The present application claims priority from Japanese Application No. 2006-279986 filed on Oct. 13, 2006, the content of which is hereby incorporated by reference into this application.
The present invention relates to a display device mounted with self-luminous elements as self-luminous type display elements such as EL (Electroluminescence) elements, organic EL element elements, etc.
In the case of the self-luminous element typified by the EL element, organic EL element, etc., the element has a property such that the luminance of that is proportional to a current amount flown into the self-luminous element, so that a display of gradation sequence can be made by controlling the current amount flown into the self-luminous element. In this way, a display device can be made by arranging a plurality of the self-luminous elements.
However, if the self-luminous element is used in an extended period of time, the element has a property such that a deterioration of the element makes progress along with time lapse, and the luminance of that reduces. The rate of deterioration is dependent on the time period of luminance in this case. Therefore, a burn-in pattern occurs in response to a luminous state (displayed pattern) of individual pixels.
As a technique to solve the burn-in pattern caused by the deterioration of self-luminous element due to the time lapse, JP-A-2002-278514 discloses a technique in which a drive current is measured for every pixel train (one train of column direction), a rate of the deterioration is detected from the amount of drive current, and a result of the detection is fed back to a signal voltage, thereby solving the burn-in pattern.
However, in the case of the technique disclosed in JP-A-2002-278514, it is necessary to mount a series resistor and an ADC (A/D converter), as a current detection circuit, in every pixel train on a glass substrate. For this reason, there arises a problem that a size of a circuit and an area (frame) are increased, and a number of new interface signals are required for applying the foregoing feed back technique when the signal voltage is supplied from an outside of panel.
An object of the invention is to provide a display device to solve occurrence of a burn-in pattern by controlling a luminous period of the self-luminous element in response to the deterioration, without providing the interface signal for the feed-back to the outside of panel (outside of glass substrate).
According to an aspect of the invention, a display device has a display panel arranged by a plurality of pixels, a scanning line driving circuit that selects the pixel arranged on the display panel, and a data line driving circuit that supplies a signal voltage to the pixel selected by the scanning line driving circuit, in which the pixel provides a luminous element, a transistor for driving the luminous element and a writing capacitor for fetching a signal voltage in accordance with an input reference voltage of the transistor, and the transistor controls a luminous period in accordance with the input reference voltage shifted in response to a characteristic of the luminous element.
According to another aspect of the invention, a self-luminous display device is constituted by a display element unit arranged in matrix-shaped arrangement with self-luminous elements, summation of luminous currents of which is controlled in accordance with a writing signal voltage; a writing signal voltage control circuit that generates the writing signal voltage in response to input data; a writing capacitor that stores the writing signal voltage; a sweep signal generation circuit that generates one cycle sweep signal in a luminous time period after a writing completion for all of pixels; signal lines that supply the writing signal voltage to the writing capacitor for each of the pixels in a writing time period and the sweep signal to the writing capacitor in the luminous time period; a power supply device that supplies a luminous current to the self-luminous elements; a drive transistor that controls the luminous period in accordance with a comparison result of the writing signal voltage and the sweep signal signal; a characteristic capacitor that stores a characteristic of the drive transistor independent from a characteristic of one self-luminous element connected in parallel with other self-luminous element; a reset switch connected between a gate and a source of the drive transistor; a characteristic hold switch connected between the source of the drive transistor and one end of the characteristic capacitor; and a luminance control switch connected between the source of the drive transistor and one end of the self-luminous element.
On the writing time period, the writing signal voltage is stored in the writing capacitor by controlling the reset switch and the characteristic hold switch on the basis of a threshold value voltage of the drive transistor independent from the self-luminous element characteristic stored in the characteristic capacitor.
On the luminous time period, the self-luminous element is made into a luminous state by controlling the luminance control switch.
With input of the sweep signal from the signal line, the level of sweep signal is based on the characteristic independent from the self-luminous element characteristic stored in the writing capacitor. In contrast, the threshold value voltage of drive transistor becomes a threshold value voltage added with the characteristic of self-luminous element. Therefore, the luminous period is controlled in response to a characteristic variation caused by a deterioration due to a temperature and time lapse of the self-luminous element.
According to the invention, the invention provides a display device having a stable luminance among the pixels without causing a burn-in pattern due to the deterioration of time lapse. In this way, the display device is desirable for DVC (Digital Video Camera), DSC (Digital Still Camera), mobile telephones, etc., which essentially requires icon displays, because the burn-in state of a fixed pattern can be eliminated.
Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings.
Embodiments of the invention will be described below with the reference to the drawings.
In the case of the embodiment, the display data 4 by an amount of one screen is, in turn, transferred from a pixel at an upper left end of a display screen by the raster scan system. Information by an amount of one pixel will be described as digital data configured by 6 bits. In this regard, the information by an amount of one pixel may also be 8 bits, 10 bits, etc.
Referring back to
Further, a reference numeral 9 denotes a data line drive circuit, and 10 denotes a data line drive signal. The data line drive circuit 9 generates a signal voltage written into the pixel configured by self-luminous element and a sweep signal signal in accordance with the data line control signal 7 to output as the data line drive signal 10.
A reference numeral 11 denotes a drive voltage generation circuit, and 12 denotes a panel supply drive voltage. The drive voltage generation circuit 11 generates a power supply voltage for supplying a current to produce luminescence from the self-luminous element and output as a panel supply drive voltage 12.
A reference numeral 13 denotes a scanning line drive circuit, 14 denotes a scanning line drive signal, and 15 denotes a display panel. The display panel 15 provides the self-luminous elements, with a matrix arranged, using such as light-emitting diodes, organic EL elements, etc. An operation of display panel 15 is carried out by the following manner. First, a signal voltage corresponding to the data line drive signal 10 output from the data line drive circuit 9 is written into a pixel selected by the scanning line drive signal 14 output from the scanning line drive circuit 13. Thereafter, a sweep signal is supplied to the pixel to thereby produce luminescence from the self-luminous element. A voltage for driving the self-luminous element is supplied as the panel supply drive voltage 12.
In addition, the data line drive circuit 9 and scanning line drive circuit 13 may be realized by a LSI for each, or may be realized by a single LSI. The single or plural LSIs may be configured on a glass substrate on which a pixel unit configured by the self-luminous elements is also configured.
In the case of the embodiment, description will be concerned with a configuration below, that is, the display panel 15 has a resolution of 240×320 dots, and one dot is configured by 3 pixels, R (Red), G (Green) and B (Blue) in the order from the left thereof, that is, the horizontal direction of display is configured by 720 pixels.
In the display panel 15, a luminance of producing luminescence by the self-luminous element is regulated by a current amount flown into the self-luminous element and a luminous period of the self-luminous. The larger the current amount flown into the self-luminous element is, the higher the luminance of self-luminous element becomes. The longer the luminous period of self-luminous element is, the higher the luminance of self-luminous element becomes.
The first dot R data line 16 and first dot G data line 17 are signal lines to input a first dot R signal, a first dot G signal and the sweep signal to the pixel.
The first line reset selection line 18, first line characteristic hold selection line 19, first line luminous selection line 20, second line reset selection line 21, second line characteristic hold selection line 22, and second line luminous selection line 23, write signal voltages into the pixels on the lines selected by the selection lines of the lines (rows), respectively, through the respective data lines. A luminous period of the pixel, which produces luminescence, is controlled by an organic EL element drive voltage supplied from the respective column organic EL element drive voltage supply lines in accordance with the signal voltages and sweep signal signals.
Further referring to
The reset switch 32 turns On-state by the first line reset selection line 18. The characteristic hold switch 33 turns On-state by the first line characteristic hold selection line 19. Therefore, a threshold characteristic is stored in the characteristic hold capacitor 34 with an input/output state of the drive transistor 31 short-circuited, and a signal voltage from the first dot R data line 16 is also accumulated into the writing capacitor 30 on the basis of the threshold characteristic.
The drive transistor 31 is switched its On and Off states by the level of sweep signal which varies in accordance with the writing signal voltage accumulated in the writing capacitor 30 and the luminance control switch 35 turned On-state by the first line luminous selection line 20 in response to the threshold value including the characteristic of organic EL element 36 and controls a time period for supplying a drive current to the organic EL element 36 from the first column organic EL element drive voltage supply line 24 in a luminous time period after a writing completion for all of the pixels. Therefore, the luminance of organic EL element 36 is determined by the writing signal voltage into the writing capacitor 30 and an organic EL element drive voltage.
Further, a next description will be concerned with the following condition. That is, the number of pixels of display panel 15 is 240×320 dots. The total number of line (row) selection lines is 960 because 3 lines for each of the lines in the horizontal direction are arranged from a first line to a 320th line in the vertical direction. The total number of data lines is 720 because the lines for Red, Green and Blue in the vertical direction are arranged from a first dot to a 240th dot. In addition, the organic EL element drive voltage supply line is connected to all of the pixels by lines parallel with the data lines from the under side of display panel 15. That is, the total number of lines in the vertical direction is 1440 aligned in the horizontal direction, which is also concerned with the following description below.
The data shift circuit 40 fetches the display input data 39 by an amount of one line in one horizontal period in accordance with the data clock 38, as a reference of start to fetch the data start pulse 37, and outputs as the shift data 42. After fetching, the data shift circuit 40 generates the fly-back period signal 41 indicating a period up to a next fetching start.
Further referring to
Further, a reference numeral 46 denotes a gradation sequence voltage selection circuit, and 47 denotes a one-line display data. The gradation sequence voltage selection circuit 46 selects one level from 64-level gradation sequence voltages in accordance with the one-line latch data 45 to output as the one-line display data 47.
A method of generating the one-line display data 47 from the data line control signal 7 is the same as conventional one, except the generating operation of fly-back period signal 41.
Further, in
Further, a reference numeral 51 denotes a gradation voltage/sweep signal switching circuit. This circuit 51 switches the one-line display data 47 with the sweep signal 49 by the triangular switching signal 50 to output as the data line drive signal 10.
The vertical shift register 54 outputs, in turn, the first line selection signal 55, second line selection signal 56 up to the 320th line selection signal 57 by the vertical shift pulse 53 and vertical start pulse 52 indicating the head of vertical line.
Further referring to
The line selection circuit 61 outputs the reset signal 58 and characteristic hold signal 59 for carrying out an On control at a time of writing a signal voltage to an only selected line among the first line selection signal 55, second line selection signal 56 up to the 320th line selection signal 57 to thereby output an On-state signal to the first line reset selection line 18 and first line characteristic hold selection line 19, or the second line reset selection line 21 and second line characteristic hold selection line 22, or the 320th line reset selection line 62 and 320th line characteristic hold selection line 63.
Further, on the luminous time period after writing the signal voltage into all of the pixels, a signal which turns all lines On-state simultaneously in the luminous time period, is output to the first line luminous selection line 20, the second line luminous selection line 23 and 320th line luminous selection line 64 from the luminance control signal 60 which carries out the On control.
The number of pixels of display panel 15 is 240×320 dots. Therefore, the total number of lines for the line selection signals or scanning drive signal 14 is 960 because 320 lines in the horizontal direction are aligned from the first line to the 320th line in the vertical direction, and 320 lines for each of the reset selection line, characteristic hold selection line and luminous selection line, in the horizontal direction are also aligned from the first line to the 320th line. A next description will be based on the above-mentioned condition below.
Referring to
The first line selection signal waveform 70 and second line selection signal waveform 74 turn sequentially “High” by shifting the vertical start pulse waveform 65 in accordance with the vertical shift clock waveform 66. The first line reset selection line waveform 71 is normally “Low” state, but turns “High” when the first line selection signal waveform 70 is “High” and the reset signal waveform 67 is “High”. The first line characteristic hold selection line waveform 72 is normally “Low” state, but turns “High” when the first line selection signal waveform 70 is “High” and the characteristic hold signal waveform 68 is “High”. The second line reset selection line waveform 75 is normally “Low” state, but turns “High” when the second line selection signal waveform 74 is “High and the reset signal waveform 67 is “High”. The second line characteristic hold selection line waveform 76 is normally “Low” state, but turns “High” when the second line selection signal waveform 74 is “High” and the characteristic hold signal waveform 68 is “High”.
That is, the vertical shift register 54 outputs a selection signal so that the first line to the 320th line turn sequentially “High”. The line selection circuit 61 makes the reset signal and characteristic hold signal valid when the respective line selection signal waveforms are “High” alone, the following description will be concerned with a condition indicating that both the reset signal waveform 67 and the characteristic hold signal waveform 68 are the same in waveform.
The first line luminous selection line waveform 73 and second line luminous selection line waveform 77 are the luminance control signal waveform 69 which turns “High” during the sweep signal time period 85. This condition is common for all of the lines.
The first dot R data line waveform 78 becomes the writing signal voltage level 79 corresponding to display data in the data writing time period 84 within the one-frame time period 88. The first dot R data line waveform 78 then becomes the sweep signal high voltage level 80 after completion of writing data into all of the lines, and is changed to the triangular low voltage level 81 within the sweep signal time period 85 which is excluded with the data writing time period 84 from the one-frame time period 88, and again changed to the sweep signal high voltage level 80.
Here, it is assumed that the entire screen is displayed by the same gradation sequence, a writing signal voltage level of which is assumed as Vsig_1. The following description will be concerned with the above-mentioned condition. The potential Vsig_1 which is written into the pixel is held by the writing capacitor 30 to set to as a reference voltage for the gate input of drive transistor 31. The output waveform 82 of first line first column pixel drive transistor 31 turns “Low” within the sweep signal time period 85 while the sweep signal voltage level exceeds Vsig_1, and turns “High” while the sweep signal voltage level dips from Vsig_1.
Therefore, the power supply to the organic EL element 36 turns “Off state” or becomes the non-luminous time period 87 while the first line first column pixel drive transistor output waveform 82 is “Low”. In contrast, the power supply to the organic EL element 36 turns “On state” or becomes the luminous time period 86, while the first line first column pixel drive transistor output waveform 82 is “High”. According to the description above, a luminous time period in accordance with the signal voltage is determined. In addition, it is assumed that the foregoing signal voltage (data) input and sweep signal input are carried out within a predetermined cycle. In this embodiment, it is also assumed that these inputs are carried out in a time period within the one-frame time period 88 which becomes a 60 Hz frequency. The following description will be concerned with the above-mentioned condition below.
Referring back to
writing capacitor voltage 95=Vsig—1−signal voltage writing reference potential 91 (1)
In
As a result, the drive transistor output waveform 82 turns “Low” when the drive transistor input voltage 96 is larger than the organic EL element luminous threshold value 94, and turns “High” when the input voltage 96 is smaller than the threshold value 94. This time period of “High” becomes the luminous time period 86.
Hereinafter, a control at a time of detecting a current in this embodiment will be described with reference to
Referring to
The data line drive circuit 9 outputs the data line drive signal 10 to the data line of display panel 15 by the data line control signal 7 including gradation sequence information during a signal voltage writing time period, and outputs a sweep signal signal as the data line drive signal 10 to the data line during the luminous time period.
The scanning drive circuit 13 outputs the scanning line drive signal 14 to control the scanning selection lines of display panel 15.
The drive voltage generation circuit 11 generates a drive voltage to produce luminescence from the organic EL element and supply as the panel supply drive voltage 12 to the display panel 15. Finally, the pixels on the scanning line selected by the scanning line drive signal 14 in the display panel 15 produce luminescence by the panel supply drive voltage 12 so that the luminous period is controlled in response to the signal voltage to compensate the deterioration of the self-luminous element having a burn-in state, by the signal voltage and sweep signal in the data line drive signal 10.
The luminance control of display panel 15 operated by the data line drive circuit 9 and scanning line drive circuit 13 and a burn-in state compensation drive in detail will be described with use of
Referring to
The sweep signal generation circuit 48 generates the sweep signal 49 and sweep signal switching signal 50 in accordance with the fly-back period signal 41. As shown in
Further, in
The data line drive signal 10 shown in
As described above, the data line drive circuit 9 writes the signal voltage into the display panel 15 within the data writing time period, and outputs the sweep signal within the luminous time period.
Next, the signal voltage writing and luminous period control by the scanning line drive circuit 13, and the burn-in state compensation operation will be described with use of
First, in
Further, the line selection circuit 61 outputs the reset signal 58 and characteristic hold signal 59 taking an AND operation with the first line selection signal 55, second line selection signal 56 and 320th line selection signal 57 which are outputted sequentially from the vertical shift register 54 line by line, to the first line reset selection line 18, first line characteristic hold selection line 19, second line reset selection line 21, second line characteristic hold selection line 22, 320th line reset selection line 62, and 320th line characteristic hold selection line 63 line by line, respectively.
The line selection circuit 61 also outputs the luminance control signal 60 indicating a luminous time period to the first line luminous selection line 20, second line luminous selection line 23 and 320th luminous selection line 64 so that the pixels in common with all of the lines turn “On”. Here, the luminance control signal 60 has been described as generated by the display control circuit 6 shown in
Next, referring to
An operation of the following description in the luminous time period is divided into one case of an initial condition where the organic EL element 36 does not have deterioration caused by the time lapse and the other case of an element characteristic variation caused by the same. First, the case of the initial condition will be described with use of
Referring to
In this condition described above, the input voltage 96 of drive transistor 31 shown in
Next, a condition where the characteristic of organic EL element 36 varies by causing the deterioration due to time lapse, that is, a burn-in phenomenon occurs, will be described with use of
Similarly to the case of initial condition, in
In this condition described above, similarly to the case of initial condition, the input voltage 96 of drive transistor 31 shown in
As described above, the luminous period becomes long when the organic EL element is deteriorated. Therefore, appropriate luminous period compensation and luminance compensation can be given to the pixel having a burn-in phenomenon of the fixed pattern shown in
Further, the amount of luminance compensation can be regulated by controlling the inclination of sweep signal signal, therefore, the inclination can be varied in response to a luminance degradation amount by causing the deterioration of organic EL element. For example, even though the same display data is received and the same signal voltages are supplied to the organic EL elements, respectively, the inclination of sweep signal can be changed in response to the case where the deterioration progresses due to the time lapse and the temperature variation by using the element. Consequently, the luminance can be maintained to the extent necessary for human eyes without difficulty even though the same display data is received and the same signal voltages are supplied to the organic EL elements, because the luminance is restorable in response to the case where the deterioration progresses due to the time lapse and the temperature variation by using the element.
In addition, the drive transistor for inverting the input voltage is configured by a pMOS transistor, and the switch is configured by an nMOS transistor. However, their configurations are not limited by such transistors, any configurations may be acceptable if devices act as the inverter and switch. Further, the pixel configuration including switches etc. are not limited by the embodiment, any configurations may be acceptable if it is possible to operate the pixel configuration such that the organic EL element is cut off in writing the signal voltage to hold the characteristic of drive transistor (inverter), and the organic EL element is connected in the luminous period alone.
Further, according to the embodiment, it is possible to carry out the luminance compensation for every pixel on an arbitrary display pattern. As a result, the invention exerts an advantage such that a fixed burn-in pattern is eliminated, also exerts an advantage for the luminance degradation caused by the deterioration of entire screen.
Referring to
In the case of this embodiment, a stray capacitance at the series connection point of the pMOS transistor 104 and nMOS transistor 105 is used in place of the characteristic hold capacitor 34 shown in
It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.
Number | Date | Country | Kind |
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2006-279986 | Oct 2006 | JP | national |
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Number | Date | Country | |
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20080100543 A1 | May 2008 | US |