JP2020060650A - Display driver, display module and display method - Google Patents

Abstract

To control circuit ground voltage ELVSS of a display panel, to reduce power consumption of the display panel.SOLUTION: According to one embodiment, a display driver comprises an image analysis circuit unit, a corrected feature value calculation circuit unit, and a control value generation circuit unit. The image analysis circuit unit analyzes input image data to calculate a feature value. The corrected feature value calculation circuit unit corrects the feature value according to a desired display brightness value, to calculate a corrected feature value. The control value generation circuit unit generates a control value of a circuit ground voltage from the corrected feature value, based on correspondence information indicating the correspondence between the control value of the circuit ground voltage of a display panel and the feature value, for a specific display brightness value.SELECTED DRAWING: Figure 2

Description

  The present disclosure relates to a display driver, a display module and a display method.

  Power consumption can be reduced by controlling the circuit ground voltage of the display panel.

  According to one embodiment, the display driver includes an image analysis circuit unit, a corrected feature value calculation circuit unit, and a control value generation circuit unit. The image analysis circuit unit analyzes the input image data and calculates a feature value. The post-correction feature value calculation circuit unit corrects the feature value according to the desired display brightness value to calculate the post-correction feature value. The control value generation circuit unit, based on the correspondence information indicating the correspondence relationship between the control value of the circuit ground voltage of the display panel and the feature value, for the specific display brightness value, the control value of the circuit ground voltage from the corrected feature value. To generate.

1 is a block circuit diagram schematically showing a configuration example of a display device according to an embodiment. It is a block circuit diagram which shows roughly the example of 1 structure of the circuit ground voltage control circuit part by one Embodiment. 6 is an example of a luminance histogram according to a method in which the image analysis circuit unit according to the embodiment calculates a display luminance upper limit value from input image data. 6 is a graph showing an example of a correspondence relationship between a display brightness value and a circuit ground voltage upper limit value, which the correction coefficient calculation LUT according to one embodiment has. 6 is a graph showing an example of a correspondence relationship between a corrected feature value and a control value of a circuit ground voltage, which the LUT for generating a control value according to an embodiment has. It is a figure which shows an example of the correspondence of a display brightness value and a circuit ground voltage when controlling the brightness | luminance of a display panel using gamma control and emission control by one Embodiment together.

  The display device 1 shown in FIG. 1 according to one embodiment includes a display driver 2, a PMIC (Power Management Integrated Circuit) 3, and a display panel 4. In one embodiment, the display panel 4 and the display driver 2 that drives the display panel 4 are collectively referred to as a display module 11. The display device 1 is configured to display an image corresponding to input image data received from a host (not shown) on the display panel 4. In one embodiment, the display panel 4 is an OLED (Organic Light Emitting Diode) panel.

  In one embodiment, the display panel 4 includes the data lines 41 parallel to each other, the scan lines 42 parallel to each other, the pixel circuits 43 arranged in a matrix at the intersections of the data lines 41 and the scan lines 42, and the scan driver circuit unit. 44 and an emission line 45 parallel to the scan line 42. Each pixel circuit 43 is configured to emit light with a brightness corresponding to a designated gradation value.

  In one embodiment, the scan driver circuit section 44 is configured to drive the scan line 42 and the emission line 45 to select the row of the pixel circuit 43 in which the writing operation is performed. In one embodiment, the scan driver circuit unit 44 drives the emission line 45 according to the emission control signal received from the display driver 2 to control light emission and non-light emission of the pixel circuit 43. The emission control signal is a signal that specifies permission or prohibition of lighting of the pixel circuit 43. The emission control signal is used to inhibit the lighting of the target pixel circuit 43 during the writing operation. The emission control signal is also used to adjust the brightness of the entire display panel 4 by changing the ratio of the time that the pixel circuit 43 emits light.

  In one embodiment, the PMIC 3 receives the control signal from the display driver 2, generates the circuit ground voltage ELVSS and the power supply voltage (not shown), and supplies the circuit ground voltage ELVSS to the display panel 4.

  In one embodiment, the display driver 2 includes an interface 21, an image processing circuit unit 22, and a data driver circuit unit 23. In one embodiment, the interface 21 receives input image data and various control data from an external host and sends the input image data and various control data to the image processing circuit unit 22.

  In one embodiment, the image processing circuit unit 22 receives the input image data from the interface 21 and controls the gamma characteristic of the display module 11 according to the input image data. Here, the gamma characteristic is a characteristic of the correspondence relationship between the gradation value of the input image data and the voltage value output to the pixel circuit 43. In one embodiment, the image processing circuit unit 22 calculates a drive voltage for driving each pixel circuit 43 corresponding to each pixel from the gradation value of each pixel of the received input image data, and the data driver circuit It is transmitted to the unit 23.

  In one embodiment, the data driver circuit unit 23 performs image processing on each of the pixel circuits 43 selected by the scan line 42 via the data line 41 (also referred to as a source line) of the display panel 4. The corresponding drive voltage received from the circuit unit 22 is written.

  In one embodiment, the image processing circuit unit 22 includes a circuit ground voltage control circuit unit 222, and the circuit ground voltage control circuit unit 222 generates a control signal and transmits the control signal to the PMIC 3. The control signal represents information for controlling the circuit ground voltage ELVSS supplied to the display panel 4.

  In one embodiment, the image processing circuit unit 22 includes an emission control circuit unit 221. The emission control circuit unit 221 generates an emission control signal at the timing of writing a drive voltage to the pixel circuit 43 and scan driver. It is transmitted to the circuit unit 44.

  In one embodiment, the PMIC 3 includes the circuit ground voltage generation circuit unit 31, and the circuit ground voltage generation circuit unit 31 performs circuit control based on the control signal received from the circuit ground voltage control circuit unit 222 of the image processing circuit unit 22. The ground voltage ELVSS is generated and supplied to the display panel 4. In one embodiment, the PMIC 3 further includes a power supply voltage generation circuit unit (not shown). The power supply voltage generation circuit section generates a power supply voltage and supplies it to the display panel 4. The power supply voltage generation circuit unit may be provided separately from the PMIC 3.

  In the embodiment shown in FIG. 2, the circuit ground voltage control circuit unit 222 of the image processing circuit unit 22 includes an image analysis circuit unit 50, a corrected feature value calculation circuit unit 51, a control value generation circuit unit 55, and a control unit. And a signal generation circuit unit 57.

  In one embodiment, the image analysis circuit unit 50 analyzes the input image data to be displayed on the display panel 4 and calculates the characteristic value thereof. In one embodiment, the distribution of brightness values for each pixel included in the input image data produces a brightness histogram as shown in FIG. The horizontal axis of the brightness histogram indicates the brightness value of the pixel included in the input image data that is the analysis target. The vertical axis of the brightness histogram represents the total number of pixels having the same brightness value in the input image data as the analysis target. In one embodiment, the image analysis circuit unit 50 analyzes the input image data and calculates a brightness value for each of all the pixels included in the input image data. In one embodiment, the image analysis circuit unit 50 calculates the average value and the maximum value of the calculated brightness values, and calculates the weighted average value of the average value and the maximum value as the feature value of the input image data. In one embodiment, the average value of the brightness values is the average image level APL (Average Picture Level).

  In one embodiment, the weighted average value is calculated based on the weighted ratio. The weight ratio may be stored in the storage device 501 such as a register, and the image analysis circuit unit 50 may read the weight ratio from the storage device 501. The value of the weight ratio may be adjustable by rewriting the weight ratio stored in the storage device 501.

In one embodiment, the weighted ratio is given as a value greater than or equal to 0 and less than or equal to 1, in which case the feature value may be calculated according to Good.
Feature value = weighted average value = (average value x weighted ratio) + (maximum value x (1-weighted ratio))

  In one embodiment, the pixel circuit 43 corresponding to a pixel having a luminance value higher than the feature value in the input image data is displayed with the luminance corresponding to the feature value. On the other hand, the maximum brightness of the display panel 4 can be lowered when displaying the image represented by the input image data. As described later, this leads to raising the circuit ground voltage ELVSS of the display panel 4 and also saving power consumption of the display panel 4.

  In one embodiment, the average value may be used as the feature value. This corresponds to the case where the weighting ratio is equal to 1. In another embodiment, the maximum value may be used as the feature value. This corresponds to the case where the weighting ratio is equal to 0.

  In one embodiment, the corrected feature value calculation circuit unit 51 includes a correction coefficient calculation circuit unit 52 and a correction circuit unit 54. The correction coefficient calculation circuit unit 52 calculates the correction coefficient corresponding to the display brightness value DBV signal representing the desired display brightness value DBV. In one embodiment, the desired display brightness value DBV is a value that specifies the brightness of the screen displayed on the display panel 4. In one embodiment, the display brightness value DBV may be specified by the host according to an operation by the user, or may be determined inside the display driver 2 based on the display brightness value specified by the host. When the user observing the display panel 4 requests the adjustment of the screen brightness, the display brightness value DBV may be adjusted according to the operation of the input device by the user.

  In one embodiment, the correction coefficient calculation circuit unit 52 includes a correction coefficient calculation LUT 53. FIG. 4 illustrates an example of the correction coefficient calculation LUT 53 according to an embodiment. The correction coefficient calculation LUT 53 has correspondence information indicating a correspondence relationship between the display brightness value DBV and the correction coefficient corresponding to the display brightness value DBV. In the graph of FIG. 4, the horizontal axis represents the display brightness value DBV and the vertical axis represents the correction coefficient. Here, the correspondence relationship between the display brightness value DBV and the correction coefficient is based on the gamma characteristic of the display module 11. In the example of FIG. 4, when the display brightness value DBV is half the maximum value, the correction coefficient is about 73%. This corresponds to that when the display brightness value DBV is half the maximum value, the brightness of the display panel 4 is about 73% of the maximum value. The correction coefficient calculation LUT 53 stores the correction coefficient corresponding to the display brightness value DBV based on the gamma characteristic of the display module 11 so that the correction coefficient calculation circuit unit 52 can read the correction coefficient. In one embodiment, the correction coefficient calculation circuit unit 52 inputs a display brightness value DBV signal representing the display brightness value DBV from the outside, reads a correction coefficient corresponding to this display brightness value DBV from the correction coefficient calculation LUT 53, Output to the correction circuit unit 54.

  In one embodiment, the correction circuit unit 54 multiplies the characteristic value and the correction coefficient to calculate the corrected characteristic value. In one embodiment, the correction circuit unit 54 includes a multiplier.

  In one embodiment, the control value generation circuit unit 55 generates the control value of the circuit ground voltage ELVSS based on the corrected feature value. In one embodiment, the control value generation circuit unit 55 includes a control value generation LUT 56, and uses the control value generation LUT 56 to generate a control value for controlling the circuit ground voltage ELVSS.

  In one embodiment, the control value generation LUT 56 indicates the correspondence between the corrected feature value of the input image data and the control value of the circuit ground voltage ELVSS corresponding to the corrected feature value for a specific display brightness value. It has corresponding information. FIG. 5 shows an example of the control value generating LUT 56. The horizontal axis represents the corrected feature value of the input image data, and the vertical axis represents the control value for controlling the circuit ground voltage ELVSS.

  In one embodiment, the correspondence information included in the control value generation LUT 56 is based on the gamma characteristic of the display module 11 when a specific display brightness value is set on the display panel 4. In one embodiment, this particular display brightness value may be the maximum display brightness value that can be set for display module 11.

  In one embodiment, when the corrected feature value is input, the control value generation circuit unit 55 performs a table lookup on the control value generation LUT 56 with reference to the input corrected feature value, and the corrected feature value. The control value of the circuit ground voltage ELVSS corresponding to the value is generated and transmitted to the control signal generation circuit unit 57.

  In one embodiment, the interval of the voltage that the PMIC 3 can output as the circuit ground voltage ELVSS is relatively coarse. In this case, the candidate values of the control value for designating the voltage that can be selected as the circuit ground voltage ELVSS are discretely distributed on the vertical axis of the graph of FIG. In one embodiment, the correspondence information included in the control value generation LUT 56 includes a plurality of candidate values that the PMIC 3 can output as the circuit ground voltage ELVSS.

  In one embodiment, the control value of the circuit ground voltage ELVSS is a corrected feature value in the gamma characteristic of the display module 11 in a state where a specific display brightness value is set on the display panel 4 among the plurality of candidate values. Is determined so as not to exceed the voltage value corresponding to. In one embodiment, this control value may be determined to exceed the voltage value corresponding to the maximum brightness value of the input image data based on this gamma characteristic. At this time, among the pixels included in the input image data, the pixel circuit 43 corresponding to a pixel having a luminance value larger than the characteristic value and equal to or less than the maximum luminance value is displayed with the luminance corresponding to the characteristic value. However, on the other hand, the power consumption of the display panel 4 can be saved.

  In one embodiment, the control value of the circuit ground voltage ELVSS is a post-correction characteristic based on the gamma characteristic of the display module 11 in a state where a specific display brightness value is set on the display panel 4 among the plurality of candidate values. It is determined to be maximum within a range not exceeding the voltage value corresponding to the value.

  In one embodiment, the control signal generation circuit unit 57 generates a control signal representing a control value and transmits the control signal to the PMIC 3. In one embodiment, the control signal is a pulse signal. In this embodiment, by assigning a number to each of the discretely distributed candidate values, which number of candidate values the control value is equal to is represented by the number of pulses included in one pulse signal. be able to.

  In one embodiment, the control signal is transmitted to the circuit ground voltage generation circuit unit 31 of the PMIC 3. The circuit ground voltage generation circuit unit 31 generates the circuit ground voltage ELVSS represented by the control signal according to the control signal and supplies the circuit ground voltage ELVSS to the display panel 4.

  According to the circuit ground voltage control circuit unit 222 as described above, the control value of the circuit ground voltage ELVSS is set to be output in the case of a specific display brightness value, for example, one case where the display brightness value is 100%. When the display brightness value DBV is different, the control value generating circuit unit 55 can appropriately generate the control value of the circuit ground voltage ELVSS at any display brightness value DBV lower than 100%.

  In the embodiment, when controlling the brightness of the display panel 4, not only the gamma characteristic control but also the emission control via the emission control circuit unit 221 may be used together. FIG. 6 shows an example of the display brightness value DBV set on the display panel 4. In one embodiment, when the display brightness value DBV is greater than or equal to the predetermined threshold value T, the display device 1 controls the brightness of the display panel 4 by controlling the gamma characteristic of the display module 11, and further, FIG. As shown in, the circuit ground voltage ELVSS is controlled so as to match the gamma characteristic. In the range of values that the display brightness value DBV can take, a region where such control is performed is referred to as a gamma control region in FIG. The gamma control area in FIG. 6 is equal to the right half of FIG.

  When the display brightness value DBV is less than or equal to the predetermined threshold value T, the display module 11 changes the ratio of the light emission period and the non-light emission period of each pixel circuit 43 of the display panel 4 via the emission control signal. The brightness of the display panel 4 is controlled. In the range of values that the display brightness value DBV can take, a region where such control is performed is referred to as an emission control region in FIG. In the emission control region of FIG. 6, the circuit ground voltage ELVSS is uniform.

  In one embodiment, the brightness of the display panel 4 is controlled by simultaneously controlling the gamma characteristic of the display module 11 and controlling the ratio of the light emitting period and the non-light emitting period of each pixel circuit 43 of the display panel 4. Is also possible. In one embodiment, the brightness of the display panel 4 is controlled by the gamma characteristic control, the emission control, or both of the controls are used together. It is performed according to the brightness value DBV.

  Although various embodiments of the present disclosure have been specifically described above, the technology described in the present disclosure can be implemented with various modifications. For example, the above embodiment can be applied to various display panels having a configuration in which the circuit ground voltage is supplied to each pixel circuit, in addition to the OLED display panel.

DESCRIPTION OF SYMBOLS 1 display device 11 display module 2 display driver 21 interface 22 image processing circuit unit 221 emission control circuit unit 222 circuit ground voltage control circuit unit 23 data driver circuit unit 3 PMIC
31 circuit ground voltage generation circuit section 4 display panel 41 data line 42 scan line 43 pixel circuit 44 scan driver circuit section 45 emission line 50 image analysis circuit section 501 storage device 51 corrected feature value calculation circuit section 52 correction coefficient calculation circuit section 53 LUT for calculating correction coefficient
54 correction circuit unit 55 control value generation circuit unit 56 control value generation LUT
57 Control signal generation circuit section

Claims (20)

An image analysis circuit unit that analyzes input image data and calculates a feature value,
A corrected characteristic value calculation circuit unit that corrects the characteristic value according to a desired display luminance value to calculate a corrected characteristic value,
A control value of the circuit ground voltage is generated from the corrected feature value based on first correspondence information indicating a correspondence relationship between the control value of the circuit ground voltage of the display panel and the feature value for a specific display brightness value. A control value generation circuit unit,
Display driver. Further comprising a first LUT having the first correspondence information indicating the correspondence between the control value of the circuit ground voltage of the display panel and the characteristic value for the specific display brightness value,
The display driver according to claim 1, wherein the control value generation circuit unit refers to the first LUT to generate the control value of the circuit ground voltage from the corrected feature value. The first correspondence information includes a plurality of candidate values that the PMIC can output as the circuit ground voltage,
The control value of the circuit ground voltage exceeds the voltage value corresponding to the corrected characteristic value based on the gamma characteristic in the state where the specific display luminance value is set on the display panel from the plurality of candidate values. The display driver according to claim 2, wherein the display driver is determined so as not to exist and to exceed a voltage value corresponding to the maximum luminance value of the input image data in the gamma characteristic. The first correspondence information includes a plurality of candidate values that the PMIC can output as the circuit ground voltage,
The control value of the circuit ground voltage exceeds the voltage value corresponding to the corrected characteristic value based on the gamma characteristic in the state where the specific display luminance value is set on the display panel from the plurality of candidate values. The display driver according to claim 2, wherein the display driver is determined to have a maximum value in a non-existence range. The display driver according to claim 3, wherein the specific display brightness value is a maximum display brightness value that can be set in the display panel. The corrected characteristic value calculation circuit unit calculates a correction coefficient based on the desired display brightness value, and calculates the corrected characteristic value based on the characteristic value and the correction coefficient. The display driver according to 1 above. Further comprising a second LUT having second correspondence information indicating a correspondence relationship between the desired display brightness value and the correction coefficient,
The display driver according to claim 6, wherein the post-correction feature value calculation circuit unit calculates the correction coefficient from the desired display brightness value with reference to the second LUT. The display driver according to any one of claims 3 to 7, wherein the characteristic value is a weighted average value of an average value and a maximum value of luminance values in each pixel of the input image data. The display driver according to claim 6, wherein the corrected characteristic value calculation circuit unit includes a multiplier that multiplies the characteristic value and the correction coefficient to calculate the corrected characteristic value. The display driver according to claim 3, further comprising a control signal generation circuit unit that generates a control signal that transmits the control value of the circuit ground voltage to the PMIC. An emission control circuit unit for controlling the brightness of the display panel by changing the ratio of the light emitting period and the non-light emitting period in the pixel circuit included in the display panel according to the display brightness value set in the display panel. The display driver according to claim 1, further comprising: A display panel and a display driver for driving the display panel,
The display driver is
An image analysis circuit unit that analyzes input image data and calculates a feature value,
A corrected characteristic value calculation circuit unit that corrects the characteristic value according to a desired display luminance value to calculate a corrected characteristic value,
Control for generating a control value of the circuit ground voltage from the corrected feature value based on correspondence information indicating a correspondence relationship between the control value of the circuit ground voltage of the display panel and the feature value for a specific display brightness value. A value generation circuit section,
Display module. Further comprising an LUT having the correspondence information indicating the correspondence between the control value of the circuit ground voltage of the display panel and the characteristic value for the specific display brightness value,
The display module according to claim 12, wherein the control value generation circuit unit refers to the LUT to generate the control value of the circuit ground voltage from the corrected feature value. Analyzing the input image data to calculate the feature value,
Calculating the corrected characteristic value by correcting the characteristic value according to a desired display brightness value,
A control value of the circuit ground voltage is generated from the corrected feature value based on first correspondence information indicating a correspondence relationship between the control value of the circuit ground voltage of the display panel and the feature value for a specific display brightness value. That
Display method including. For the specific display brightness value, referring to the first LUT having the first correspondence information indicating the correspondence between the control value of the circuit ground voltage of the display panel and the feature value, the circuit is calculated from the corrected feature value. The display method according to claim 14, wherein the control value of the ground voltage is generated. The first correspondence information includes a plurality of candidate values that the PMIC can output as the circuit ground voltage,
The control value of the circuit ground voltage exceeds the voltage value corresponding to the corrected characteristic value based on the gamma characteristic in the state where the specific display luminance value is set on the display panel from the plurality of candidate values. 16. The display method according to claim 15, wherein the display method is determined such that the voltage value does not exist and exceeds the voltage value corresponding to the maximum luminance value of the input image data in the gamma characteristic. The first correspondence information includes a plurality of candidate values that the PMIC can output as the circuit ground voltage,
The control value of the circuit ground voltage does not exceed the voltage value corresponding to the corrected characteristic value based on the gamma characteristic in the state where the specific display brightness value is set on the display panel from the plurality of candidate values. The display method according to claim 15, wherein the display method is determined to be maximum in the range. The display method according to any one of claims 14 to 17, wherein the specific display brightness value is a maximum display brightness value that can be set in the display panel. The calculation of the corrected feature value is
Calculating a correction coefficient based on the display brightness value set in the display panel,
The display method according to claim 14, further comprising: calculating the corrected characteristic value based on the characteristic value and the correction coefficient. Calculating the correction factor is
The display brightness value set in the display panel is referred to by referring to a second LUT having second correspondence information indicating a correspondence relationship between the display brightness value set in the display panel and the circuit ground voltage of the display panel. The display method according to claim 19, further comprising: calculating the correction coefficient from

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