1. Field of the Invention
The present invention relates to a drive apparatus for a display panel in which a large number of light emitting elements as pixels are arranged, for example, in a matrix pattern, and in particular to a drive apparatus and a drive method for a light-emitting display panel for controlling display brightness according to a lighting rate of the above-mentioned pixel.
2. Description of the Related Art
For example, in PDP (plasma display panel) etc., finding an average brightness level (or APL=Average Picture Level) of a picture signal to be displayed, a PLE (Peak Luminance Enhancement) control means is employed which controls the display brightness of the above-mentioned picture signal based on this average picture level.
As for the above-mentioned PLE control means, in the case where the average picture level is small (or when the whole picture is dark) with respect to signal having even the same brightness level, a peak brightness level is set to be high so that high brightness display may be provided. On the other hand, in the case where the average picture level is high (when the whole picture is bright), the peak brightness level is lowered so as to inhibit power consumption. By carrying out PLE control in this way, it is possible to realize low power consumption and also possible to display an image of good contrast.
As described above, the display apparatus provided with the PLE control means which finds the average picture level APL of the picture signal to be displayed and controls the display brightness by this APL is disclosed in patent documents 1 and 2 as listed below, for example.
[Patent document 1] Japanese Patent Publication (KOKAI) No. H9-281927
[Patent document 2] Japanese Patent Publication (KOKAI) No. 2001-175220
Incidentally, when performing the above-mentioned PLE control, and when picture signals are R (red), G (green), and B (blue) signals, the picture signal is converted into gray scale (brightness) data to find the above-mentioned APL value. In this case, even if the values of R, G, and B signals are the same value, when a color picture signal is converted into gray scale, the resultant brightnesses (apparent whiteness) on the gray scale are different from one another. For example, in NTSC, an emission brightness ratio (R:G:B) (for respective colors) is about 3:6:1.
Therefore, when converting the color picture signal into a gray scale signal, weighting is conventionally carried out according to an emission brightness rate (proportion) of each color at the time of displaying the gray scale, and a means for calculating the above-mentioned APL is employed.
The above-mentioned brightness rate weighting means 31 and the averaging means 32 constitute an APL calculation means 33, and a peak brightness control means 34 is controlled by APL output from this APL calculation means 33. The above-mentioned PLE control is realized such that peak brightness of a composite picture signal is controlled by the above-mentioned APL output in the above-mentioned peak brightness control means 34. In other words, the above-mentioned APL calculation means 33 and the above-mentioned peak brightness control means 34 constitute a PLE control means 35.
In the above-mentioned brightness rate weighting means 31, in order to simplify the explanation of its operation, it is assumed that a brightness ratio (luminance proportions) of the pixels of the respective colors required to obtain the achromatic color (white color) is R:G:B=3:6:1, for example. In this case, the picture signal of R, the picture signal of G, and the picture signal of B are respectively multiplied and weighted by 3/(3+6+1), 6/(3+6+1), and 1/(3+6+1).
The picture signals respectively weighted in the above-mentioned brightness rate weighting means 31 are added together to calculate an average value by the above-mentioned averaging means 32. This average value is outputted from the APL calculation means 33 as APL (average picture level), and is supplied as a control signal to the above-mentioned peak brightness control means 34. In other words, the above-mentioned APL is calculated by the following Equation 1.
APL=R×3/(3+6+1)+G×6/(3+6+1)+B×1/(3+6+1) (Equation 1)
Incidentally, in these days, a display panel has been realized which can be thinned and provide display of a high quality and uses an organic EL (electroluminescence) element taking advantage of a characteristic of being a self-emitting type element. There is also part of the background that a light-emitting functional layer of the element employs an organic compound which can expect a good light-emission property, so that the organic EL display panel has as high an efficiency and long a lifetime as can be put into practical use.
The above-mentioned organic EL element can be electrically represented in an equivalent circuit as shown in
As for this organic EL element, when a light-emitting drive voltage is applied, charge which is equivalent to capacitance of the element first flows into an electrode as displacement current and is accumulated. Then, if a fixed voltage (light-emitting threshold voltage=Vth) inherent to the element is exceeded, electric current begins to flow from one electrode (anode side of the diode component E) into an organic layer which constitutes a light-emitting layer. Thus, the EL element may be considered to emit light at an intensity proportional to the electric current.
In other words, when the drive voltage is not greater than the light-emitting threshold voltage Vth, electric current little flows into EL element, and does not emit light. Therefore, as shown by a solid line in
Furthermore, it is also known that the brightness properties of the organic EL element generally change with temperature as shown by a dashed line in
Furthermore, the above-mentioned EL element has a problem that luminous efficiencies with respect to the drive voltages differ according to the luminescence colors. The luminous efficiencies of EL elements, which may currently be put into practical use, emitting respectively the above-mentioned R, G, and B are in a situation where the luminous efficiency of G is generally higher and the luminous efficiencies of R and B are lower as shown in
As described above, when trying to realize the above-mentioned PLE control in the display apparatus for a color display panel in which a color display pixel is constituted by a light emitting element, as a sub-pixel, represented by the organic EL element whose luminous efficiency differs for each color, a technical problem to be described below may arise.
In other words, since the luminous efficiency of the element for each color differs, if brightness is controlled (PLE control) based on the APL value calculated only from the picture signal and the brightness rate as can be seen from a structure shown in
For example, assuming that the brightness ratio is R:G:B=3:6:1 as described above, the luminous efficiency of a blue (B) light emitting element is the lowest and that only the above-mentioned blue light emitting element is fully lit, the APL output at this time is APL=B×1/(3+6+1) according to the above-mentioned Equation 1, and is determined to be “a very dark screen”. Therefore, a problem arises in that although blue has the lowest luminous efficiency, it is controlled so that the peak brightness is to rise, thus increasing power consumption and damaging the effect of the above-mentioned PLE which lowers the peak brightness at the time of the rate of high lighting, and inhibits the power consumption.
Further, as described above, since the emission brightness has characteristics depending on a current value in the display panel using the EL element as a display pixel, power consumption considerably varies depending on the lighting rate of the pixel according to the picture signal to be displayed. In other words, as shown in
Therefore, there is a problem in that a power supply circuit for supplying drive current to the above-mentioned display panel needs to secure output capacity which is sufficient for supplying predetermined drive current to each pixel, when the lighting rate of the above-mentioned pixel is the maximum (100%), and that a size of each component used for the power supply circuit and the whole size are inevitably increased.
In addition, a PLE controlling method which inhibits an amount of current supplied to the display panel by controlling the lighting rate according to display image data is disclosed in patent document 3 listed below.
[Patent document 3] Japanese Patent Publication (KOKAI) 2005-189636
The present invention is made in view of the above-mentioned technical problems, and a first object is to provide a drive apparatus and a drive method for a light-emitting display panel in a drive apparatus for a color display panel constituted by the light emitting elements whose luminous efficiencies for respective colors differ from one another, which can prevent an unsuitable APL value (lighting rate) in view of the field of power consumption from being calculated due to a difference in luminous efficiency.
Further, basically following the above-mentioned PLE controlling method, a second object of the present invention is to provide a drive apparatus and a drive method of for light-emitting display panel, which can solve a problem that the size of the component in a power supply unit is increased, as described above.
In order to attain the above-mentioned first object, a first preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention is a drive apparatus for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, the drive apparatus including an APL calculation means for calculating an average picture level (APL) from the above-mentioned picture signal, and a peak brightness control means for variably controlling peak brightness in the above-mentioned picture signal according to APL calculated by the above-mentioned APL calculation means, wherein the above-mentioned APL calculation means is provided with a weighting means for weighting a picture signal of each color according to a light emitting current rate of each color at the time of displaying a gray scale.
Further, a second preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention in order to attain the above-mentioned first object is a drive apparatus for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, the drive apparatus including an APL calculation means for calculating an average picture level (APL) from the above-mentioned picture signal, and a peak brightness control means for variably controlling peak brightness in the above-mentioned picture signal according to APL calculated by the above-mentioned APL calculation means, wherein the above-mentioned APL calculation means is provided with a weighting means for weighting a picture signal of each color according to a light emitting power rate of each color at the time of displaying a gray scale.
On the other hand, in order to attain the above-mentioned first object, a first preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means performs weighting operation for weighting a picture signal of each color according to a light emitting current rate of each color at the time of displaying a gray scale.
Further, in order to attain the above-mentioned first object, a second preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means performs weighting operation for weighting a picture signal of each color according to a light emitting power rate of each color at the time of displaying a gray scale.
Furthermore, in order to attain the above-mentioned first object, a third preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means selectively performs either first weighting operation for weighting a picture signal of each color according to a light emitting current rate of each color at the time of displaying a gray scale, or second weighting operation for weighting the picture signal of each color according to an emission brightness rate of each color at the time of displaying the gray scale.
Still further, in order to attain the above-mentioned first object, a fourth preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means selectively performs either first weighting operation for weighting a picture signal of each color according to a light emitting power rate of each color at the time of displaying a gray scale, or second weighting operation for weighting the picture signal of each color according to an emission brightness rate of each color at the time of displaying the gray scale.
Further, in order to attain the above-mentioned first object, a fifth preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means performs first weighting operation for weighting a picture signal of each color according to a light emitting current rate of each color at the time of displaying a gray scale and second weighting operation for weighting the picture signal of each color according to an emission brightness rate of each color at the time of displaying the gray scale.
Further, in order to attain the above-mentioned first object, a sixth preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which light emitting elements of a plurality of colors are arranged in a matrix pattern and each of the above-mentioned light emitting elements is selectively caused and driven to emit light based on a picture signal, wherein an average picture level (APL) is calculated from the above-mentioned picture signal by an APL calculation means and APL information data calculated by the above-mentioned APL calculation means are supplied as a control signal to a peak brightness control means, so as to perform variable control operation for peak brightness for variably controlling the peak brightness in the above-mentioned picture signal; when calculating the above-mentioned average picture level, the above-mentioned APL calculation means performs first weighting operation for weighting a picture signal of each color according to a light emitting power rate of each color at the time of displaying a gray scale and second weighting operation for weighting the picture signal of each color according to an emission brightness rate of each color at the time of displaying the gray scale.
Further, in order to attain the above-mentioned second object, a first preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention is a drive apparatus for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, and one frame (period) is divided into a plurality of sub-frames to realize gradation control by selecting the above-mentioned sub-frames (periods) and by summing the lighting periods of the pixel within one frame period, the above-mentioned drive apparatus including a lighting rate calculation means for calculating a lighting rate of the pixel in the above-mentioned display panel to be lit and driven based on image data, and a brightness control means for controlling emission brightness of each of the above-mentioned pixels according to the lighting rate obtained by the above-mentioned lighting rate calculation means, wherein emission brightness of each of the above-mentioned pixels is controlled by controlling proportions of the lighting period and a non-lighting period of the pixel in one frame period based on the above-mentioned lighting rate.
Further, in order to attain the above-mentioned second object, a second preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention is a drive apparatus for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, the above-mentioned drive apparatus including a scanning driver for selectively setting each of the above-mentioned scanning lines as a scanning selection potential or a non-scanning selection potential, and a data driver for selectively connecting each of the above-mentioned data lines to a lighting driving power supply or a non-lighting driving power supply, the above-mentioned drive apparatus including a lighting rate calculation means for calculating a lighting rate of the pixel in the above-mentioned display panel to be lit and driven based on image data, and a brightness control means for controlling emission brightness of each of the above-mentioned pixels according to the lighting rate obtained by the above-mentioned lighting rate calculation means, wherein emission brightness of each of the above-mentioned pixels is controlled by controlling a period when the above-mentioned lighting driving power supply is connected with the above-mentioned data line based on the above-mentioned lighting rate.
Further, in order to attain the above-mentioned second object, a third preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention is a drive apparatus for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, and an image is displayed by selectively lighting and driving the above-mentioned pixels, the above-mentioned drive apparatus including a lighting rate calculation means for calculating a lighting rate of the pixel in the above-mentioned display panel to be lit and driven based on image data, and a brightness control means for controlling emission brightness of each of the above-mentioned pixels according to the lighting rate obtained by the above-mentioned lighting rate calculation means, wherein the above-mentioned brightness control means controls emission brightness of each of the above-mentioned pixels by controlling an output value of a drive power supply to be provided for each of the above-mentioned pixels based on the above-mentioned lighting rate.
Further, in order to attain the above-mentioned second object, a fourth preferred fundamental aspect in the drive apparatus for the light-emitting display panel in accordance with the present invention is a drive apparatus for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, and an image is displayed by selectively lighting and driving the above-mentioned pixels, the above-mentioned drive apparatus including a lighting rate calculation means for calculating a lighting rate of the pixel in the above-mentioned display panel to be lit and driven based on image data, and a brightness control means for controlling emission brightness of each of the above-mentioned pixels according to the lighting rate obtained by the above-mentioned lighting rate calculation means, wherein the above-mentioned brightness control means is arranged to control the emission brightness of each of the above-mentioned pixels by performing a conversion process for the above-mentioned image data based on said lighting rate.
Now, in order to attain the second object of the above, a first preferred fundamental aspect in the drive method of the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which pixels each having a light emitting element are arranged in intersections where a plurality of data lines intersect with a plurality of scanning lines, and one frame (period) is divided into a plurality of sub-frames to realize gradation control by selecting the above-mentioned sub-frames (periods) and by summing the lighting periods of the pixel within one frame period, wherein emission brightness of each of the above-mentioned pixels is controlled by calculating a lighting rate of the pixel in the above-mentioned display panel to be lit and driven based on image data, and by controlling proportions of the lighting period and a non-lighting period of the pixel in one frame period based on the above-mentioned calculated lighting rate.
Further, in order to attain the above-mentioned second object, a second preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, the above-mentioned display panel including a scanning driver for selectively setting each of the above-mentioned scanning lines as a scanning selection potential or a non-scanning selection potential, and a data driver for connecting each of the above-mentioned data lines to a lighting driving power supply or a non-lighting driving power supply, wherein a lighting rate of the pixel in the above-mentioned display panel to be lit and driven is calculated based on image data, and emission brightness of each of the above-mentioned pixels is controlled by controlling a period when the above-mentioned lighting driving power supply is connected with the above-mentioned data line based on the above-mentioned calculated lighting rate.
Further, in order to attain the above-mentioned second object, a third preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, and an image is displayed by selectively lighting and driving the above-mentioned pixels, wherein a lighting rate of the pixel in the above-mentioned display panel to be lit and driven is calculated based on image data, and emission brightness of each of the above-mentioned pixels is controlled by controlling an output value of a drive power supply to be provided for each of the above-mentioned pixels based on the above-mentioned calculated lighting rate.
Further, in order to attain the above-mentioned second object, a fourth preferred fundamental aspect in the drive method for the light-emitting display panel in accordance with the present invention is a drive method for a light-emitting display panel in which pixels each having a light emitting element are arranged at intersections where a plurality of data lines intersect with a plurality of scanning lines, and an image is displayed by selectively lighting and driving the above-mentioned pixels, wherein a lighting rate of the pixel in the above-mentioned display panel to be lit and driven is calculated based on image data, and emission brightness of each of the above-mentioned pixels is controlled by performing a conversion process for the above-mentioned image data based on the above-mentioned calculated lighting rate.
Hereafter, a drive apparatus for a light-emitting display panel in accordance with the present invention will be described with reference to preferred embodiments shown in the drawings.
In the drive apparatus, a controller circuit 1 which generates various types of timing signals is connected with an analog/digital (A/D) conversion unit 2, an image memory 3 capable of storing a picture signal for at least one frame, and a PLE control unit 4 as a peak brightness control means capable of controlling display brightness of the picture signal. In a preferred embodiment as shown in this
Based on the clock signal supplied from the controller circuit 1, the above-mentioned A/D conversion unit 2 samples an inputted analog signal and operates to convert this into a picture signal for each pixel to be supplied to the image memory 3. The above-mentioned image memory 3 operates so that the picture signal for every pixel supplied from the A/D conversion unit 2 may be written in the image memory 3 one by one according to the write-in signal W from the above-mentioned controller circuit 1.
As described above, a frame memory is used as the above-mentioned image memory 3, and data for one screen in the display panel is written in by way of the above-mentioned write-in operation, as will be described later. Further, the picture signal written in the image memory 3 is read according to the read-out signal R outputted from the above-mentioned controller circuit 1, and is arranged to be supplied to the above-mentioned PLE control unit 4.
As for the picture signal read from the above-mentioned image memory 3, this PLE control unit 4 operates so that the display brightness may be controlled for each frame period, for example. For this reason, it is arranged that a synchronization signal in synchronism with one frame period is supplied from the controller circuit 1 to the PLE control unit 4. In addition, amore particular structure of the above-mentioned PLE control unit 4 and its operation will be described in detail later. The picture signal outputted from the above-mentioned PLE control unit 4 is supplied to an output processing unit 5, and this output processing unit 5 converts the above-mentioned picture signal into a signal form to be outputted which can be driven in a data driver 7 as will be described later.
In addition, based on the above-mentioned horizontal and vertical synchronizing signals in the picture signal, the above-mentioned controller circuit 1 is arranged to generate a shift clock signal, a start pulse, etc. for a scanning driver 6 and a data driver 7 to supply them to each of the drivers 6 and 7.
Reference numeral 10 shown in
Further, a scanning line 11 and a data line 12 which are respectively connected to the above-mentioned scanning driver 6 and the data driver 7 are arranged perpendicularly to each other at the above-mentioned display panel 10. In the intersections, the sub-pixels R, G, and B including the above-mentioned EL elements are arranged at it, respectively.
In addition, it is arranged that a voltage for lighting and driving the pixel is supplied from the power supply circuit 8 through a power supply line 13 to each of the above-mentioned sub-pixels.
This pixel R is arranged so that a data signal V data corresponding to the picture signal from the above-mentioned data driver 7 may be supplied to a source of TFT for control, i.e., a data write-in transistor Tr1, through the data line 12 arranged at the display panel.
It is arranged that a scanning signal Select (hereafter also referred to as a write-in pulse) may be supplied to a gate of the above-mentioned data write-in transistor Tr1 through the scanning line 11 connected to a scanning driver 6. A drain of the above-mentioned data write-in transistor Tr1 is connected to a gate of a lighting and driving TFT i.e., a lighting and driving transistor Tr2 and also connected to one terminal of a capacitor C1 for holding electric charges.
Further, a source of the lighting and driving transistor Tr2 is arranged to be connected with the other terminal of the above-mentioned capacitor C1 and supplied with a drive voltage Vcc from the above-mentioned power supply circuit 8 via a power supply line 13. A drain of the above-mentioned lighting and driving transistor Tr2 is connected to an anode terminal of an organic EL element E1 as a light emitting element, and a cathode terminal of this organic EL element E1 is connected to a reference potential point (ground) of the display panel 10.
In addition, in the circuit structure of the pixel R as shown in
In the structure of the pixel R as shown in
Then, the charge voltage is supplied to a gate of the drive transistor Tr2, the transistor Tr2 causes current corresponding to its gate voltage and the drive voltage Vcc supplied to the source to flow into the above-mentioned EL element E1, whereby the EL element E1 emits light.
If application of the above-mentioned write-in pulse to the gate of the above-mentioned control transistor Tr1 is stopped, the transistor Tr1 is so-called cut off. However, the gate voltage of the drive transistor Tr2 is held by the electric charge accumulated in the capacitor C1, whereby the drive current to the EL element E1 is maintained.
In this embodiment, light emission of each pixel arranged at the display panel 10 is controlled based on the picture signal in which brightness is controlled in the above-mentioned PLE control unit 4. In this case, as one means, based on the picture signal in which the brightness control is carried out in the above-mentioned PLE control unit 4, the brightness (gradation) of each sub-pixel can be controlled by controlling a voltage value of the data signal Vdata supplied from the data driver 7 through each data line 12 to the source of the transistor Tr1 for control, for example, whereby control of the peak brightness of the pixel can be realized by the above-mentioned PLE. In addition, at this time, a display color in one color display pixel can be adjusted by controlling the gradation among the above-mentioned R, G and B separately.
Further, as another means, one frame (period) is divided into a plurality of sub-frames and the pixel is controlled to be lighting or non-lighting on a sub-frame by sub-frame basis, so that the brightness (gradation) control of each pixel can be realized by summing the lighting periods of the pixel in one frame period. Also by using such a sub-frame method, it is possible to realize control of the peak brightness of the pixel based on the above-mentioned PLE control. Also in this case, by carrying out gradation control of the sub-pixel of each of the above-mentioned R, G, and B separately on a sub-frame by sub-frame basis, the display color in one color display pixel can be adjusted.
By means of a block diagram,
The respective picture signals corresponding to R, G, and B outputted from the above-mentioned circuit 21 are supplied to a weighting means 22A, and each of the picture signals R, G, and B is weighted. In this weighting means 22A, in order to obtain the same brightness with respect to each color of the picture signals R, G, and B, weighting is carried out according to the light emitting current rates (proportions) required for the respective light emitting elements of the respective colors, i.e., the light emitting current rates of the respective colors at the time of displaying grayscales. In addition, this weighting means 22A is referred to as a first weighting means, for convenience.
In order to simplify the explanation of the weighting operation by means of this first weighting means 22A, it is assumed that a light emitting current ratio required for the respective light emitting elements of R, G, and B is R:G:B=1:1:2 to obtain the achromatic color (white color), for example. In this case, the picture signal of R, the picture signal of G, and the picture signal of B are respectively multiplied and weighted by 1/(1+1+2), 1/(1+1+2), and 2/(1+1+2).
The picture signals weighted by the above-mentioned first weighting means 22A are supplied to the averaging means 23 to calculate an average value, and this average value is outputted from the APL calculation means 20 as APL (average picture level). The operation of calculating the average value in the above-mentioned averaging means 23 is as already described with reference to the structure shown in
APL=R×1/(1+1+2)+G×1/(1+1+2)+B×2/(1+1+2) (Equation 2)
The APL output found by the above-mentioned APL calculation means 20 is provided as a control signal to a peak brightness control means 29. A composite picture signal read from the above-mentioned image memory 3 is supplied as a signal to be controlled to this peak brightness control means 29. The peak brightness of this picture signal is controlled by the above-mentioned APL output so as to realize the PLE control.
The output by the peak brightness control means 29, i.e., the output by the PLE control unit 4 is supplied to the output processing unit 5, as described above. This output processing unit 5 converts the picture signal into a signal form which can be driven in the data driver 7 and outputs it.
According to the APL calculation output by using the above-mentioned weighting means 22A, in order to obtain the same brightness when display is carried out by the gray scale, weighting is performed according to the rates (proportions) of the light emitting currents needed for the respective light emitting elements of the respective colors. Thus, when the above-mentioned PLE control is introduced into the drive apparatus for the display panel using the light emitting elements represented by an organic EL element whose emission brightness depends on drive current, the APL calculation can be judged suitably. Therefore, regardless of the light emitting elements of R, G, and B, when the lighting rate is high, it is possible to realize the PLE control which lowers the peak brightness and controls power consumption.
Further, in the structure shown in
In other words, the weighting means 22A in the first aspect of the already explained PLE control unit 4 “performs the weighting according to the rates (proportions) of the light emitting currents needed for the respective light emitting elements of the respective colors”, while the weighting means 22A in the second aspect “performs the weighting according to the rates (proportions) of the light emitting power needed for the respective light emitting elements of the respective colors ”, thus they are different from each other.
However, the light emitting power P of the light emitting element can be represented as P=Vf×If which is a product of a forward direction voltage Vf and current If. In other words, the above-mentioned light emitting power P has a relationship proportional to the forward direction voltage Vf and has a relationship proportional to the above-mentioned light emitting current If. Therefore, the structure which realizes the weighting means 22A in the second aspect of the PLE control unit 4 can be shown as a structure of a block diagram similar to the weighting means 22A in the first aspect as shown in
The weighting operation by this second means and the above-mentioned PLE operation by means of the APL output generated by the averaging means may provide operational effects similar to those of the weighting operation by the already explained first means and the PLE operation by means of the APL output generated by the averaging means.
By means of a block diagram,
In the structure as shown in this
Further, in order to obtain the same brightness when the display is achieved by the gray scale with respect to the picture signals of R, G, and B of the respective colors, the second weighting means 22B as shown in FIG. 8 performs the weighting according to rates (proportions) of the brightness needed for the respective light emitting elements of the respective colors, i.e. the weighting according to the emission brightness rate (proportion) of each color at the time of displaying the gray scale. This achieves the same function as the already-described brightness rate weighting means as shown in
Further, the above-mentioned first weighting means 22A and second weighting means 22B are respectively connected with averaging means 23a and 23b. Averaged outputs from these averaging means 23a and 23b are arranged to be supplied to the second selection means 27. The averaged output chosen by the second selection means 27 is arranged to be supplied to the peak brightness control means 29. In other words, the above-mentioned first and second selection means 26 and 27 are arranged so that the averaged outputs from the above-mentioned first and second weighting means 22A and 22B can be chosen alternatively.
According to the structure as shown in
Further, as described in the above-mentioned second preferred embodiment, the first weighting means 22A in the structure as shown in
By means of a block diagram,
In the structure as shown in this
According to the structure as shown in this
Further, as described in the above-mentioned second preferred embodiment, it may be arranged that the first weighting means 22A in the structure as shown in
Then, a fifth preferred embodiment of the present invention will be described.
Based on the clock signal supplied from the luminescence control circuit 101, the above-mentioned A/D conversion circuit 102 samples the inputted analog signal and operates to convert this into image data for each pixel to be supplied to the image memory 103. The above-mentioned image memory 103 operates so that each pixel datum supplied from the A/D conversion circuit 102 may be written in the image memory 103 one by one according to the write-in signal W from the above-mentioned luminescence control circuit 101.
A frame memory is used as the above-mentioned image memory 103, and the writing of the data for one screen in the display panel to be described later is performed by the above-mentioned write-in operation. Then, in a situation where the writing of the data for one screen is completed, it operates to obtain proportions (lighting rates) of the pixels to be caused and controlled to emit light based on the above-mentioned image data written in the memory 103. In other words, the luminescence control circuit 101 also achieves the function as a lighting rate calculation means.
Based on the horizontal and vertical synchronizing signals in the above-mentioned picture signal, the above-mentioned luminescence control circuit 101 operates to generate a synchronization signal for a scanning driver 106, a data driver 107, and an erase driver 108 as a second scanning driver. Further, the luminescence control circuit 101 obtains the lighting rate of the pixel from the image data written in the above-mentioned memory 103, and operates to read the image data from the above-mentioned memory 103 according to the read-out signal R supplied from the luminescence control circuit 101.
Further, based on the above-mentioned lighting rate, the above-mentioned luminescence control circuit 101 refers to the above-mentioned dimmer setting table 104, and operates to generate a control signal for the data driver 107 and the erase driver 108. In addition, operation at this time of the data driver 107 and the erase driver 108 will be described in detail later.
Reference numeral 110 shown in
It is arranged that a scanning signal Select (hereafter also referred to as a write-in pulse) may be supplied to a gate of the above-mentioned data write-in transistor Tr1 through the scanning line 113 connected to a scanning driver 106. A drain of the above-mentioned data write-in transistor Tr1 is connected to a gate of a lighting and driving TFT i.e., a lighting and driving transistor Tr2 and also connected to one terminal of the capacitor C1 (as electric capacitance) for holding electric charges.
Further, the source of the lighting and driving transistor Tr2 is arranged to be connected with the other terminal of the above-mentioned capacitor C1 and supplied with a drive voltage Vcc via a power supply line 116. The drain of the above-mentioned lighting and driving transistor Tr2 is connected to the anode terminal of the organic EL element E1 as a light emitting element, and the cathode terminal of this organic EL element E1 is connected to the reference potential point (ground).
Furthermore, it is arranged that a gate of an erase transistor Tr3 as TFT for erase is supplied with an erase signal Erase (also referred to as an erase pulse) from an erase driver through the erase signal line 115. A source and a drain of the erase transistor Tr3 are connected to terminals of the above-mentioned capacitor C1, respectively.
In addition, in the circuit structure of the pixel 111 as shown in
In the structure of the pixels 111 as shown in
When the application of the above-mentioned write-in pulse to the gate of the above-mentioned control transistor Tr1 is stopped, the transistor Tr1 is so-called cut off. However, the gate voltage of the drive transistor Tr2 is held by the electric charge accumulated in the capacitor C1, whereby the drive current to the EL element E1 is maintained. Therefore, the EL element E1 can continue a lighting state corresponding to the above-mentioned data signal Vdata in a period (one sub-frame period as will be described later) until the next address operation.
On the other hand, in the middle of the lighting period of the above-mentioned EL element E1 (in the middle of one sub-frame period), the erase pulse Erase which causes the erase transistor Tr3 to turn on is supplied from the above-mentioned erase driver 108, whereby the electric charge charged in the capacitor C1 can be eliminated (discharged) instantaneously. As a result, the drive transistor Tr2 is in a cut-off state, and the EL element E1 is turned off immediately. In other words, the lighting period in one sub-frame of the EL element E1 is controlled by controlling an output timing of the erase pulse Erase from the erase driver 108, so that multi-gradation expression can be realized.
In other words,
FIGS. 12(a) and 12(b) show an example in which the rates (proportions) of the lighting period and the non-lighting period for each sub-frame are controlled according to the lighting rate (proportion) of the above-mentioned pixel 111 arranged at the display panel 110.
Now, when the lighting rate of the pixel is low, lighting control as shown in
Here, when trying to realize the gradation “8” (for example), a series of lighting patterns as shown in
The erase pulse as shown in
Corresponding to the above-mentioned lighting rate, the lighting period for each sub-frame is stored in the above-mentioned dimmer setting table 104 as a parameter. When the number of a sub-frame to be lit and controlled is supplied from the sub-frame counter 118 to the logical operation unit 119, the logical operation unit 119 accesses the table 104 and operates so that the output timing signal of the above-mentioned erase pulse may be generated based on the parameter of the lighting time stored corresponding to the number of the sub-frame.
This is generated as the output timing signal of the erase pulse for every sub-frame each corresponding to the lighting rate of the pixel as shown in
According to the fifth preferred embodiment as described above, it operates so that the emission brightness of each pixel may be controlled based on the lighting rate of the pixel in the situation where a specific gamma characteristic is provided, to thereby it operates so that the emission brightness of each pixel may be inhibited when the lighting rate is high.
Therefore, the maximum drive current supplied from the power supply circuit to the display panel can be controlled, thus solving the problem that the size of each component used for the power supply circuit and the whole power supply circuit are large.
Anode lines A1-Am as m data lines are arranged vertically (in a column direction) at a display panel 121 as shown in
The above-mentioned anode-line drive circuit 122 is provided with constant current sources I1-Im as lighting driving power sources which operate by means of a drive voltage VH, and drive switches Sa1-Sam. It operates such that the drive switches Sa1-Sam are connected to the above-mentioned constant current sources I1-Im side, so that current from the constant current sources I1-Im may be supplied to the individual EL elements arranged at intersections where the anode lines intersect with the cathode lines. Further, when not supplying the current from the constant current sources I1-Im to the individual EL elements, the above-mentioned drive switches Sa1-Sam are arranged so that each of the above-mentioned anode lines can be connected to the ground potential as a non-lighting driving power supply.
Further, the above-mentioned cathode-line scanning circuit 123 is provided with scanning switches Sk1-Skn corresponding to the respective cathode lines K1-Kn. The switches operate so that either of a reverse bias voltage source VM which functions as a non-scanning selection potential and prevents cross talk luminescence or the ground potential which functions as the scanning selection potential may be connected to the corresponding cathode line. Thus, the switches operate so that each of the above-mentioned EL elements may selectively be caused to emit light by connecting the constant current sources I1-Im to the desired anode lines A1-Am, while setting cathode lines as the ground potential at predetermined time intervals.
In the preferred embodiment as shown in
From the image data written in the image memory 103, the above-mentioned luminescence control circuit 101 calculates a lighting rate of the EL element as the display pixel arranged at the display panel 121, and refers to the dimmer setting table 104 based on this lighting rate. It reads brightness control data corresponding to the lighting rate from the above-mentioned dimmer setting table 104, and operates to control a supply period of the constant current supplied from the constant current sources I1-Im in the anode-line drive circuit 122 to an EL element to be lit.
In other words, according to the lighting rate of the pixel in this embodiment, the supply period of the constant current supplied from each of the above-mentioned constant current sources I1-Im to the EL element to be lit is controlled for each scanning period, whereby it operates so that the control of the emission brightness of each pixel may be realized. In particular, when the lighting rate of the pixel is high, the control is such that the supply period of the constant current for each scanning period supplied from each of the above-mentioned constant current sources I1-Im to the EL element which constitutes each pixel may be short, whereby the emission brightness of each pixel in a situation where the lighting rate of the pixel is high is inhibited.
In the reset period as shown in
On the other hand, as shown in FIGS. 15(D) and 15(E), the scanning driver 123 in the above-mentioned reset period is controlled by the scanning switches sk1-skn provided therein to respectively supply the ground potential GND to the cathode lines to be scanned (scanning lines) and the cathode lines not to be scanned (non-scanning lines). Thus, the anode and cathode electrodes of each of the organic EL elements arranged at the display panel 121 are respectively connected to the ground potential GND which is a reset potential, so that a reset action (GND-GND reset) by which the electric charge in the parasitic capacitance of each EL element is nulled is performed.
Further, in the constant current drive period which is a period when the EL element can emit light, as shown in
On the other hand, the cathode driver 123 in the above-mentioned constant current drive period is controlled such that cathode lines (scanning lines) are set as the ground potential GND which is the scanning selection potential as shown in
Thus, being connected with the scanning lines, the EL elements to be lit are supplied with lighting driving current from the constant current sources I1-Im so as to be in the lighting state and the reverse bias voltage VM is applied to the cathode lines in a non-scanning state, so that each of the EL elements connected to the intersection of the anode line to be lit and the cathode line which is not selected for scanning may be prevented from emitting light due to cross talk.
At this time, based on the brightness control data corresponding to the above-mentioned lighting rate from the luminescence control circuit 101 as shown in
When the lighting rate of the pixel is high according to the above-mentioned operation, the supply period of the constant current in one scanning period is controlled to be short and the emission brightness of each pixel is inhibited. Therefore, when the lighting rate of the pixel is high also in the preferred embodiment as shown in
For convenience of description, in the fifth preferred embodiment in accordance with the present invention as shown in
Further, in addition to the above-mentioned fifth preferred embodiment, also in the sixth preferred embodiment as shown in
Next, a seventh preferred embodiment of the present invention will be described.
Based on the clock signal supplied from the luminescence control circuit 201, the above-mentioned A/D conversion circuit 202 samples the inputted analog signal and operates to convert this into image data for each pixel to be supplied to the image memory 203. The above-mentioned image memory 203 operates so that each pixel datum supplied from the A/D conversion circuit 202 may be written in the image memory 203 one by one according to the write-in signal W from the above-mentioned luminescence control circuit 201.
A frame memory is used as the above-mentioned image memory 203, and the writing of the data for one screen in the display panel to be described later is performed by the above-mentioned write-in operation. Then, in a situation where the writing of the data for one screen is completed, it operates to obtain proportions (lighting rates) of the pixels to be caused and controlled to emit light based on the above-mentioned image data written in the memory 203. In other words, the luminescence control circuit 201 also achieves the function as the lighting rate calculation means.
Based on the horizontal and vertical synchronizing signals in the above-mentioned picture signal, the above-mentioned luminescence control circuit 201 operates to generate a synchronization signal for a scanning driver 206 and a data driver 207. Further, the luminescence control circuit 201 obtains the lighting rate of the pixel from the image data written in the above-mentioned memory 203, and operates to read the image data from the above-mentioned memory 203 according to the read-out signal R supplied from the luminescence control circuit 201.
Further, based on the above-mentioned lighting rate, the above-mentioned luminescence control circuit 201 refers to the above-mentioned dimmer setting table 204, and operates to read brightness control information corresponding to the lighting rate and to realize the above-mentioned PLE control by controlling the lighting driving voltage supplied to the pixel of the display panel to be described later. For this reason, in the preferred embodiment as shown in
Reference numeral 210 shown in
In addition, it is arranged that a voltage for lighting and driving the pixel is supplied to each of the above-mentioned pixels 211 from a power supply circuit 209 through a power supply line 216 and that the power supply circuit 209 is supplied with an output voltage from the above-mentioned DC-DC converter 208.
It is arranged that the scanning signal Select (hereafter also referred to as write-in pulse) may be supplied to the gate of the above-mentioned data write-in transistor Tr1 through the scanning line 213 connected to the scanning driver 206. The drain of the above-mentioned data write-in transistor Tr1 is connected to the gate of the lighting and driving TFT i.e., the lighting and driving transistor Tr2 and also connected to one terminal of the capacitor C1 for holding electric charges.
Further, the source of the lighting and driving transistor Tr2 is arranged to be connected with the other terminal of the above-mentioned capacitor C1 and supplied with the drive voltage Vcc via the power supply line 216. The drain of the above-mentioned lighting and driving transistor Tr2 is connected to the anode terminal of the organic EL element E1 as the light emitting element, and the cathode terminal of this organic EL element E1 is connected to the reference potential point (ground).
In addition, in the circuit structure of the pixel 211 as shown in
In the structure of the pixel 211 as shown in
Then, the charge voltage is supplied to the gate of the drive transistor Tr2, the transistor Tr2 causes the current corresponding to its gate voltage and the drive voltage Vcc supplied to the source to flow into the above-mentioned EL element E1, whereby the EL element E1 emits light.
If the application of the above-mentioned write-in pulse to the gate of the above-mentioned control transistor Tr1 is stopped, the transistor Tr1 is so-called cut off. However, the gate voltage of the drive transistor Tr2 is held by the electric charge accumulated in the capacitor C1, whereby the drive current to the EL element E1 is maintained.
Thus, the EL element E1 can continue the lighting state corresponding to the above-mentioned data signal Vdata in the period until the next address operation. Therefore, in the above-mentioned address period, according to the data signal Vdata supplied from the data driver 207, the lighting or turning-off of the pixel is controlled, to thereby realize the gradation control where the lighting period in a unit period of each pixel is controlled individually.
On the other hand, as already described, the luminescence control circuit 201 as shown in
In the structure as shown in
A pulse signal generated by way of PWM from the above-mentioned PWM circuit 225 is arranged to be supplied to a gate of a power FET Q1, so as to switch the FET Q1. In other words, power energy from a battery Batt is accumulated in an inductor L1 by switching ON the above-mentioned FET Q1. On the other hand, as the FET Q1 is subjected to OFF operation, the power energy accumulated in the above-mentioned inductor is accumulated in a capacitor C3 via a diode D1.
By repeating the on/off operation of the above-mentioned FET Q1, the boosted (rise in voltage) DC output can be obtained as a terminal voltage of the capacitor C3, so as to be the output voltage Vcc from the converter. As described above, this output voltage Vcc is divided by the resistance elements R1 and R2, and fed back to the error amplifier 222, so that the output voltage Vcc may be controlled based on the control voltage Vcon1 according to the lighting rate of the pixel as a result.
As such, according to the seventh preferred embodiment as shown in
The anode lines A1-Am as m data lines are arranged vertically (in a column direction) at a display panel 231 as shown in
The above-mentioned anode-line drive circuit 232 is provided with the constant current sources I1-Im which operate by means of the drive voltage VH, and the drive switches Sa1-Sam. It operates such that the drive switches Sa1-Sam are connected to the above-mentioned constant current sources I1-Im side, so that the current from the constant current sources I1-Im may be supplied to the individual EL elements arranged at the intersections where the anode lines intersect with the cathode lines. Further, when not supplying the current from the constant current sources I1-Im to the individual EL elements, the above-mentioned drive switches Sa1-Sam are arranged so that each of the above-mentioned anode lines can be connected to the ground potential as the reference potential point.
Further, the above-mentioned cathode-line scanning circuit 233 is provided with scanning switches Sk1-Skn corresponding to the respective cathode lines K1-Kn. The switches operate so that either of the reverse bias voltage source VM which functions as the non-scanning selection potential and prevents cross talk luminescence or the ground potential which functions as the scanning selection potential may be connected to the corresponding cathode line. Thus, the switches operate so that each of the above-mentioned EL elements may selectively be caused to emit light by connecting the constant current sources I1-Im to the desired anode lines A1-Am, while setting cathode lines as the reference potential point (ground potential) at predetermined time intervals.
In the preferred embodiment as shown in
From the image data written in the image memory 203, the above-mentioned luminescence control circuit 201 calculates a lighting rate of the EL element as the display pixel arranged at the display panel 231, and refers to the dimmer setting table 204 based on this lighting rate. It reads brightness control data corresponding to the lighting rate from the above-mentioned dimmer setting table 204, and operates to control the constant current value from the constant current sources I1-Im in the anode-line drive circuit 232.
In other words, when the lighting rate of the pixel is high, it operates to inhibit the drive current (value) supplied from the above-mentioned constant current sources I1-Im to the EL elements which constitute the respective pixels, whereby the emission brightness of each pixel in a situation where the lighting rate of the pixel is high is inhibited.
Further, an output terminal of the operational amplifier 236 is connected with a base electrode of an npn-type transistor Q7. An emitter electrode of the above-mentioned transistor Q7 is connected with the inversing input terminal of the operational amplifier 236, and also connected with the ground potential GND through a resistor R5. In other words, the above-mentioned operational amplifier 236 and the transistor Q7 constitute a voltage/current conversion means, and operate to vary an amount of current which flows into the transistor Q7 according to the current value control data Vcon2 from the above-mentioned luminescence control circuit 201.
On the other hand, emitter and collector electrodes of a pnp-type transistor Q8 are connected between the above-mentioned drive voltage source VH and a collector electrode of the above-mentioned transistor Q7. It is arranged that the base and collector electrodes of the above-mentioned transistor Q8 are short-circuited and each base electrode of pnp-type transistors Q11-Q1m is similarly supplied with a base potential of the above-mentioned transistor Q8.
Further, an emitter electrode of each of the above-mentioned transistors Q11-Q1m is connected to the above-mentioned drive voltage source VH, so that a current mirror circuit is arranged in which the transistor Q8 serves as the current source on the control side and each of the transistors Q11-Q1m serves as the current source on the side to be controlled.
Therefore, collector current of the transistor Q8 which functions as the current source on the control side is variably controlled by the current value control data Vcon2 as indicated by the above-mentioned variable voltage source 235, so that the collector current in each of the transistors Q11-Q1m is each variably controlled. In short, the above-mentioned transistors Q11-Q1m respectively function as the constant current sources I1-Im as shown in
According to the eighth preferred embodiment shown in
In addition, in the above-described seventh and eighth preferred embodiments, although the example is illustrated using the organic EL element as the light emitting element which constitutes each pixel, it is also possible to obtain similar operational effects, even if another type of light emitting element whose emission brightness depends on the drive current or the drive voltage is used. Furthermore, in the above-mentioned preferred embodiments, although the proportions (lighting rate) of the pixels to be lit and controlled are obtained based on the image data written in the image memory 203, it is possible to calculate an average brightness level from the above-mentioned image data.
Next, a ninth preferred embodiment of the present invention will be described.
Based on the clock signal supplied from the luminescence control circuit 301, the above-mentioned A/D conversion circuit 302 samples the inputted analog signal and operates to convert this into pixel data for each pixel to be supplied to the image memory 303. The above-mentioned image memory 303 operates so that each pixel datum supplied from the A/D conversion circuit 302 may be written in the image memory 303 one by one according to the write-in signal W from the above-mentioned luminescence control circuit 301.
A frame memory is used as the above-mentioned image memory 303, and the writing of the data for one screen in the display panel to be described later is performed by the above-mentioned write-in operation. Then, in a situation where the writing of the data for one screen is completed, it operates to obtain proportions (lighting rates) of the pixels to be caused and controlled to emit light based on the above-mentioned image data written in the memory 303. In other words, the luminescence control circuit 301 also achieves the function as the lighting rate calculation means.
Based on the horizontal and vertical synchronizing signals in the above-mentioned picture signal, the above-mentioned luminescence control circuit 301 operates to generate a synchronization signal for a scanning driver 306 and a data driver 307. Further, the luminescence control circuit 301 obtains the lighting rate of the pixel from the image data written in the above-mentioned memory 303, and operates to read the image data from the above-mentioned memory 303 according to the read-out signal R supplied from the luminescence control circuit 301.
In the preferred embodiment as shown in
Reference numeral 310 shown in
It is arranged that the scanning signal Select (hereafter also referred to as write-in pulse) may be supplied to the gate of the above-mentioned data write-in transistor Tr1 through the scanning line 313 connected to the scanning driver 306. The drain of the above-mentioned data write-in transistor Tr1 is connected to the gate of the lighting and driving TFT i.e., the lighting and driving transistor Tr2 and also connected to one terminal of the capacitor C1 for holding electric charges.
Further, the source of the lighting and driving transistor Tr2 is arranged to be connected with the other terminal of the above-mentioned capacitor C1 and supplied with the drive voltage Vcc from the above-mentioned power supply circuit 309 via the power supply line 316. The drain of the above-mentioned lighting and driving transistor Tr2 is connected to the anode terminal of the organic EL element E1 as the light emitting element, and the cathode terminal of this organic EL element E1 is connected to the reference potential point (ground).
In addition, in the circuit structure of the pixel 311 as shown in
In the structure of the pixel 311 as shown in
Then, the charge voltage is supplied to the gate of the drive transistor Tr2, the transistor Tr2 causes the current corresponding to its gate voltage and the drive voltage Vcc supplied to the source to flow into the above-mentioned EL element E1, whereby the EL element E1 emits light.
If the application of the above-mentioned write-in pulse to the gate of the above-mentioned control transistor Tr1 is stopped, the transistor Tr1 is so-called cut off. However, the gate voltage of the drive transistor Tr2 is held by the electric charge accumulated in the capacitor C1, whereby the drive current to the EL element E1 is maintained.
Thus, the EL element E1 can continue the lighting state corresponding to the above-mentioned data signal Vdata in the period until the next address operation. Therefore, in the above-mentioned address period, according to the data signal Vdata supplied from the data driver 307, the lighting or turning-off of the pixel is controlled, to thereby realize the gradation control where the lighting period in a unit period of each pixel is controlled individually.
In the preferred embodiment as shown in
When all of the first through seventh sub-frames that constitute one frame period are supplied with the data signal for controlling the pixel to be non-lighting, gradation “0” is realized as shown in
As already described, based on the lighting rate of the pixel, the above-mentioned luminescence control circuit 301 refers to the image data conversion table 304, and operates to perform an image data conversion process of extracting, from the table 304, image data whose gradation is low when the lighting rate is large. Thus, when the lighting rate is near 100%, it operates to reduce the gradation, which is based on the picture signal inputted into the luminescence control circuit 301, by n steps in gradation (n is an integer). Therefore, when the lighting rate is high, the lighting period in one frame period of the pixel is reduced, and the emission brightness of the pixel is inhibited.
As described above, since it operates so that the emission brightness of the pixel may be inhibited by controlling the gradation to be low when the lighting rate of the pixel is high, the maximum drive current supplied from the power supply circuit to the display panel is inhibited. Therefore, it is possible to solve the problem that the size of each component used for the power supply circuit and the whole power supply circuit are large.
The anode lines A1-Am as m data lines are arranged vertically (in a column direction) at a display panel 321 as shown in
The above-mentioned anode-line drive circuit 322 is provided with constant current sources I1-Im which operate by means of the drive voltage VH, and the drive switches Sa1-Sam. It operates such that the drive switches Sa1-Sam are connected to the above-mentioned constant current sources I1-Im side, so that current from the constant current sources I1-Im may be supplied to the individual EL elements arranged at the intersections where the anode lines intersect with the cathode lines. Further, when not supplying the current from the constant current sources I1-Im to the individual EL elements, the above-mentioned drive switches Sa1-Sam are arranged so that each of the above-mentioned anode lines can be connected to the ground potential as the reference potential point.
Further, the above-mentioned cathode-line scanning circuit 323 is provided with scanning switches Sk1-Skn corresponding to the respective cathode lines K1-Kn. The switches operate so that either of the reverse bias voltage source VM which functions as the non-scanning selection potential and prevents cross talk luminescence or the ground potential which functions as the scanning selection potential may be connected to the corresponding cathode line. Thus, the switches operate so that each of the above-mentioned EL elements may selectively be caused to emit light by connecting the constant current sources I1-Im to the desired anode lines A1-Am, while setting cathode lines as the reference potential point (ground potential) at predetermined time intervals.
In the preferred embodiment as shown in
Also in the structure as shown in
In other words, as with the example shown in
Accordingly, when the lighting rate is high, the lighting period in one frame period of the pixel is reduced, and the emission brightness of the pixel is inhibited. Therefore, also in the drive apparatus for the passive matrix type display panel, it is possible to obtain operational effects similar to those in the ninth preferred embodiment shown in
In addition, in the ninth and tenth preferred embodiments as described above, although the examples are shown in which the gradation control is carried out in eight steps, practical gradation control may suitably employ 32 steps, 64 steps etc., for example. Further, in the above description, although the examples are illustrated using the organic EL element as the light emitting element which constitutes each pixel, it is also possible to use another type of light emitting element whose emission brightness depends on the drive current.
Number | Date | Country | Kind |
---|---|---|---|
2005-298315 | Oct 2005 | JP | national |
2005-303445 | Oct 2005 | JP | national |
2005-303446 | Oct 2005 | JP | national |
2005-338724 | Nov 2005 | JP | national |