JP4952972B2 - Self-luminous display device, light emission condition optimization device, light emission condition optimization method and program - Google Patents

Description

One embodiment of the present invention relates to a self light emitting display device in which self light emitting elements are arranged in a matrix.
One embodiment of the present invention relates to a light emission condition optimizing device and a light emission condition optimizing method mounted on a self-luminous display device. One embodiment of the present invention relates to a program for optimizing light emission conditions to be executed by an arithmetic device (computer) mounted on a self-luminous display device.
Self-luminous elements include, for example, EL (Electro Luminescence) elements, LED (Light
There are Emitting Diode (PEM) elements, PDP (Plasma Display Panel) elements, and FED (Field Emission Display) elements.

An organic EL element is a light emitting element excellent in luminous efficiency capable of obtaining a luminance of several hundred nits at a voltage of 10 V or less. The organic EL element has good contrast performance and excellent display characteristics in low gradation display. For this reason, it is regarded as promising as a next-generation flat panel display.
On the other hand, light emission luminance, contrast, and power consumption depend on the characteristics of the organic EL element that is a light emitting element.
JP 2003-228331 A

By the way, recent display devices are required to have higher luminance. Accordingly, the driving voltage or driving current of the organic EL element tends to increase.
However, continuous application of a high voltage or high current has a problem of deteriorating the organic EL element and shortening the life. At the same time, continuous application of high voltage or high current has a problem of increasing power consumption.

The inventors pay attention to the above technical problems and propose a technique having the following processing functions as a technique for optimizing the light emission condition of each pixel.
(A1) An average luminance detection unit that obtains an average luminance level in units of planes based on display data of all pixels (a2) A shorter light emission period is associated with a larger average luminance level in units of planes, and the average luminance level in units of planes is 100 A look-up table that associates a maximum period that can be assigned as a light emission period when 0% to 10 % of the% luminance level, and for an average luminance level that is larger than a reference value, the light emission period is nonlinear as the average luminance level increases. Lookup table (a3) in which the correspondence relationship to be shortened is recorded The light emission period corresponding to the average luminance level detected by the average luminance detection unit is read from the lookup table, and control is performed so that each pixel emits light during the light emission period. Light emission period control unit that outputs a control signal to the drive circuit

In addition, the inventors propose a technique having the following processing functions as a technique capable of realizing an equivalent function through arithmetic processing.
(B1) An average luminance detection unit that obtains an average luminance level in units of planes based on display data of all pixels (b2) A shorter light emission period is associated with an increase in the average luminance level in units of planes, and the average luminance level in units of planes is 100 A light emission period calculating unit that associates a maximum period that can be assigned as a light emission period when the luminance level is 0 to 10 %, and for an average luminance level greater than a reference value, the light emission period increases as the average luminance level increases. A light emission period calculation unit (b3) that calculates a light emission period according to a function having a correspondence relationship that shortens nonlinearly. A control signal for controlling each pixel to emit light in the light emission period calculated by the light emission period calculation unit is output to the drive circuit. Light emission period controller

  By adopting these techniques, the light emission period can be optimized according to the average luminance level in units of planes. That is, for an image having an average luminance level in units of planes greater than the reference value, the light emission period is nonlinearly shortened as the average luminance level increases. Thus, the maximum power consumption can be suppressed within a certain range without processing the display data.

Hereinafter, an organic EL display device equipped with the technology 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 illustrated or described in particular in this specification.
Moreover, the form example demonstrated below is one form example of invention, Comprising: It is not limited to these.

(A) Description of Basic Effects by Variable Control of Light Emission Period First, basic effects obtained by variably controlling the light emission period will be described.
FIG. 1 shows a correspondence relationship between the drive current Iel flowing through the organic EL element and the light emission luminance Lel. As shown in FIG. 1, a proportional relationship is recognized between the drive current Iel and the light emission luminance Lel.
By the way, the gradation display characteristic of a general display requires an input / output characteristic of a power of 2.2 from an ergonomic point of view. That is, an input / output characteristic of the power of 2.2 is required between display data (input data) and light emission luminance. This nonlinear input / output characteristic is called a gamma characteristic.

FIG. 2 shows the gradation display characteristics. The horizontal axis represents the maximum gradation value as 100%. For example, in the case of 8-bit display data (input data), the gradation value “255” is shown as 100%. The vertical axis indicates the luminance corresponding to the gradation value “255” as 100%.
Of course, this gradation display characteristic is also required for an active matrix organic EL display.

This gradation display characteristic is realized by one of the following methods.
(1) A technique for giving a digital / analog conversion circuit that converts display data (input data) into a voltage value of a driving transistor having a power of 2.2. (2) An output characteristic of drain current with respect to a gate voltage of the driving transistor is 2 .Method to give square characteristic

With this gradation display characteristic, the power consumption Wel of the organic EL display as a whole is calculated as a value obtained by multiplying the sum of the drive currents Iel flowing through the individual organic EL elements by the power supply voltage. That is, it is calculated as Wel = ΣIel · (power supply voltage).
This means that the power consumption is proportional to the brightness of the entire screen, in other words, the amount of data in one frame.

Therefore, the power consumption when the light emission period is not variably controlled (modulated) is as shown in FIG. 3 in relation to the average input data level.
The average input data level here means an average luminance level (APL: Average Picture Level) in units of one frame (screen). Note that the horizontal axis of FIG. 3 indicates 100% with the entire white (100% luminance of all pixels) being “100”. Also, the horizontal axis of FIG. 3 indicates the power consumption value of the average input data level APL, with the power consumption of the entire white being “1”.

Thus, if the entire period of one frame is the light emission period, the power consumption of the entire screen increases along a characteristic curve given by the average input data level APL raised to the power of 2.2.
This characteristic is the same when the light emission period is limited to a part of one frame period. FIG. 4 shows the relationship between the average input data level and power consumption when the light emission period is fixed to 25%, 50%, and 75% of one frame period.

Note that the horizontal axis of FIG. 4 represents the ratio of the light emitting period as a percentage, where one frame period is 100%. It is assumed that the organic EL display is turned off outside the light emission period.
In addition, the vertical axis in FIG. 4 represents “100” as the power consumption when displaying the entire white when the light emission period is 75% of one frame period.
Of course, the power consumption increases as the light emission period becomes longer even at the same average input data level.

From the above, it can be seen that shortening the light emission period is effective in reducing power consumption.
However, sufficient light emission luminance cannot be obtained by simply shortening the light emission period. That is, there is a problem in image quality reproducibility.
Therefore, the light emission period is actively variably controlled according to the average input data level (average luminance level in units of planes) APL. FIG. 5 shows an example of association of the light emission period with the average input data level APL.

FIG. 5 shows an example in which the light emission period is varied in the range of 25% to 75% of one frame period with respect to 0% to 100% of the average input data level APL. That is, an example is described in which the light emission period is lengthened (75%) as the average luminance is small and the light emission period is shortened (25%) as the average luminance is large. The reason for extending the light emission period when the average luminance is low is to ensure a sufficient contrast difference on the low luminance screen. This is because, for example, sufficient luminance is ensured for a small-area high-luminance region.
FIG. 6 shows the power consumption when the light emission period is variably controlled according to the average input data level. FIG. 6 also shows the power consumption (FIG. 4) when the light emission period is fixed to 25% or 75% of the frame period.

When the light emission period is variably controlled, the power consumption is 40% or less when the light emission period is fixed to 75% of the frame period, as shown by the curve connecting the X mark and the ▲ mark.
Note that the curve connecting the crosses in the figure corresponds to the case where the entire frame is uniformly displayed with the same data value. Such a display is called “flat field display”. A display example is shown in FIG.

That is, the solid line connecting the ▲ marks indicates the power consumption when the light emission period is varied from 75% to 25% according to the average input data level when the average input data level is 0 to 100% in the flat field display. It shows a change.
The maximum power consumption in the flat field display is calculated by the following equation.
Maximum power consumption = (power consumption / unit emission period), emission period, (gamma value, input data level)
Here, the light emission period is a value in which the entire period of one frame is “1”.

On the other hand, the curve connecting the crosses in the figure corresponds to the case where a white window having a black level as a background and having a brightness of 100% is varied in a range of 0 to 100% with respect to the entire display area. Such a display is called “window display”. FIG. 7B shows a display example.
That is, the solid line connecting the X marks indicates a change in power consumption when the light emission period of the white window is varied from 75% to 25% according to the window area of 0 to 100% in the window display.
The maximum power consumption in the white window display is calculated by the following equation.
Maximum power consumption = (power consumption / unit light emission period), light emission period, input window size

As described above, by adopting a method of controlling the light emission period in units of planes independently of the input data level for each pixel, the power consumption is suppressed without reducing the maximum luminance as the spec of the organic EL display can do.
For example, if the maximum power consumption when the light emission period is fixed is 100 W, the maximum power consumption is suppressed to 33 W by changing the light emission period in the range of 25% to 75% (dynamic range is 3 times). can do.

(B) Optimization process of light emission conditions As described above, the power consumption can be greatly reduced by linearly reducing the light emission period with respect to the average luminance level in units of planes.
However, even if the average luminance level of the surface unit is the same, the power consumption of the white window display is larger than the power consumption of the flat field display. For example, the white window display shown in FIG. 8A and the flat field display shown in FIG. 8B both have an average luminance level of 50%. The effect of the gamma characteristic (FIG. 3) increases.

For this reason, the power consumption curve (solid line connecting the x marks) of the white window display shown in FIG. 6 has a convex shape upward, and the power consumption is maximized at a value smaller than the maximum value (100%) of the average input data level. Become. That is, the power consumption set for the maximum value (100%) of the average input data level (the light emission period is the minimum value (25%)) may be exceeded.
Therefore, it is required to optimize the light emission conditions so as to satisfy the maximum power consumption while maintaining the image quality regardless of the display mode. Actually, a general display image is an intermediate mode between flat field display and white window display.
The inventors propose the following control method from the above viewpoint.

(B-1) Form example 1
Here, a method of controlling the light emission period so as to cancel the 2.2-th power gamma characteristic that affects power consumption will be described.

(A) Optimization condition (1) Maximum luminance Here, the maximum luminance displayed as the organic EL display is set when the average input data level APL is minimum and the light emission period is maximum.
In the case of a general image, when the average input data level APL is between 0% (all black) and 10%, the power consumption is kept low even when the light emission period is saturated to the maximum value of the variable range. And no visual discomfort.

In order to obtain a high contrast, a range from 0% to 10% of the average input data level APL is set to the maximum value.
However, the upper limit of the range in which the light emission period is set to the maximum value of the variable range need not be limited to 10% of the average input data level APL, and may be set to about 20% depending on the purpose and the content of the display image.

(2) Maximum power consumption Here, the maximum power consumption that can be shared as an organic EL display is set when the average input data level APL is maximum and the light emission period is minimum.
This value may be a flat field display or a white window display. That is, even in the white window display, the maximum value of power consumption is given when the average input data level APL is maximum and the light emission time is minimum.

(3) Light emission period The conditions of the variable range of the light emission period associated with the variable range of the average input data level (average luminance level) APL are set as follows.
First, the upper limit of the variable range will be described.
When the maximum value of the light emission period is set to 100%, there is a possibility that an afterimage may be seen due to human visual characteristics during moving image reproduction. For this reason, the organic EL display seems to have a poor response speed even though the response speed is actually high.

Therefore, the inventors consider that the maximum value of the light emission period is optimally less than 50%.
However, from the viewpoint of widening the variable range (dynamic range) of the light emission period, it is recommended that the upper limit of the variable range be set to less than 80% of one frame period (maximum variable period).
That is, the inventors recommend that the maximum value of the light emission period is set in a range of about 50% to 80% of one frame period according to the purpose.

Next, the lower limit of the variable range will be described.
When the light emission period is extremely close to 0%, it is necessary to increase the current density of the organic EL element in order to obtain a predetermined luminance in a short light emission period.
However, increasing the current density to obtain high luminance simultaneously causes a deterioration in luminance. In addition, when the light emission period is short, the active matrix type self-luminous display (that is, line sequential light emission) is achieved, but the state is close to impulse driving as in the cathode ray tube display. As a result, the vertical scanning frequency (frame rate) is 60 Hz. In the case of, flickering of the screen can be seen and cause the image quality to be impaired.

Therefore, the inventors consider that the minimum value of the light emission period is optimally 25% or more.
However, from the viewpoint of widening the variable range (dynamic range) of the light emission period, it is recommended that the lower limit of the variable range be set between 10% and 30% of one frame period (maximum variable period).
That is, the variable range of the light emission period is set to about 10% to 80% of one frame period (maximum variable period). Preferably, it is set to about 25% to 75% of one frame period (maximum variable period). More preferably, it is set to about 30% to 50% of one frame period (maximum variable period).

(4) Cancellation of Gamma Characteristic As described above, between 0% (all black) and 10% of the average input data level APL, the light emission period is assigned the maximum value in the variable range, while the average input data level APL is The interval of 10% or more is associated with a shorter light emission period as the average input data level APL per unit is larger.
However, if the light emission period is linearly assigned to the average input data level, the aforementioned maximum power consumption cannot be satisfied.

Therefore, the inventors shorten the light emission period non-linearly as the average input data level increases for an average input data level greater than a reference value (for example, 50%). That is, between 50% and 100% of the average input data level APL, the light emission period is shortened by a non-linear curve that cancels the gamma characteristic (2.2 power). Even if the light emission period is shortened in this way, an image of one frame has a gamma characteristic of 2.2, so that the image quality is not impaired at all.
In addition, between 10% and 50% of the input data level APL, the light emission period may be shortened linearly or nonlinearly as the average input data level increases.

FIG. 9 shows a correspondence relationship between the average input data level APL satisfying the above light emission conditions and the light emission period.
In the figure, the curve indicated by the solid line is the optimized correspondence. In addition, the straight line shown with the broken line in a figure respond | corresponds to the corresponding relationship demonstrated in FIG.
As can be seen by comparing the straight line and the broken line, the light emission period is longer than 0% to 50% of the average input data level APL than the broken line. On the other hand, the light emission period is shorter than the broken line between 50% and 100% of the average input data level APL.

FIG. 10 shows the transition of power consumption when “flat field display” and “white window display” are displayed in the optimized light emission period (FIG. 9).
The curve with ▲ in the figure corresponds to “flat field display”, and the curve with x in the figure corresponds to “white window display”.
In the case of FIG. 10, it can be seen that the power consumption curve of the white window display (solid line connecting x marks) is almost flattened from around 50% to 100% of the average input data level.

In this way, as a result of canceling the gamma characteristic (the power of 2.2) from around 50% to 100% of the average input data level, the power consumption is reduced so as to satisfy the maximum power consumption for all actual image displays. Can be suppressed.
That is, it is possible to achieve both suppression of maximum power consumption and high image quality.

(B) Configuration of Display Device and Light-Emitting Condition Optimization Circuit (1) Overall Configuration of Display Device Here, a device configuration that enables a control operation that satisfies the light-emitting conditions described above will be described.
FIG. 11 shows a conceptual configuration example of an organic EL display device. That is, FIG. 11 shows only one of the pixel circuits arranged in a matrix, and shows the connection relationship of the drive circuits.
Note that the pixel circuit has a three-transistor structure.

In the figure, there are three drive circuits: a data line drive circuit 1, a scan line selection gate line drive circuit 3, and a light emission period control gate drive circuit 5.
All or part of these drive circuits are mounted on the panel substrate as drive ICs. However, all or part of these driving circuits can be formed on the panel substrate together with the pixel circuit.

The pixel circuit 7 includes three transistors T1, T2, and T3, a capacitive element C1, and an organic EL element 9. These three transistors T1, T2, and T3 are all constituted by thin film transistors (TFTs). In this circuit example, an N-channel transistor is used as the transistor T1, and a P-channel transistor is used as the transistors T2 and T3.
Among these, the transistor T1 is for capturing a data signal (voltage value). The control terminal of the transistor T1 is connected to the scanning line, and its opening / closing operation is controlled by the scanning line selection gate line driving circuit 3. When the transistor T1 is in a closed state, a data signal (voltage value) supplied from the data line driving circuit 1 through the data line is written and held in the capacitor C1.

The transistor T2 is for supplying a drive current to the organic EL element 9. The control terminal of the transistor T2 is connected to one electrode of the capacitive element C1, and controls the drive current value supplied to the organic EL element 9. That is, the current density is controlled.
The transistor T3 is for controlling the supply and stop (on and off) of the drive current. The transistor T3 is located on the drive current supply path. The control terminal of the transistor T3 is connected to the light emission period control gate drive circuit 5, and controls the opening / closing operation of the supply path. In conjunction with this opening / closing operation, the organic EL element 9 is turned on or off.
The variable control of the light emission period is realized through the opening / closing operation of the transistor T3.

The control signal for the transistor T3 is given from the light emission condition optimization circuit 11.
The light emission condition optimizing circuit 11 is a circuit for obtaining an average input data level (average luminance level) in units of planes from display data input to the data line driving circuit 1 and obtaining a light emission period suitable for the average input data level. .
The light emission condition optimization circuit 11 variably controls the light emission period in a range of 25% to 75% of one frame period. That is, as shown in FIG. 12, the dynamic range is tripled.
Of course, the variable control of the light emission period is executed nonlinearly in a region where the average input data level is high as shown in FIG.

(2) Light Emission Condition Optimization Circuit FIG. 13 shows an example of the internal configuration of the light emission condition optimization circuit 11. The light emission condition optimization circuit 11 includes a luminance data conversion unit 21, an average luminance detection unit 23, a light emission period lookup table 25, and a light emission period control unit 27.
Among these, the luminance data conversion unit 21 is a signal processing unit that converts RGB data into luminance data (display data). By this conversion processing, the RGB data is converted into luminance data (display data) having only brightness information.

The average luminance detection unit 23 is a signal processing unit that obtains an average luminance level (average input data level) APL in units of planes based on luminance data of all pixels.
The light emission period look-up table 25 is a storage area for storing the correspondence corresponding to FIG. That is, the look-up table 25 for the light emission period has a relationship in which a light emission period of 75% is associated with an average input data level APL of 0% to 10%, and an average input data level APL of 10% to 50%. % Stores a correspondence relationship in which the light emission period is linearly shortened, and a correspondence relationship in which the light emission period is nonlinearly shortened when the average input data level APL for each plane is 50% to 100%.

The light emission period control unit 27 reads the light emission period corresponding to the average luminance level (average input data level) APL detected by the average luminance detection unit 23 from the light emission period lookup table 27, and each pixel emits light during the light emission period. This is a signal processing unit that outputs a control signal Scont to be controlled to the light emission period control gate drive circuit 5.
The light emission period control unit 27 is configured by a circuit that modulates the pulse width in the read light emission period, for example.

As described above, the setting of the light emission period can be completed in a short time by storing the correspondence relationship between the average input data level APL and the light emission period in the lookup table. In addition, it is possible to cope with any non-linear curve having a corresponding relationship.
For reference, FIG. 14 shows how the organic EL element is controlled to emit light when the emission period corresponding to the average input data level APL detected for a certain screen is 70%.

FIG. 14A shows data signals (voltage values) corresponding to individual pixels constituting the organic EL display. As illustrated, the data signal (voltage value) takes an arbitrary value according to each pixel.
FIG. 14B shows a signal waveform of the control signal Scont output from the light emission condition optimization circuit 11. This control signal Scont is applied to the transistor T3, and 70% of one frame period is controlled to be in the ON state.

FIG. 14C is a signal waveform showing the ON / OFF state of the organic EL element corresponding to each pixel. While the transistor T3 is in the on state, the organic EL element emits light by driving current corresponding to display data (voltage value). The remaining 30% of one frame period is turned off because the drive current is cut off.
This on / off operation is executed for the entire screen of the organic EL display.

(C) Program In the above description, the light emission condition optimizing circuit in which the correspondence is read using the lookup table has been described.
However, equivalent control can be realized through program processing executed on a computer. However, this configuration requires that a computer (microprocessor) is mounted on the organic EL display and that the time required for calculation is sufficiently short for the display of the screen.

FIG. 15 shows an outline of the light emission condition optimization processing program.
First, the program converts RGB data as display data into luminance data (S1).
Next, the program calculates an average luminance level (average input data level) APL in units of planes based on the luminance data of all pixels (S2).

  Subsequently, the program calculates a light emission period used for displaying the corresponding screen using a predetermined function (S3). The function here is a function that gives the correspondence in FIG. That is, a function for associating a 75% light emission period with an average input data level APL of 0% to 10%, and a light emission period linearly shorter with an average input data level APL of 10% to 50%. The function for associating the light emission period with the light emission period, and the function for associating the light emission period so that the average input data level APL for each plane is non-linearly shortened from 50% to 100%. It is desirable that the function of the nonlinear part also considers the amount of calculation.

Thereafter, the program modulates the pulse width in the obtained light emission period, and generates a control signal Scont (S4).
The method of reading out these series of processes from the firmware or other storage area and executing them by a program is also effective in that the control method can be adjusted and improved after product shipment.

(B-2) Embodiment 2
Next, a method of controlling the light emission period and the light emission level so as to cancel the 2.2th power gamma characteristic that affects the power consumption will be described. That is, the second embodiment is a combination control of the light emission period and the light emission level. In the case of this control method, there is an advantage that the dynamic range can be made larger than the control of only one of them.
Moreover, adjusting the balance of the control amount is effective for realizing image quality corresponding to the display screen.

(A) Optimization Conditions FIG. 16 shows the light emission period and light emission level variable conditions used in this embodiment.
In the case of this embodiment, the light emission period is variably controlled in the range of 25% to 75% of one frame period according to the average input data level. However, as described in Embodiment 1, the lower limit may be set to about 10% and the upper limit may be set to about 80%. Also in this example, the peak luminance of the luminance level can be variably controlled with a dynamic range that is three times higher by the variable control of the light emission period.

On the other hand, the light emission level is variably controlled in the range of 50% to 100% of the luminance level capable of generating the light emission level according to the average input data level. In the case of this example, the peak luminance of the luminance level can be variably controlled with a double dynamic range by the variable control of the light emission level.
Therefore, in this embodiment, a dynamic range of 6 times can be realized by controlling the combination of the light emission period and the light emission level.
For this reason, according to the content of the screen to display, it becomes possible to give more suitable light emission conditions.

FIG. 17 shows the correspondence relationship of the light emission periods that are variably controlled according to the average input data level APL. Since this correspondence is basically the same as in FIG.
FIG. 18 shows a correspondence relationship between light emission levels that are variably controlled according to the average input data level APL. The correspondence relationship regarding the light emission level is substantially the same as the light emission period.
Note that, in order to ensure the brightness of the high-luminance small area portion on the low-luminance screen, the vicinity of 100% of the light emission level is assigned near 0% of the average input data level APL.

In addition, as the average input data level APL gradually increases from 0%, the light emission level also decreases. The light emission level is about 75% around 50% of the average input data level APL, and around 70% of the average input data level APL. The light emission level becomes about 60%. Between 70% and 100% of the average input data level APL, the light emission level is reduced non-linearly so that the change in the light emission level becomes gentle.
FIG. 19 shows a change in power consumption when light emission of the organic EL element is controlled with such a correspondence.

The curve with ▲ in the figure corresponds to “flat field display”, and the curve with x in the figure corresponds to “white window display”.
Also in the case of FIG. 19, it can be seen that the power consumption curve (solid line connecting the X marks) of the white window display is almost flattened from around 50% to 100% of the average input data level.
In this way, as a result of canceling the gamma characteristic (the power of 2.2) from around 50% to 100% of the average input data level, the power consumption is reduced so as to satisfy the maximum power consumption for all actual image displays. Can be suppressed.
That is, it is possible to achieve both suppression of maximum power consumption and high image quality.

(B) Configuration of Display Device and Light Emission Condition Optimization Circuit (1) Overall Configuration of Display Device A device configuration that enables a control operation that satisfies the light emission conditions described above will be described.
FIG. 20 shows a conceptual configuration example of an organic EL display device. In FIG. 20, parts corresponding to those in FIG. 11 are denoted by the same reference numerals.
The organic EL display device includes a data line driving circuit 31, a scanning line selecting gate line driving circuit 3, a light emission period controlling gate driving circuit 5, a pixel circuit 7, and a light emission condition optimizing circuit 33.

There are two components that are unique to this embodiment: a data line drive circuit 31 and a light emission condition optimization circuit 33.
FIG. 21 shows an internal configuration example of the data line driving circuit 31. The data line driving circuit 31 includes a data switch 41, a digital / analog conversion circuit 43, a sample hold circuit 45, and a buffer amplifier 47. The data switch 41 is a circuit unit that distributes display data (corresponding to RGB signals) input in a digital signal format to corresponding data lines according to the pixel arrangement.

The data switch 41 is supplied with a clock pulse CLK for determining a driving speed, a driving control signal CTL, and the like from a known external system.
The digital / analog conversion circuit 43 is a circuit that converts display data into a voltage value. In this embodiment, the maximum reference voltage Vref is given from the light emission condition optimization circuit 33.

That is, the maximum reference voltage Vref is variably controlled in the range of 50% to 100% of the reference voltage. When the maximum reference voltage Vref is increased or decreased, the voltage value as the conversion output can be increased or decreased while maintaining the gradation information given by the display data.
The sample hold circuit 45 is a circuit that holds a voltage value supplied to the corresponding data line. Actually, it is composed of parallel circuits for reading and writing.
The buffer amplifier 47 is an amplifier circuit that supplies a voltage value to the corresponding data line.

FIG. 22 shows an internal configuration example of the light emission condition optimization circuit 33. FIG. 22 shows parts corresponding to those in FIG.
The light emission condition optimization circuit 33 includes a luminance data converter 21, an average luminance detector 23, a light emission period lookup table 25, a light emission period controller 27, a light emission level LUT 51, and a light emission level controller 53.
Among these components, there are two components that are unique to the embodiment: a light emission level LUT 51 and a light emission level control unit 53.

The light emission level look-up table 51 is a storage area for storing a correspondence relationship corresponding to FIG. That is, the light emission level lookup table 51 stores a correspondence relationship that decreases nonlinearly as the average input data level APL in units of planes increases.
The light emission level control unit 53 reads the light emission level corresponding to the average luminance level (average input data level) APL detected by the average luminance detection unit 23 from the light emission level lookup table 51, and each pixel emits light at the light emission level. The signal processing unit generates the reference voltage Vref and outputs it to the digital / analog conversion circuit 43.

That is, in this embodiment, it is assumed that a voltage source is built in the light emission level control unit 53. However, the generation of the reference voltage Vref itself may be performed by an external voltage source, and the light emission level control unit 53 may control only the output of a control signal to the voltage source.
Also in this case, the setting of the light emission period can be completed in a short time by storing the correspondence relationship between the light emission period and the light emission level with respect to the average input data level APL in the lookup table. In addition, it is possible to cope with any non-linear curve having a corresponding relationship.
For reference, FIG. 23 shows how the organic EL element is controlled to emit light when the emission period corresponding to the average input data level APL detected for a certain screen is 70%.

FIG. 23A shows data signals (voltage values) corresponding to individual pixels constituting the organic EL display. As shown in the figure, the data signal (voltage value) takes an arbitrary value according to each pixel, with a value determined by the reference voltage Vref of the digital / analog conversion circuit 43 as an upper limit value.
FIG. 23B is a signal waveform of the control signal Scont for the light emission period output from the light emission condition optimization circuit 33. This control signal Scont is applied to the transistor T3, and 70% of one frame period is controlled to be in the ON state.

FIG. 23C is a signal waveform showing the ON / OFF state of the organic EL element corresponding to each pixel. While the transistor T3 is in the on state, the organic EL element emits light by driving current corresponding to display data (voltage value). The remaining 30% of one frame period is turned off because the drive current is cut off.
This on / off operation is executed for the entire screen of the organic EL display.

(C) Program In the above description, the light emission condition optimizing circuit in which the correspondence is read using the lookup table has been described.
However, equivalent control can also be realized through program processing executed on an arithmetic device (computer). However, this configuration requires that a computer (microprocessor) is mounted on the organic EL display module and that the time required for calculation is sufficiently short for the display of the screen.

FIG. 24 shows an outline of the light emission condition optimization processing program. In this program, the same processing as that in the case of the first embodiment (FIG. 15) is executed for the portion related to the control of the light emission period.
First, the program converts RGB data into luminance data as a process common to the control of the light emission period and the light emission level (S11).
Next, the program calculates an average luminance level (average input data level) APL in units of planes based on the luminance data of all pixels (S12).

Thereafter, the program executes the light emission period control (S13, S14) and the light emission level control (S15, S16) in parallel.
First, as control of the light emission period, the program calculates the light emission period used for displaying the corresponding screen using a predetermined function (S13). The function here is a function that gives the correspondence in FIG. Of course, it is desirable that the function of the nonlinear part also considers the viewpoint of the amount of calculation.
Thereafter, the program modulates the pulse width in the obtained light emission period, and generates the control signal Scont (S14). The generated control signal Scont is given to the light emission period control gate drive circuit 5.

On the other hand, as control of the light emission level, the program calculates the maximum light emission level of the corresponding screen using a predetermined function (S15). This function is a function that gives the correspondence in FIG. Of course, it is desirable that the function of the nonlinear part also considers the viewpoint of the amount of calculation.
Thereafter, the program controls the voltage source to generate a reference voltage corresponding to the obtained maximum light emission level.
The method of reading out these series of processes from the firmware or other storage area and executing them by a program is also effective in that the control method can be adjusted and improved after product shipment.

(C) Other Embodiments (a) In the embodiment described above, the case where the light emission period is associated non-linearly in the range of 50% or more of the average input data level (average luminance level) APL has been described.
However, 50% giving the lower limit of the non-linear range is an example, and a wider range may be set. For example, the light emission periods may be associated non-linearly within a range of 10% or more of the average input data level (average luminance level) APL.

(B) In the above-described embodiment, the case where the pixel circuit having the structure shown in FIG. 11 is used has been described. That is, the case where the transistor T3 is connected between the supply line of the power supply voltage Vcc and the transistor T2 has been described.
However, other circuit configurations can be adopted for the pixel circuit that can control the light emission period and the extinction period of the organic EL element independently of the display data.
For example, as shown in FIG. 25, the transistor T3 may be connected between the cathode power supply line and the transistor T2.

(C) In the above-described embodiment, the case where the reference voltage Vref of the digital / analog conversion circuit 43 is variably controlled when the emission level is variably controlled has been described. However, the amount of current flowing through the current source may be variably controlled. .

(D) In the above-described embodiment, the product form of the organic EL display alone has been described.
However, the technology according to the invention can also be applied to various light emitting devices (electronic devices) equipped with an organic EL display.
For example, a video camera, a digital camera, a head-mounted display, a navigation system, a sound reproducing device, a notebook computer, a game machine, a portable information terminal (a portable computer, a mobile phone, a portable game machine, an electronic book, etc.), a clock The present invention can also be applied to an image reproducing device, a monitor, and a television receiver.

In any of the light emitting devices, a housing, an organic EL display, a signal processing circuit, and an input port are included. For example, in the case of a television receiver, a speaker and a tuner are mounted in addition to the above-described configuration. In addition to the above-described configuration, the notebook computer or the portable information terminal has operation keys and operation buttons.
Further, in the case of a video camera or a digital camera, in addition to the above-described configuration, an imaging camera and a writing circuit for storing captured video data in a storage medium are provided. Further, in the case of an electronic device having a communication function such as a mobile phone, in addition to the above-described configuration, a transmission / reception circuit and an antenna as necessary are provided.

(E) The program described in the above embodiment may be distributed by storing it in a storage medium. Note that the storage medium includes a magnetic storage medium, an optical storage medium, a semiconductor storage medium, and the like.
(F) Various modifications can be considered for the above-described embodiments within the scope of the gist of the invention. Various modifications and application examples created based on the description of the present specification are also conceivable.

It is a figure which shows the correspondence of the drive current Iel which flows into an organic EL element, and the light emission brightness | luminance Lel. It is a figure which shows a gradation display characteristic. It is a figure which shows the relationship between the average input data level when not modulating a light emission period, and power consumption. It is a figure which shows the relationship between the average input data level at the time of shortening light emission period fixedly, and power consumption. It is a figure which shows the example of matching of the light emission period with respect to the average input data level APL. It is a figure which shows the power consumption in the case of carrying out the variable control of the light emission period according to an average input data level. It is a figure explaining a flat field display and a white window display. It is a figure which shows the example of a display which a difference in power consumption produces even if an average input data level is the same. It is a figure which shows an example of the correspondence which optimized the light emission period with respect to an average input data level. It is a figure which shows the correspondence of the average input data level and power consumption on optimization conditions. It is a figure which shows the conceptual structural example of an organic electroluminescent display apparatus. It is a figure explaining the example of the dynamic range of the light emission luminance by the variable control of light emission period. It is a figure which shows the internal structural example of the light emission condition optimization circuit. It is a figure explaining the signal level and light emission state of each part in 1 frame period. It is a figure which shows the example of a process sequence performed with the optimization program of light emission conditions. It is a figure explaining the example of the dynamic range of the light emission luminance by the combination of the variable control of a light emission period, and the variable control of a light emission level. It is a figure which shows an example of the correspondence which optimized the light emission period with respect to an average input data level. It is a figure which shows an example of the correspondence which optimized the light emission level with respect to an average input data level. It is a figure which shows the correspondence of the average input data level and power consumption on optimization conditions. It is a figure which shows the conceptual structural example of an organic electroluminescent display apparatus. It is a figure which shows the internal structural example of a data line drive circuit. It is a figure which shows the internal structural example of the light emission condition optimization circuit. It is a figure explaining the signal level and light emission state of each part in 1 frame period. It is a figure which shows the example of a process sequence performed with the optimization program of light emission conditions. It is a figure which shows the other conceptual structural example of an organic electroluminescent display apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,31 Data line drive circuit 3 Scan line selection gate line drive circuit 5 Light emission period control gate line drive circuit 7 Pixel circuit 11, 33 Light emission condition optimization circuit 21 Luminance data converter 23 Average luminance detector 25 Light emission period Look-up table 27 Light emission period control unit 43 Digital / analog conversion circuit 51 Light emission level lookup table 53 Light emission level control unit

Claims (12)

In an active matrix self-luminous display device mounting a drive circuit for controlling the light emission period of each pixel,
An average luminance detection unit for obtaining an average luminance level in units of planes based on display data of all pixels;
A look-up table that associates a shorter light emission period with a larger average luminance level in units of planes. For an average luminance level greater than a reference value, records a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. The lookup table
A light emission period control unit that reads a light emission period corresponding to the average luminance level detected by the average luminance detection unit from a lookup table and outputs a control signal for controlling each pixel to emit light during the light emission period to the drive circuit. And
A self-luminous display device characterized by associating a maximum period that can be allocated as a light-emission period when the average luminance level of a surface unit is 0 to 10 % of a 100% luminance level. The self-luminous display device according to claim 1,
The variable control range of the light emission period is set between 10% and 80% of a 100% light emission period. The self-luminous display device according to claim 1,
A light-emission level control unit that controls the maximum value of the voltage value generated according to display data of each pixel in units of planes so as to decrease nonlinearly as the average luminance level detected in units of planes increases. A self-luminous display device. In a method for optimizing the light emission conditions in an active matrix self-luminous display device in which a drive circuit for controlling the light emission period of each pixel is mounted,
A process for obtaining an average luminance level for each surface based on display data of all pixels;
A look-up table that associates a shorter light emission period with a larger average luminance level in units of planes. For an average luminance level greater than a reference value, records a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A process of reading the light emission period corresponding to the detected average luminance level with reference to the lookup table,
And a process of outputting a control signal for controlling each pixel to emit light during the read emission period to the drive circuit,
A method for optimizing a light emission condition, characterized in that when the average luminance level in units of planes is 0 to 10 % of the 100% luminance level, a maximum period that can be assigned as a light emission period is associated. In an arithmetic device mounted on an active matrix self-luminous display device mounting a drive circuit for controlling the light emission period of each pixel,
A process for obtaining an average luminance level for each surface based on display data of all pixels;
A look-up table that associates a shorter light emission period with a larger average luminance level in units of planes. For an average luminance level greater than a reference value, records a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A process of reading the light emission period corresponding to the detected average luminance level with reference to the lookup table,
A process of outputting a control signal to the drive circuit for controlling each pixel to emit light during the read light emission period,
A program characterized in that when the average luminance level in units of planes is 0 to 10 % of the 100% luminance level, the maximum period that can be allocated as the light emission period is associated. In a light emission condition optimizing device for driving an active matrix type self-luminous display device that implements a drive circuit for controlling the light emission period of each pixel,
An average luminance detection unit for obtaining an average luminance level in units of planes based on display data of all pixels;
A look-up table that associates a shorter light emission period with a larger average luminance level in units of planes. For an average luminance level greater than a reference value, records a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. The lookup table
A light emission period control unit that reads a light emission period corresponding to the average luminance level detected by the average luminance detection unit from a lookup table and outputs a control signal for controlling each pixel to emit light during the light emission period to the drive circuit. And
A light emission condition optimizing device characterized by associating a maximum period that can be assigned as a light emission period when the average luminance level of a surface unit is 0 to 10 % of a 100% luminance level. In an active matrix self-luminous display device mounting a drive circuit for controlling the light emission period of each pixel,
An average luminance detection unit for obtaining an average luminance level in units of planes based on display data of all pixels;
A light emission period calculation unit that associates a shorter light emission period with an increase in the average luminance level of a surface unit, and for an average luminance level greater than a reference value, a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A light emission period calculation unit for calculating a light emission period according to a function having;
A light emission period control unit that outputs, to the drive circuit, a control signal for controlling each pixel to emit light in the light emission period calculated by the light emission period calculation unit;
A self-luminous display device characterized by associating a maximum period that can be allocated as a light-emission period when the average luminance level of a surface unit is 0 to 10 % of a 100% luminance level. The self-luminous display device according to claim 7,
The variable control range of the light emission period is set between 10% and 80% of a 100% light emission period. The self-luminous display device according to claim 7,
A light-emission level control unit that controls the maximum value of the voltage value generated according to display data of each pixel in units of planes so as to decrease nonlinearly as the average luminance level detected in units of planes increases. A self-luminous display device. In a method for optimizing the light emission conditions in an active matrix self-luminous display device in which a drive circuit for controlling the light emission period of each pixel is mounted,
A process for obtaining an average luminance level for each surface based on display data of all pixels;
A light emission period calculation unit that associates a shorter light emission period with an increase in the average luminance level of a surface unit, and for an average luminance level greater than a reference value, a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A process of calculating a light emission period according to a function having,
And a process of outputting a control signal to the drive circuit for controlling each pixel to emit light during the calculated light emission period,
A method for optimizing a light emission condition, characterized in that when the average luminance level in units of planes is 0 to 10 % of the 100% luminance level, a maximum period that can be assigned as a light emission period is associated. In an arithmetic device mounted on an active matrix self-luminous display device mounting a drive circuit for controlling the light emission period of each pixel,
A process for obtaining an average luminance level for each surface based on display data of all pixels;
A light emission period calculation unit that associates a shorter light emission period with an increase in the average luminance level of a surface unit, and for an average luminance level greater than a reference value, a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A process of calculating a light emission period according to a function having,
Executing a process of outputting a control signal to the drive circuit for controlling each pixel to emit light in the calculated light emission period,
A program characterized in that when the average luminance level in units of planes is 0 to 10 % of the 100% luminance level, the maximum period that can be allocated as the light emission period is associated. In a light emission condition optimizing device for driving an active matrix type self-luminous display device that implements a drive circuit for controlling the light emission period of each pixel,
An average luminance detection unit for obtaining an average luminance level in units of planes based on display data of all pixels;
A light emission period calculation unit that associates a shorter light emission period with an increase in the average luminance level of a surface unit, and for an average luminance level greater than a reference value, a correspondence relationship in which the light emission period is nonlinearly shortened as the average luminance level increases. A light emission period calculation unit for calculating a light emission period according to a function having;
A light emission period control unit that outputs, to the drive circuit, a control signal for controlling each pixel to emit light in the light emission period calculated by the light emission period calculation unit;
A light emission condition optimizing device characterized by associating a maximum period that can be assigned as a light emission period when the average luminance level of a surface unit is 0 to 10 % of a 100% luminance level.

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