The present invention relates to adjusting contrast and brightness of a display device.
One example of a pixel circuit for an active type OLED display device is shown in
The gate of the TFT1 is connected to an auxiliary capacitor power supply Vcs via an auxiliary capacitor C, as well as to a data line Data for supplying a voltage based on pixel data (luminance data) via an n-channel TFT2 for selection. The gate of the TFT2 is connected to a gate line Gate extending in a horizontal direction.
At the time of display, the gate line is made H, and the TFT2 of a corresponding line is turned on. In this state pixel data is supplied to the data line Data, and this charges the auxiliary capacitor C. The TFT1 is then driven by a voltage in response to the pixel data, and the current through the TFT1 flows in the OLED element 3.
Here, the amount of emitted light and the current in the OLED element 3 has a substantially proportional relationship, but current begins to flow in the TFT1 when a voltage difference from the gate−PVdd exceeds a specified threshold voltage Vth. Pixel data supplied to the data line Data is added to the voltage (Vth) so that drain current starts to flow in the vicinity of image black level. Also, the amplitude of an image signal is such that there is specified luminance in the vicinity of a white level.
Here, since the luminance of light emitted from the OLED element 3 is proportional to the current flowing in the element, as described above, in order to drive a panel it is necessary to have a power supply capable of providing the current required when carrying out display for an image having maximum luminance over the entire surface. Accordingly, a power supply is required that has considerable surplus capacity compared to the power supply capacity required under normal usage conditions.
On the other hand, with a display device for displaying mainly natural images, used in a digital camera or video camera, the average level of image data is normally about 25%, and the maximum current of the power supply is rarely utilized.
There have also been proposed methods of calculating a histogram and average luminance in image frame units and generating panel drive data based on the results, with the intention of improving image quality and conserving power (see Japanese Patent Laid-open No. Hei. 7-322179 and Japanese Patent Laid-open No. 2002-116732.
With a display device having contrast and brightness adjustment built-in, it is necessary to determine the capacity of the power supply section assuming adjustment to the respective maximum values. There is a problem that the capacity of the power supply has to be significantly increased.
It is an object of this invention to provide contrast and brightness adjustment in a display device which doesn't require a substantial increase in the capacity of the power supply.
This object is achieved by a display device for carrying out image display on a display panel by controlling current flowing in display elements for each pixel based on image data, comprising:
display setting circuitry for setting a relationship between image data and current values for current flowing in display elements in response to an input adjustment signal, to set contrast or brightness;
estimation circuitry for estimating panel current flowing in all pixels when carrying out display for the display panel based on the image data; and
current control means for controlling actual panel current by correcting the set contrast or brightness based on the panel current estimated by the estimation means.
In this way, according to the present invention the set contrast or brightness is corrected based on estimated panel current. The panel current can be controlled to specified values or less.
Also, if the panel current estimated by the estimation means does not exceed a specified set value, correction of contrast or brightness by the current control means is preferably not carried out.
Further, if the panel current estimated by the estimation means exceeds the specified set value, the current control means preferably corrects the contrast or brightness such that actual panel current at the time the estimated panel current becomes maximum panel current coincides with the maximum panel current.
In this way, if the estimated panel current is small, the present invention controls actual panel current to less than the maximum panel current.
The current control means can store a coefficient defining the relationship between estimated panel current required in correction of contrast or brightness, and correction of contrast or brightness, and corrects the contrast or brightness using this coefficient.
Actual current consumption is detected at the factory, and if an optimum value for this coefficient is inspected and stored, then even if there are variations in efficiency for each panel, variations in maximum consumed current can be suppressed for each display device.
a) is a drawing showing a relationship between panel current Ical obtained through calculation and actual panel current I;
b) is a drawing showing a relationship between panel current I and maximum luminance;
a) is a drawing showing a relationship between panel current Ical obtained through calculation and actual panel current I; and
b) is a drawing showing a relationship between panel current I and maximum luminance.
When contrast or brightness have been raised, rise in contrast or brightness at regions where panel current is large is suppressed, so that maximum current flowing in the panel does not exceed a set value.
The OLED panel 18 is made up of the pixel circuits shown in
With this embodiment, the image signal is supplied to a panel current calculating block 20. This panel current calculating block 20 obtains panel current Ical, being the sum total of current flowing in all pixels of the OLED panel 18, from data for a single frame of a plurality of frames of an image for driving the OLED panel 18. As the panel current Ical, instead of the sum total for one frame it is also possible to use an average value for one frame or a sum total or average value for a plurality of frames.
The panel current Ical acquired in the panel current calculating block 20 is then supplied to a contrast/brightness coefficient correction circuit 22. This contrast/brightness coefficient correction circuit 22 corrects set values for contrast (C) and brightness (B) input by a user based on panel current Ical calculated from the image signal, supplies a corrected contrast coefficient C′ to the multiplier 10 and supplies a corrected brightness coefficient B′ to the adder 12. As a result, the image signal supplied to the gamma correction circuit 14 has been subjected to contrast and brightness adjustment using the corrected contrast coefficient C′ and brightness coefficient B′.
A description will now be given for the contrast coefficient C′ and the brightness coefficient B′.
With an active matrix type OLED panel 18, data for each pixel is held for the duration of one frame by a capacitor (auxiliary capacitor) added to the gate of a TFT for normal pixel drive. As a result, when current flowing in a pixel has a proportional relationship with respect to image data, the total current of the pixel section of the OLED panel 18 at a particular point in time is proportional to the total image data for one frame that has been input from that point until one frame before. By measuring this proportional constant in advance, it is possible to calculate total current (panel current Ical) of pixel section in a frame unit from the image data.
Here, the calculated panel current Ical is a value calculated with contrast C and brightness B set to C=1 and B=0.
In
Ical=Dframe/(k·E)
Here, k is gamma correction input data divided by luminance, and E is luminance divided by current flowing in one pixel.
The relationship between panel current (Ical) obtained in this way and the actual panel current (I) is shown in
In this way, if C=1 and B=0, for initial setting, then as shown by the straight line m, panel current I actually flowing increases linearly in response to panel current Ical calculated in response to image data. Also, with characteristics n and o, B=0, and passes through the origin, but since the value of C is larger for the case of o, the gradient is large. Also, with characteristics p and q, the entire characteristic is shifted because of the value of B.
Also, as shown in
Natural images taken with a digital camera or video camera have an average pixel level that is less than 50%, except in special cases, because of effects such as automatic exposure. As a result, for images having an average level that is a particular value or more, that is, images having a power consumption value of a particular value or more, even if the rate of increase in contrast adjustment is reduced, there is no effect for a lot of images.
In this way, with the panel current less than a predetermined specified value Icalx, input contrast C and brightness B are supplied as they are to the multiplier 10 and adder 12 in the contrast/brightness coefficient correction circuit 22. As a result, display is carried out at the set luminance.
On the other hand, when Ical>Icalx, C′0 is selected, contrast is corrected and display is carried about using the corrected contrast. That is, contrast C′ has a small value compared to C, and actual panel current I is suppressed. As a result, in this case, maximum luminance of the display pixels is suppressed.
Specifically, if the number of pixels for one frame is N, when the panel current resulting from calculation Ical≦Icalx, the actual panel current I is:
I=(C·Dframe+B′·N)′(k·E)
and if Ical>Icalx, the actual panel current I is:
I=(C′0·Dframe+B′·N)/(k·E)
In the example of
A description will now be given of the calculation of corrected contrast C′0 in the contrast/brightness coefficient correction circuit 22. Calculation is carried out in the contrast/brightness coefficient correction circuit 22 using the following equation.
C′0=C−(C+B/(k·Lw0)−a)·(Ical−Icalx)/(Imax−Icalx) (1)
Here, C is contrast setting value, B is brightness setting value, Lw0 is maximum luminance at initial setting time (C=1, B=0), a is luminance when panel current displaying all white becomes Imax divided by Lw0, Ical is panel current derived from linear conversion of original image data, Imax is maximum current flowing in the panel, Icalx is a value for Ical at the point where maximum luminance begins to decrease, and can be arbitrarily set, and k is gamma correction input data divided by luminance.
As shown in
Also, in the case where it is assumed that B=0, if Icalx is exceeded, (C−a) is divided and subtracted from contrast C until Imax is reached, for Ical=Imax, C′0=a becomes true, and the panel current I actually flowing at this time also becomes I=Imax. With respect to brightness B also, from when calculated panel current Ical=Icalx until Ical=Imax, when division is carried out and Ical=Imax becomes true, actual panel current becomes I=Imax.
In this way, the relationship between panel current Ical derived from linear conversion of original image data values and actual panel current I becomes as shown in
Here, the rate of decrease of maximum luminance differs depending on light emission efficiency, such as q1, q2 and q3, and becomes a=a1, a=a2 and a=a3. Specifically, even if there are variations in light emission efficiency for each panel, the maximum consumed current of the panel does not vary, and it is possible to make the maximum luminance in a range where average luminance is low the same. Accordingly, even if there are variations in panel efficiency it is possible to suppress variations in maximum consumed current of every set by adjusting a at the time of shipping.
Here, besides values for a, values such as Lw0 and Icalx required in the calculation of C′0 are stored in a non-volatile memory provided inside the device, such as inside the contrast/brightness coefficient correction circuit 22, at the factory. As a result, the above described calculation becomes possible at the time of use. Values such as Er, Eg and Eb required for the calculation of I are also similarly stored in non-volatile memory. With respect to k, it is possible to use a value that has been stored in the gamma correction circuit 14. It is also possible to have a configuration where values are obtained using automatic calculation based on current when some or all of these set values are used or measured luminance values.
The maximum luminance when panel current is small is determined using set values of contrast and brightness, and the luminance at this time becomes x·Lw0.
Also, when contrast and brightness have been set so that 100% luminance becomes less than or equal to a·Lw0, maximum luminance is constant regardless of the current value.
Icalx can be set arbitrarily, but is preferably set so that when C and B have been set to maximum values, actual panel current Ix at that time is less than or equal to Imax.
In the case of a panel for displaying colors by driving RGB pixels with separate signal sources, since light emission efficiencies Er, Eg and Eb for each of RGB generally vary for each color, the total current I of the OLED panel 18 is calculated using the following equation.
I=Rframe/Er+frame/Eg+Bframe/Eb (2)
Here, Rframe is the total of R image data for one frame, Gframe is the total of G image data for one frame, Bframe is the total of B image data for one frame, Er is R luminance divided by current flowing in one R pixel, Eg is G luminance divided by current flowing in one G pixel, and Eb is B luminance divided by current flowing in one B pixel.
In this way, according to this embodiment, total current for one frame of the OLED panel 18 is estimated based on input image data, and estimate total panel current Ical reaches a predetermined value Icalx, and the set value C is used as it is without carrying out correction of contrast C.
On the other hand, if panel total current Ical exceeds a specified value, correction is added to the contrast C, and corrected contrast value C′ is varied in accordance with the magnitude of panel total current Ical so that panel current I actually flowing at the time total current Ical from calculation becomes permitted maximum current Imax, and control is carried out so that actual panel current I does not exceed Imax.
Specifically, panel current is made to not exceed a predetermined value, and it is possible to vary contrast and brightness by suppressing reduction in image quality to a minimum.
With the embodiment described above, no correction has been carried out for brightness B supplied to the adder 12, and brightness was taken into consideration at the time of correcting contrast C. However, it is also possible to have direct correction of B. For example, during the period from when Ical=Icalx to Ical=Imax, B is continuously divided so as to become zero, and the term for B can then be deleted from the calculation of contrast C. Specifically, the term (C+B/(k·Lw0)) in equation (1) above can also be included in conversion of B′ from B. It is also possible to use contrast C as it is and to include this correction in conversion from B to B′.
As has been described above, according to the present invention, set contrast and brightness are corrected based on estimated panel current. In this way, it is possible to suppress panel current to a specified value or less.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
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