated gradation value after the shift calculated based on the measured luminance also does not include an error. For this reason, the accuracy of the gradation conversion table generated in step S50 is high. This makes it possible to suppress luminance unevenness with high accuracy.

  FIG. 10 is a diagram illustrating a calculation gradation-luminance table according to the embodiment. Specifically, FIG. 4 is a diagram for explaining steps S20 and S30 in the present embodiment. In each pixel 400 of the display unit 113, a plurality of calculated gradation values (D4, 140, 1A0, 200, 260: hexadecimal notation) not including the lower limit gradation (black display) used as an image are selected. (S20). FIG. 10 shows a calculation gradation-luminance table for the pixel P and the pixel Q.

  Here, at the calculation gradation D4 of the pixel P and the pixel Q, the pixel luminance is measured as 0.022729 and 0.03036, respectively. All of the measured luminance values exceed the measurement lower limit value of the luminance meter 3, and reflect the accurate emission luminance.

  As described above, in the case where the gradation conversion table of each pixel 400 is generated based on the same number of operation gradations in all the pixels 400 included in the display unit 113, for example, the same input gradation data is applied to all the pixels. When the corrected input gradation data is supplied to each pixel, the emission luminance is the same between the pixel P and the pixel Q as shown in FIG. That is, it is possible to effectively suppress luminance unevenness over the entire display panel.

(Other embodiments)
As mentioned above, although the manufacturing method of the display panel was demonstrated based on the said embodiment, this invention is not limited to embodiment mentioned above. Another embodiment realized by combining arbitrary constituent elements in the embodiment, or modifications obtained by applying various modifications conceivable by those skilled in the art without departing from the gist of the present invention to the embodiment. Various devices incorporating the organic EL display panel according to this embodiment are also included in the present invention.

  In step S20 to step S50 in the above embodiment, selection of a plurality of calculation gradation values, generation of calculation gradation-luminance table, shift of calculation gradation value, and generation of gradation conversion table are performed on pixels. However, this is not a limitation. A plurality of calculated gradation values, a calculated gradation-luminance table, a shifted calculated gradation value, and a gradation conversion table acquired in adjacent or neighboring pixels may be used. Thereby, although it is assumed that the correction accuracy of luminance unevenness falls, the effect that the manufacturing process regarding a correction process can be simplified is produced.

  In the above embodiment, an example of the pixel circuit configuration included in the display unit 113 of the present disclosure has been described. However, the circuit configuration of the pixel 400 is not limited to the above circuit configuration. For example, in the above-described embodiment, the configuration in which the enable transistor 405, the drive transistor 401, and the organic EL element 402 are arranged in this order between the positive power supply line and the negative power supply line is exemplified. May be arranged in a different order. That is, in the display unit 113 of the present disclosure, the drain and source of the drive transistor 401 and the anode and cathode of the organic EL element 402 are negative and positive, regardless of whether the drive transistor is n-type or p-type. The arrangement order of the drive transistor 401 and the organic EL element 402 is not limited as long as it is arranged on the current path between the power supply line and the power supply line.

  In the above embodiment, the selection transistor 404, the enable transistor 405, the reference transistor 406, and the initialization transistor 407 may be n-type, p-type, or a combination of both.

  In the method for manufacturing the display device according to the above embodiment, the case where the display device 1 using the organic EL element 402 is manufactured has been described as an example. However, the display device using the light emitting element other than the organic EL element is manufactured. You may apply to the method.

  In addition, the present invention can be realized not only as a manufacturing method of the display device 1 including the characteristic steps described in the above embodiment, but also generated using the characteristic steps included in the manufacturing method as a means. The display device 1 having the gradation conversion table has the same effect as described above. In other words, the display device 1 is supplied with the organic EL element 402 and the input gradation data for determining the light emission luminance of the organic EL element 402, so that a driving current corresponding to the input gradation data flows to the light emitting element. A plurality of pixels 400 including a driving transistor 401 element, a data line 434 for supplying input gradation data to the pixel 400, a scanning line 424 for supplying a scanning signal to the pixel 400, and an input to the data line 434 A data line driving circuit 112 that supplies gradation data, a scanning line driving circuit 111 that supplies scanning signals to the scanning lines 424, and a gradation conversion table that is referred to when correcting input gradation data are stored for each pixel 400. And a gradation conversion table for each pixel 400 is read from the memory 121 with respect to the video signal input from the outside and the input gradation data is obtained. Positive for and a correcting unit. The gradation conversion table includes a first step of acquiring representative gradation-luminance characteristics, a second step of selecting a plurality of discrete calculation gradation values not including the lower limit gradation in the display gradation range, and the pixel 400. A third step of creating a calculated gradation-luminance table for each, and a shift amount of the calculated gradation value such that each data of the calculated gradation-luminance table matches data on the representative gradation-luminance characteristics Arbitrary input gradation data in the display gradation range is corrected based on correlation data between the calculated gradation value shifted by the shift amount obtained in the fourth step and the fourth step and the calculated gradation value before the shift. And a fifth step of generating a gradation conversion table for each pixel.

  Further, the display device 1 manufactured by the display device manufacturing method according to the present embodiment is built in a thin flat TV as shown in FIG. By the method for manufacturing a display device according to the present embodiment, a high-quality thin flat TV in which luminance unevenness is suppressed with high accuracy is realized.

  The display device and the manufacturing method thereof according to the present invention are useful in technical fields such as thin televisions and personal computer displays that require a large screen and high resolution.

DESCRIPTION OF SYMBOLS 1 Display apparatus 2 Information processing apparatus 3 Luminometer 11 Display panel 12 Control circuit 21 Operation part 22 Storage part 23 Communication part 111 Scan line drive circuit 112 Data line drive circuit 113 Display part 121 Memory 400 Pixel 401 Drive transistor 402 Organic EL element 403 Storage capacitor 404 Select transistor 405 Enable transistor 406 Reference transistor 407 Initialization transistor 424, 425, 426, 427 Scan line 434 Data line

Claims (7)

Pixels including a light emitting element and a driving element that supplies a driving current corresponding to the input gradation data to the light emitting element by supplying input grayscale data for determining light emission luminance of the light emitting element are arranged in a matrix. A method of manufacturing a display device having a display panel arranged,
A representative gradation-luminance characteristic, which is a gradation-luminance characteristic common to the entire display panel, is obtained as a target for correcting the gradation-luminance characteristic for each pixel representing the correlation between the input gradation and the light emission luminance. One step,
A plurality of gradation values for generating a gradation conversion table to be referred to when correcting the input gradation data, including a lower limit gradation in a display gradation range which is a gradation range used as an image A second step of selecting a plurality of non-discrete arithmetic gradation values;
A third step of measuring emission luminance at the plurality of discrete calculation gradation values for each of the pixels and creating a calculation gradation-luminance table for each of the pixels;
The plurality of discrete data for each pixel such that each data corresponding to the combination of the calculated gradation value and the luminance in the calculated gradation-luminance table matches the data on the representative gradation-luminance characteristic. A fourth step for obtaining a shift amount of the calculated gradation value;
The display gradation range based on correlation data between the plurality of discrete operation gradation values shifted by the shift amount obtained in the fourth step and the plurality of discrete operation gradation values before the shift. And a fifth step of generating, for each pixel, the gradation conversion table for correcting arbitrary input gradation data in the display device. In the second step,
The method for manufacturing a display device according to claim 1, wherein the same plurality of discrete calculation gradation values are selected in all the pixels. In the fifth step,
When the plurality of discrete arithmetic gradation values before the shift is x, the plurality of shifted discrete arithmetic gradation values is y, the correction coefficient is α, and the offset value is β, the gradation conversion table is: The display device manufacturing method according to claim 1, wherein the display device is generated as a linear expression represented by y = αx + β. In the third step, the light emission luminance at the plurality of discrete calculation gradation values is measured with a luminance meter,
4. The display according to claim 1, wherein in the second step, the plurality of discrete calculation gradation values that are equal to or higher than a gradation value corresponding to a minimum luminance detectable by the luminance meter are selected. Device manufacturing method. In the first step,
5. The display device according to claim 1, wherein the representative gradation-luminance characteristic acquired in a manufacturing method of another display device manufactured under the same condition is used as the representative gradation-luminance characteristic. Manufacturing method. further,
The method for manufacturing a display device according to claim 1, further comprising a sixth step of writing the gradation conversion table of each pixel generated in the fifth step into a predetermined memory. A plurality of pixels including a light emitting element and a driving element that supplies a driving current corresponding to the input gray scale data to the light emitting element by supplying input gray scale data that determines light emission luminance of the light emitting element;
A plurality of data lines for supplying the input gradation data to each of the plurality of pixels;
A plurality of scanning lines for supplying a scanning signal to each of the plurality of pixels;
A data line driving circuit for supplying the input grayscale data to the plurality of data lines;
A scanning line driving circuit for supplying the scanning signal to the plurality of scanning lines;
A memory that stores a gradation conversion table to be referred to when correcting the input gradation data for each of the plurality of pixels;
Correction for reading out the gradation conversion table corresponding to each of the plurality of pixels from the storage unit with respect to a video signal input from the outside, and correcting the input gradation data corresponding to each of the plurality of pixels With
The gradation conversion table is:
A representative gradation-luminance characteristic, which is a gradation-luminance characteristic common to all of the plurality of pixels, is obtained as a target for correcting the gradation-luminance characteristic for each pixel representing the correlation between the input gradation and the light emission luminance. The first step;
A plurality of gradation values for creating the gradation conversion table, and a plurality of discrete calculation gradation values not including the lower limit gradation in the display gradation range which is a gradation range used as an image is selected. A second step to
A third step of measuring emission luminance at the plurality of discrete calculation gradation values for each of the pixels and creating a calculation gradation-luminance table for each of the pixels;
The plurality of discrete data for each pixel such that each data corresponding to the combination of the calculated gradation value and the luminance in the calculated gradation-luminance table matches the data on the representative gradation-luminance characteristic. A fourth step for obtaining a shift amount of the calculated gradation value;
The display gradation range based on correlation data between the plurality of discrete operation gradation values shifted by the shift amount obtained in the fourth step and the plurality of discrete operation gradation values before the shift. And a fifth step of generating the gradation conversion table for correcting arbitrary input gradation data for each pixel.