Source: https://patents.google.com/patent/EP1821282A2/en
Timestamp: 2020-03-28 22:10:22
Document Index: 760310078

Matched Legal Cases: ['art 100', 'art 100', 'art 100', 'art 500', 'art 500', 'art 500', 'art 500', 'art 500', 'art 500', 'art 500', 'art 500', 'art 600', 'art 700']

EP1821282A2 - Display device and driving method thereof - Google Patents
EP1821282A2
EP1821282A2 EP07109819A EP07109819A EP1821282A2 EP 1821282 A2 EP1821282 A2 EP 1821282A2 EP 07109819 A EP07109819 A EP 07109819A EP 07109819 A EP07109819 A EP 07109819A EP 1821282 A2 EP1821282 A2 EP 1821282A2
EP07109819A
EP1821282A3 (en
Won-Kyu c/o Samsung SDI Co. Ltd. Kwak
Kwan-Hee c/o Samsung SDI Co. Ltd. Lee
Keum-Nam c/o Samsung SDI Co. Ltd. Kim
2004-10-18 Priority to EP04090400A priority patent/EP1531452B1/en
2007-08-22 Publication of EP1821282A2 publication Critical patent/EP1821282A2/en
2008-01-23 Publication of EP1821282A3 publication Critical patent/EP1821282A3/en
Referring to FIG. 1, a conventional active matrix organic electroluminescent display device 10 includes a pixel part 100, a gate line driving circuit 110, a data line driving circuit 120 and a control part (not illustrated in FIG. 1). The pixel part 100 includes a plurality of gate lines 111~11m for providing scan signals S1~Sm from the gate line driving circuit 110, a plurality of data lines 121~12n for providing data signals DR1, DG1, DB1~DRn, DGn, DBn from the data line driving circuit 120 and a plurality of power supply lines 131~13n for providing power supply voltage VDD1 ~VDDn.
The pixel part 100 includes a plurality of pixels P11~Pmn arranged in a matrix format and connected to the plurality of gate lines 111~11 m, the plurality of data lines 121~12n and the plurality of power supply lines 131~13n. Each of the pixels P11~Pmn includes three unit pixels, i.e., corresponding ones of red, green and blue unit pixels PR11~PRmn, PG11~PGmn, PB11~PBmn, so that each of the red, green and blue unit pixels PR11~PRmn, PG11~PGmn, PB11~PBmn is connected to a corresponding one of the gate lines, a corresponding one of the data lines and a corresponding one of the power supply lines.
In more detail, the red unit pixel PR11 of the pixel P11 is connected to the first gate line 111, an R data line 121R for providing an R data signal DR1 and an R power supply line 131R. In addition, the green unit pixel PG11 is connected to the first gate line 111, a G data line 121 G for providing a G data signal DG1 and a G power supply line 131G Further, the blue unit pixel PB11 is connected to the first gate line 111, a B data line 121B for providing a B data signal DB1 and a B power supply line 131B.
Referring to FIG. 2, the red unit pixel PR11 of the pixel P11 includes a switching transistor M1_R for which the scan signal S1 applied from the first gate line 111 is supplied to a gate, and the data signal DR1 is supplied to a source from the red data line 121R. The red unit pixel PR11 also includes a driving transistor M2_R for which a gate is connected to a drain of the switching transistor M1_R, and a power supply voltage VDD1 is supplied to a source from the power supply line 131 R. Further, the red unit pixel PR11 includes a capacitor C1_R connected between the gate and the source of the driving transistor M2_R, and a red EL device EL1_R having an anode connected to a drain of the driving transistor M2_R and a cathode connected to a ground voltage VSS.
Similarly, the green unit pixel PG11 includes a switching transistor M1_G for which the scan signal S1 applied from the first gate line 111 is supplied to a gate, and the data signal DG1 is supplied to a source from the green data line 121 G. The green unit pixel PG11 also includes a driving transistor M2_G for which a gate is connected to a drain of the switching transistor M1_G, and the power supply voltage VDD1 is supplied to a source from the power supply line 131G. Further, the green unit pixel PG11 includes a capacitor C1_G connected between the gate and the source of the driving transistor M2_G, and a green EL device EL1_G having an anode connected to a drain of the driving transistor M2_G and a cathode connected to a ground voltage VSS.
Further, the blue unit pixel PB11 includes a switching transistor M1_B for which the scan signal S1 applied from the first gate line 111 is supplied to a gate, and the data signal DB1 is supplied to a source from the blue data line 121 B. The blue unit pixel PB11 also includes a driving transistor M2_B for which a gate is connected to a drain of the switching transistor M1_B, and the power supply voltage VDD1 is supplied to a source from the power supply line 131 B. Further, the blue unit pixel PB11 includes a capacitor C1_B connected between the gate and the source of the driving transistor M2_B, and a blue EL device EL1_B having an anode connected to a drain of the driving transistor M2_B and a cathode connected to a ground voltage VSS.
In operation of the above described pixel circuit P11 , the switching transistors M1_R, M1 G, M1_B of the red, green and blue unit pixels are driven, and red, green and blue data DR1, DG1, DB1 are applied to the gates of the driving transistors M2_R, M2_G, M2_B from the red, green and blue data lines 121R, 121G, 121B, respectively, when the scan signal S1 is applied to the gate line 111.
The driving transistors M2_R, M2_G, M2_B supply to the EL devices EL1_R, EL1_G, EL1_B a driving current corresponding to the difference between the data signals DR1, DG1, DB1 applied to the gate and the power supply voltage VDD1 respectively supplied from the red, green and blue power supply lines 131 R, 131 G, 131 B. The driving current applied through the driving transistors M2_R, M2_G, M2_B to drive the pixel P11 drives the EL devices EL1_R, EL1_G, EL1_B. The capacitors C1_R, C1_G, C1_B store the data signals DR1, DG1, DB1 applied, respectively, to the red, green and blue data lines 121R, 121G, 121 B.
First, the first gate line 111 is driven, and pixels P11~P1n connected to the first gate line 111 are driven when the scan signal S1 is applied to the first gate line 111.
In other words, the switching transistors of the red, green and blue unit pixels PR11~PR1n, PG11 ~PG1n, PB11~PB1n of the pixels P11~P1n connected to the first gate line 111 are driven by the scan signal S1 applied to the first gate line 111. Red, green and blue data signals D(S1) (DR1~DRn, DG1~DGn, DB1∼DBn) are simultaneously applied to the gates of the driving transistors of the red, green and blue unit pixels, respectively, through the red, green and blue data lines 121R~12nR, 121G~12nG, 121B∼12nB composing first to nth data lines 121~12n according to the driving of the switching transistors.
The driving transistors of the red, green and blue unit pixels supply a driving current corresponding to the red, green and blue data signals D(S1) (DR1~DRn, DG1~DGn, DB1~DBn) applied to the red, green and blue data lines 121R~12nR, 121G∼12nG, 121B∼12nB, respectively, to the red, green and blue EL devices. Therefore, the EL devices of the red, green and blue unit pixels PR11~PR1n, PG11~PG1n, PB11~PB1n of the pixels P11~P1n connected to the first gate line 111 are simultaneously driven when the scan signal S1 is applied to the first gate line 111.
Similarly, if a scan signal S2 for driving a second gate line 112 is applied, data signals D(S2)(DR1∼DRn, DG1∼DGn, DB1∼DBn) are applied to red, green and blue unit pixels PR21~PR2n, PG21~PG2n, PB21∼PB2n of pixels P21~P2n connected to the second gate line 112 through red, green and blue data lines 121R~12nR, 121G~12nG, 121B∼12nB composing first to nth data lines 121~12n.
EL devices of the red, green and blue unit pixels PR21~PR2n, PG21~PG2n, PB21~PB2n of the pixels P21~P2n connected to the second gate line 112 are simultaneously driven by a driving current corresponding to the data signals D(S2)(DR1 ~DRn, DG1~DGn, DB1 ~DBn).
EL devices of red, green and blue unit pixels PRm1~PRmn, PGm1~PGmn, PBm1~PBmn of pixels Pm1~Pmn connected to the mth gate line 11 m are simultaneously driven according to red, green and blue data signals D(Sm)(DR1∼DRn, DG1∼DGn, DB1∼DBn) applied to the red, green and blue data lines 121R~12nR, 121G~12nG, 121B~12nB when a scan signal Sm is finally applied to mth gate line 11m by repeating the foregoing actions.
Therefore, an image is displayed by sequentially driving pixels (P11~P1n)~(Pm1~Pmn) connected to the respective gate lines 111~11m, thereby driving pixels during one frame when the scan signals S1~Sm are sequentially applied starting with the first gate line 111 and ending with the mth gate line 11 m.
In yet another exemplary embodiment of the present invention, a pixel circuit of a display device including a plurality of pixels realizes a certain color per display period of time. The pixel circuit includes at least two light emitting elements, each said light emitting element for emitting a corresponding one of colors during a sub display period of time in the certain section. The at least two light emitting elements are sequentially driven time-divisionally during the display period of time, such that each said light emitting element emit s the corresponding one of the colors so that the pixel circuit realizes the certain color in the display period of time.
Referring to FIG. 4, an organic electroluminescent display device 50 according to the first exemplary embodiment includes a pixel part 500, a gate line driving circuit 510, a data line driving circuit 520 and an emission control signal generating circuit 590. The gate line driving circuit 510 sequentially generates scan signals S1'~Sm' to gate lines of the pixel part 500 during one frame. The data line driving circuit 520 sequentially supplies red, green and blue data signals D1'~Dn' to data lines of the pixel part 500 whenever scan signals are applied during one frame. The emission control signal generating circuit 590 sequentially supplies emission control signals EC_R, G, B1 ∼ EC_R, G, Bm for controlling emission of red, green and blue EL devices to emission control lines 591~59m of the pixel part 500 whenever scan signals are applied during one frame. In this and other embodiments, the EL devices may be arranged in stripe type, delta type or mosaic type. Further, at least one of the gate line driving circuit 510, the data line driving circuit 520 and the emission control signal generating circuit may have a redundancy function.
Referring to FIG. 5A, a pixel part 500' of an organic electroluminescent display device 50' includes a plurality of gate lines 511~51m to which scan signals S1'~Sm' are supplied from a gate line driving circuit 510, and a plurality of data lines 521~52n to which data signals D1'~Dn' are supplied from a data line driving circuit 520. The pixel part 500' also includes a plurality of emission control lines 591~59m to which emission control signals EC_R, G, B1 ~ EC_R, G, Bm are supplied from an emission control signal generating circuit 590, and a plurality of power supply lines 531~53n for supplying power supply voltage VDD1 ~ VDDn.
The pixel part 500' further includes a plurality of pixels P11'~Pmn' arranged in a matrix format, and connected to the plurality of gate lines 511~51m, the plurality of data lines 521~52n, the plurality of emission control lines 591~59m and the plurality of power supply lines 531~53n. Each of the plurality of pixels P11'~Pmn' is connected to one corresponding gate line in the plurality of gate lines 511~51m, one corresponding data line in the plurality of data lines 521~52n, one corresponding emission control line in the plurality of emission control lines 591~59m and one corresponding power supply line in the plurality of power supply lines 531~53n.
For example, the pixel P11' is connected to the first gate line 511 for supplying the first scan signal S1', the first data line 521 for supplying the first data signal D1', the first emission control line 591 for supplying the first emission control signal EC_R, G, B1, and the first power supply line 531 for supplying the first power supply voltage VDD1 .
Therefore, corresponding scan signals are applied to the pixels P11'~Pmn' through corresponding scan lines, and the corresponding red, green and blue data signals are sequentially supplied to the pixels P11'~Pmn' through corresponding data lines. Further, corresponding red, green and blue emission control signals are sequentially supplied to the pixels P11'~Pmn' through corresponding emission control lines, and corresponding power supply voltage is supplied to the pixels P11'~Pmn' through corresponding power supply lines. Each of the pixels indicates a certain color, such that an image is displayed during one frame by sequentially applying corresponding red, green and blue data signals to the pixels whenever corresponding scan signals are applied to the pixels and sequentially driving red, green and blue EL devices according to red, green and blue emission control signals, thereby sequentially emitting lights corresponding to the red, green and blue data signals.
FIG. 6 schematically illustrates a pixel circuit for one pixel in a time-divisionally driving type organic electroluminescent display device according to the first exemplary embodiment of the present invention. FIG. 6 illustrates one pixel P11' in a plurality of pixels.
Referring to FIG. 6, the pixel includes an active element 570 connected to the first gate line 511, the first data line 521, the first emission control line 591 and the first common power supply line 531, and red, green and blue EL devices EL1_R', EL1_G', EL1_B' connected in parallel between the active element 570 and a common voltage (e. g., ground) VSS. First electrodes, e.g., anode electrodes, are connected to the active element 570, and second electrodes, e.g., cathode electrodes, are commonly connected to the common voltage VSS, in the red, green and blue EL devices EL1_R', EL1_G', EL1_B'.
The red, green and blue EL devices EL1_R', EL1_G', EL1_B' should be time-divisionally driven so that a pixel P11' displays a certain color by driving the three red, green and blue EL devices EL1_R', EL1_G', EL1_B' during one frame since the red, green and blue EL devices EL1_R', EL1_G', EL1_B' share one active element 570 in a pixel circuit having the structure of FIG. 6. That is, the red, green and blue EL devices EL1_R', EL1_G', EL1_B' are time-divisionally driven during one frame so that the pixel P11' realizes a certain color by dividing one frame into three sub frames and driving one of the red, green and blue EL devices EL1_R', EL1_G', EL1_B' during each sub frame.
In other words, the active element 570 drives the red EL device EL1_R' using the emission control signal EC_R1 generated to the emission control line 591 from the emission control signal generating circuit 590 so that red color corresponding to red data is emitted if red data DR1' is applied as a data D1' applied to the data line 521 as the scan signal S1' is applied from the gate line 511 to the active element 570 in the first sub frame of one frame. Similarly, when the scan signal S1' is applied from the gate line 511 to the active element 570 in the second sub frame, green data DG1' is applied as the data D1' applied to the data line 521, and the green EL device EL1_G' is emitted by the emission control signal EC_G1 generated to the emission control line 591 from the emission control signal generating circuit 590 so that green color corresponding to the green data is emitted. Finally, when the scan signal S1' is applied from the gate line 511 to the active element 570 in the third sub frame, blue data DB1' is applied as the data D1' applied to the data line 521, and the blue EL device EL1_B' is emitted by the emission control signal EC_B1 generated to the emission control line 591 from the emission control signal generating circuit 590 so that blue col or corresponding to the blue data is emitted. Therefore, red, green and blue EL devices are sequentially driven time-divisionally during one frame so that each pixel emits a certain color to display an image.
FIG. 7A illustrates a block structural view of a pixel circuit of time-divisional driving type organic electroluminescent display device according to one exemplary embodiment of the present invention, and FIG. 8A illustrates one example of detailed circuit diagram of the pixel circuit of FIG. 7A. Pixel circuits of FIG. 7A and FIG. 8A illustrate examples of pixel circuit for sequentially driving red, green and blue EL devices EL1_R', EL1_G', EL1_B' time-divisionally during one frame.
Referring to FIG. 7A and FIG. 8A, the pixel P11' includes one gate line 511, one data line 521, three emission control lines 591 r, 591 g, 591 b, the power supply line 531, and an indication unit 560 time-divisionally driven by signals applied through the lines. The indication unit 560 includes a light emitting element for self-emitting light. The light emitting element includes red, green and blue EL devices EL1_R', EL1_G', EL1_B' for emitting red, green and blue respectively.
Further, the pixel P11' includes the active element 570 for sequentially driving the red, green and blue EL devices EL1_R', EL1_G', EL1_B' time - divisionally. The active element 570 includes a driving unit 540 for supplying driving current corresponding to red, green and blue data signals DR1', DG1', DB1' to the EL devices EL1_R', EL1_G', EL1_B' of the indication unit 560 whenever the scan signal S1' is applied, and a sequential control unit 550 for controlling the driving current corresponding to the red, green and blue data signals DR1', DG1', DB1'. The data signals are sequentially supplied to the red, green and blue EL devices EL1_R', EL1_G', EL1_B' from the driving unit 540 according to the emission control signals EC_R1, EC_G1, EC_B1.
As shown in FIG. 8A, the driving unit 540 includes a switching transistor M51 in which the scan signal S1' is supplied to gate from the gate line 511, and red, green and blue data signals DR1', DG1', DB1' are time-divisionally supplied to a source from the data line 521. The driving unit 540 also includes a driving transistor M52 having a gate connected to a drain of the switching transistor M51. A power supply voltage VDD1 is supplied to a source from the power supply voltage line 531, and a drain is connected to the sequential control unit 550. A capacitor C51 is connected between a gate and a source of the driving transistor M52.
The sequential control unit 550 is connected between the driving unit 540 and the indication unit 560 to time-divisionally and sequentially drive red, green and blue EL devices EL1_R', EL1_G', EL1_B' of the indication unit 560 according to red, green and blue emission control signals EC_R1, EC_G1, EC_B1 supplied through emission control lines 591 r, 591 g, 591 b from the emission control signal generating circuit 590.
The sequential control unit 550 includes first, second and third control devices connected between the drain of the driving transistor M52 and anodes of the red, green and blue EL devices EL1_R', EL1_G', EL1_B', respectively, to sequentially control time-divisional driving of the red, green and blue EL devices EL1_R', EL1_G', EL1_B' according to the emission control signals EC_R1, EC_G1,EC_B1.
The first control device includes a thin film transistor M55_R on which the first emission control signal EC_R1 is applied to a gate, a source is connected to the drain of the driving transistor M52, and a drain is connected to the anode of the red EL device EL1_R' to drive the red EL device EL1_R' correspondingly to a red data signal applied through the driving transistor M52 by the first emission control signal EC_R1.
The second control device includes a thin film transistor M55_G to which the second emission control signal EC_G1 is applied to a gate, a source is connected to the drain of driving transistor M52, and a drain is connected to the anode of the green EL device EL1_G' to drive the green EL device EL1_G' correspondingly to a green data signal applied through the driving transistor M52 by the second emission control signal EC_G1.
The third control device includes a thin film transistor M55_B to which the third emission control signal EC_B1 is applied to a gate, a source is connected to the drain of the driving transistor M52, and a drain is connected to the anode of the blue EL device EL1_B' to drive the blue EL device EL1_B' correspondingly to a blue data signal applied through the driving transistor M52 by the third emission control signal EC_B1.
Conventionally, each one of scan signals S1~Sm is sequentially applied to a plurality of gate lines from the gate line driving circuit 110 so that m scan signals are applied during one frame, and red, green and blue data signals DR1~DRn, DG1~DGn, DB1~DBn are simultaneously applied to red, green and blue data lines from the data line driving circuit 120 whenever the respective scan signals S1~Sm are applied so that pixels are driven as illustrated in FIG. 3.
In the described exemplary embodiment of the present invention, however, one frame is divided into three sub frames, scan signals are respectively applied to gate lines from gate line driving circuit 510 during each sub frame so that 3m scan signals are applied during one frame. In case of the first pixel, when the scan signal S1' is applied to the first gate line 511 during the first sub frame, the switching transistor M51 is turned on so that the red data signal DR1' is supplied to the driving transistor M52 from the data line 521, wherein the sequential control unit 550 drives the red EL device EL1_R' correspondingly to the red data signal DR1' as the thin film transistor M55_R (i.e., the first control device) is turned on by the first emission control signal EC_R1.
Next, the sequential control unit 550 drives the green EL device EL1_G' correspondingly to the green data signal DG1' as the scan signal S1' is applied to the first gate line 511 during the second sub frame so that the green data signal DG1' is supplied to the driving transistor M52 from the data line 521, and the thin film transistor M55_G (i.e., the second control device) is turned on by the second emission control signal EC_G1.
Finally, the sequential control unit 550 drives the blue EL device EL1_B' correspondingly to the blue data signal DB1' as the scan signal S1' is applied to the first gate line 511 during the third sub frame so that the blue data signal DB1' is supplied to the driving transistor M52 from the data line 521, and the thin film transistor M55_B (i.e., the third control device) is turned on by the third emission control signal EC_B1.
In this manner, the red data signals DR1'~DRn', the green data signals DG1'~DGn' and the blue data signals DB1'~DBn' are sequentially applied to the data lines so that red, green and blue EL devices EL_R', EL_G', EL_B' of pixels P11'~Pmn' are sequentially driven time-divisionally whenever the scan signals S1'~Sm' are applied during the respective sub frames during one frame.
Therefore, circuit structure can be simplified in a pixel circuit of the present invention as the red, green and blue EL devices EL_R', EL_G', EL_B' of the pixel P11' share an active element 570 so that each pixel requires one gate line, one data line, three emission control lines and one power supply line only.
FIG. 5B illustrates another block structure of a pixel part 500" in an organic electroluminescent display device 50" according to the first exemplary embodiment of the present invention. FIG. 7B illustrates another block structural view of a pixel circuit P11" of a time-divisional driving type organic electroluminescent display device of the present invention illustrated in FIG. 5B, and FIG. 8B illustrates a detailed circuit diagram of the pixel circuit P11" of FIG. 7B.
The pixel circuit P11" illustrated in FIG. 5B, FIG. 7B and FIG. 8B is substantially the same as the pixel circuit P11' of FIG. 5A, FIG. 7A and FIG. 8A except that a separate power supply line is installed so that a power supply voltage VDD1 is supplied to a capacitor C51' of a driving unit 540' in an active element 570', through a power supply line 531 b, and the power supply voltage VDD1 is supplied to a source of a driving transistor M52' through a power supply line 531 a. This is different from the pixel circuit P11' wherein the same power supply voltage VDD1 is supplied to the capacitor C51 of a driving unit 540 and the source of the driving transistor M52 through the same power supply line 531. Hence, in the pixel circuit P11", data signals are stored in the capacitor C51' more stably by separating power supply line supplied to the capacitor C51' from the power supply line supplied to the driving transistor M52'. In the pixel circuit P11", a driving transistor M51' is coupled in substantially the same manner as the driving transistor M51 is in the pixel circuit P11'.
First, when a scan signal S1'(R) is applied to the first gate line 511 from the gate line driving circuit 510 during a first sub frame 1SF_R in one frame, the first gate line 511 is driven, and red data signals DR1'~DRn' are supplied as data signals D1'~Dn' to the driving transistor of the pixels P11'~P1n' connected to the first gate line 511 from the data line driving circuit 520'.
When the emission control signal EC_R1 from the emission control signal generating circuit 590 for controlling the red EL device EL_R' of the pixels P11'~P1 n' connected to the first gate line is applied to the sequential control unit 550 through the emission control line 591r, the thin film transistor M55_R is turned on, and driving current corresponding to the red data signals DR1'~DRn' is supplied to the red EL device so that the red EL device is driven.
Subsequently, when a second scan signal S1'(G) is applied to the first gate line 511 during a second sub frame 1 SF_G of the first frame 1 F, green data signals DG1'~DGn' are supplied to the driving transistor M52 through the data lines 521~52n. When the emission control signal EC_G1 from the emission control signal generating circuit 590 for controlling the green EL device EL_G' of the pixels P11'~P1n' connected to the first gate line 511 is applied to the sequential control unit 550 through the emission control line 591 g, the thin film transistor M55_G is turned on, and driving current corresponding to the green data signals DG1'~DGn' is supplied to the green EL device so that the green EL device is driven.
Finally, when a third scan signal S1'(B) is applied to the first gate line 511 during a third sub frame 1SF_B of the first frame 1 F, blue data signals DB1'~DBn' are supplied to the driving transistor M52 through the data lines 521~52n. When the emission control signal EC_B1 from the emission control signal generating circuit 590 for controlling the blue EL device EL_B' of the pixels P11'~P1n' connected to the first gate line 511 is applied to the sequential control unit 550 through the emission control line 591 b, the thin film transistor M55_B is turned on, and driving current corresponding to the blue data signals DB1'~DBn' is supplied to the blue EL device so that the blue EL device is driven.
Subsequently, when a scan signal S2' is applied to the second gate line 512 per each sub frame of one frame, red, green and blue data signals DR1'~DRn', DG1'~DGn', DB1'~DBn' are sequentially applied to the data lines 521~52n. Further, em ission control signals EC_R2, EC_G2, EC_B2 from the emission control signal generating circuit 590 for sequentially controlling the red, green and blue EL devices of the pixels P21'~P2n' connected to the second gate line 512 are sequentially applied to the sequential control unit 550 through the emission control lines 591 r, 591 g, 591 b, respectively, as described above. Therefore, the thin film transistors M55_R, M55_G, M55_B are sequentially turned on, and driving currents corresponding to the red, green and blue data signals DR1'~DRn', DG1'~DGn', DB1'~DBn' are sequentially supplied to the red, green and blue EL devices so that the red, green and blue EL devices are time-divisionally driven.
The red, green and blue data signals DR1'~DRn', DG1'-DGn', DB1'~DBn' are sequentially applied to the data lines 521~52n, and emission control signals EC_Rm, EC_Gm, EC_Bm from the emission control signal generating circuit 590 for sequentially controlling the red, green and blue EL devices of the pixels Pm1'~Pmn' connected to the mth gate line 51m are sequentially applied to the sequential control unit 550 through the emission control lines 591 a, 591 b, 591 c, respectively, when the scan signal is applied to the mth gate line 51 m per each sub frame of one frame by repeating the above described actions. Accordingly, the thin film transistors M55_R, M55_G, M55_B are sequentially turned on, and driving currents corresponding to the red, green and blue data signals DR1'~DRn', DG1'~DGn', DB1'~DBn' are sequentially supplied to the red, green and blue EL devices so that the red, green and blue EL devices are time-divisionally driven.
FIG. 11 illustrates a block structural view of an organic electroluminescent display device 60 having a pixel part 600, according to a second exemplary embodiment of the present invention. An organic electroluminescent display device of FIG. 11 has the similar structure and operation as the organic electroluminescent display device 50 of FIG. 4 except that two gate line driving circuits 510a, 510b and two emission control signal generating circuits 590a, 590b are arranged.
That is, it is constructed in such a way that scan signals are supplied to some of the gate lines from a first gate line driving circuit 510a, and scan signals are supplied to the rest of the gate lines from a second gate line driving circuit 510b, wherein the scan signals are applied to the upper part of the gate lines from the first gate line driving circuit 510a, and the scan signals are sequentially applied to the lower part of the gate lines from the second gate line driving circuit 510b. In further embodiments, the scan signals may be applied to even numbered gate lines from a first gate line driving circuit, and scan signals may be applied to odd numbered gate lines from a second gate line driving circuit so as to reduce density of the gate lines arranged in the pixel part. In such cases, each of the first and second gate line driving circuits 510a, 510b may have circuitry for generating only half the scan signals so as to save cost and space.
In the organic electroluminescent display device 60, scan signals may be substantially simultaneously supplied to the gate lines from the driving circuits 510a, 510b to reduce signal delay and/or to supply redundancy. To provide such signal delay reduction or redundancy capabilities, the first and second gate line driving circuits 510a, 510b may generate scan signals S11~S1m and scan signals S21~S2m, respectively, corresponding to all of the scan lines.
In the organic electroluminescent display device 60, emission control signals are supplied to some of the emission control lines from a first emission control signal generating circuit 590a, and emission control signals are supplied to the rest of the emission control lines from a second emission control signal generating circuit 590b, wherein the emission control signals are applied to the upper part of the emission control signal lines from the first emission control signal generating circuit 590a, and the emission control signals are sequentially applied to the lower part of the emission control signal lines from the second emission control signal generating circuit 590b. In further embodiments, the emission control signals may be applied to even numbered emission control lines from a first emission control signal generating circuit, and the emission control signals may be applied to odd numbered emission control lines from a second emission control signal generating circuit, so as to reduce density of emission control lines arranged in the pixel part. In such cases, each of the first and second emission control line generating circuits 590a, 590b may have circuitry for generating only half the emission control signals so as to save cost and space.
In the organic electroluminescent display device 60, emission control signals may be substantially simultaneously supplied to the emission control lines from the first and second emission control signal generating circuits 590a, 590b to reduce signal delay and/or to supply redundancy. To provide such signal delay reduction or redundancy capabilities, the first and second emission control generating circuits 590a, 590b may generate emission control signals EC_R,G,B11-EC_R,G,B1m and emission control signals EC_R,G,B21~EC_R,G,B2m, respectively, corresponding to all of the emission control lines.
FIG. 12 illustrates a block structural view of an organic electroluminescent display device 70 having a pixel part 700 according to a third exemplary embodiment of the present invention. The organic electroluminescent display device 70 of FIG. 12 has the similar structure and operation as the organic electroluminescent display device 60 of FIG. 11 except that arrangement positions of two gate line driving circuits 510a', 510b' and two emission control signal generating circuits 590a', 590b' are different from the corresponding circuits of FIG. 11. The first gate line driving circuit 510a' may generate scan signals S11'~S1m', and the second gate line driving circuit 510b' may generate scan signals S21'∼S2m'. In other embodiments, the first and second gate line driving circuits 51 0a', 51 0b' may each generate only half of the scan signals so as to save cost and space.
The first emission control signal generating circuit 590a' may generate emission control signals EC_R, G, B11'~EC_R, G, B1m', and the second emission control signal generating circuit 590b' may generate emission control signals EC_R, G, B21'~EC_R, G, B2m'. In other embodiments, the first and second emission control signal generating circuits may each generate only half of the emission control signals so as to save cost and space.
A pixel circuit of a display device for realizing a certain color during a display period of time comprising:
an active element commonly connected to the at least two light emitting elements to drive the at least two light emitting elements,
The pixel circuit of a display device according to claim 1, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least two sub frames, and the at least two light emitting elements are time-divisionally driven in accordance with the sub frames inside the one frame.
The pixel circuit of a display device according to claim 1, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least three sub frames, the at least two light emitting elements are time-divisionally driven in accordance with at least two of the sub frames inside the one frame, and one of the at least two light emitting elements is driven again or the at least two light emitting elements are simultaneously driven in a remaining at least one of the sub frames.
The pixel circuit of a display device according to claim 3, wherein the remaining at least one of the sub frames is arbitrarily selected from the sub frames.
The pixel circuit of a display device according to claim 1, wherein a light emitting time of the at least two light emitting elements is controlled to control white balance.
The pixel circuit of a display device according to 1, wherein the display device is an FED (field emission display) or a PDP (plasma display panel).
The pixel circuit of a display device according to claim 1, wherein the at least two light emitting elements include a red, green, blue or white EL device.
The pixel circuit of a display device according to claim 7, the EL device having a first electrode and a second electrode, wherein the first electrode is connected to the active element, and the second electrode is connected to a reference voltage(Vss).
The pixel circuit of a display device according to claim 7, wherein the EL device is arranged in stripe type, delta type or mosaic type.
The pixel circuit of a display device according to claim 1, wherein the active element includes at least one switching element for driving the at least two light emitting elements.
The pixel circuit of a display device according to claim 10, wherein the at least one switching element is a thin film transistor, a thin film diode, a diode or a TRS (triodic rectifier switch).
The pixel circuit of a display device according to claim 1, wherein
the at least two light emitting elements comprise red, green and blue EL devices;
the active switching element comprises at least one switching transistor for time-divisionally transmitting red, green and blue data signals;
at least one driving transistor for time-divisionally driving the red, green and blue EL devices according to the red, green and blue data signals; and
The pixel circuit of a display device according to claim 12, wherein the red, green and blue EL devices are time-divisionally driven according to corresponding said emission control signals per each sub frame inside one frame comprising at least three sub frames.
The pixel circuit of a display device according to claim 13, wherein the red, green and blue EL devices are time-divisionally driven in three of the at least three sub frames, the red, green and blue EL devices are independently driven in a remaining one of the at least three sub frames, or at least two EL devices are simultaneously driven in the remaining one of the at least three sub frames.
The pixel circuit of a display device according to claim 12, wherein white balance is controlled by controlling a light emitting time of the red, green and blue EL devices in response to corresponding said emission control signals in the respective sub frames.
The pixel circuit of a display device according to claim 12, wherein first electrodes of the red, green and blue EL devices are commonly connected to the at least one driving transistor, and second electrodes of the red, green and blue EL devices are commonly connected to a reference voltage(Vss).
The pixel circuit of a display device according to claim 12, wherein the red, green and blue EL devices are arranged in stripe type, delta type or mosaic type.
The pixel circuit of an organic electroluminescent display device according to claim 1, wherein
the active element comprises a driving unit commonly connected to the red, green and blue EL devices to drive the red, green and blue EL devices; and
The pixel circuit of an organic electroluminescent display device according to claim 18, wherein the driving unit comprises at least one switching transistor for switching data signals; at least one driving transistor for supplying driving current corresponding to the data signals to the red, green and blue EL devices; and a capacitor for storing the data signals.
The pixel circuit of an organic electroluminescent display device according to claim 19, wherein the driving unit further comprises a threshold voltage compensation device for compensating a threshold voltage of the at least one driving transistor.
The pixel circuit of an organic electroluminescent display device according to claim 19, wherein a power supply voltage is supplied to the at least one driving transistor and the capacitor through a common power supply line, or the power supply voltage is supplied to the at least one driving transistor and the capacitor through separate power supply lines.
The pixel circuit of an organic electroluminescent display device according to claim 18, wherein the sequential control unit comprises first, second and third control devices for time-divisionally controlling emission of the red, green and blue EL devices by controlling a supply of driving current to the red, green and blue EL devices from a driving transistor using corresponding red, green and blue emission control signals.
The pixel circuit of an organic electroluminescent display device according to claim 22, wherein the first, second and third control devices comprise first, second and third thin film transistors in which the corresponding emission control signals are respectively applied to gates, sources are commonly connected to the driving unit, and drains are respectively connected to the red, green and blue EL devices.
The pixel circuit of an organic electroluminescent display device according to claim 23, wherein white balance is controlled by controlling an active on time of the corresponding emission control signals applied to the sequential control unit, thereby controlling time in which driving current is applied to corresponding said EL devices by the first, second and third control devices.
The pixel circuit of an organic electroluminescent display device according to claim 18, wherein the EL devices are arranged in stripe type, delta type or mosaic type.
The pixel circuit of an organic electroluminescent display device according to claim 1, wherein the active element comprises:
a fourth thin film transistor having one of a source and a drain connected to the other one of the source and the drain of the second thin film transistor, and a second emission control signal applied to a gate; and
a fifth thin film transistor having one of a source and a drain connected to the other one of the source and the drain of the second thin film transistor, and a third emission control signal applied to a gate; and wherein
the at least two light emitting elements comprise red, green and blue EL devices having first electrodes connected to the other ones of the source and the drain of the third, fourth and fifth thin film transistors, respectively, and second electrodes commonly connected to a reference voltage(Vss).
The pixel circuit of a display device according to claim 1, comprising a plurality of pixels, the pixel circuit for realizing a certain color per display period of time, wherein each said light emitting element is adapted to emit a corresponding one of colors during a sub display period of time in the display period of time and wherein the at least two light emitting elements are sequentially driven time-divisionally during the display period of time, such that each said light emitting element emits the corresponding one of the colors so that the pixel circuit realizes the certain color in the display period of time.
The pixel circuit of a display device according to claim 27, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least two sub frames, and the at least two light emitting elements are sequentially driven in accordance with the sub frames inside the one frame.
The pixel circuit of a display device according to claim 27, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least three sub frames, the at least two light emitting elements are time-divisionally driven in accordance with at least two of the sub frames inside the one frame, and one of the at least two light emitting elements is driven again or the at least two light emitting elements are simultaneously driven in a remaining at least one of the sub frames.
The pixel circuit of a display device according to claim 27, wherein a light emitting time of the at least two light emitting elements is controlled to control white balance.
The pixel circuit of a display device comprising a plurality of pixels according to claim 1, the pixel circuit for realizing a certain color during a display period of time, wherein the pixel circuit realizes the certain color during the display period of time by emitting one of the at least two light emitting elements for a sub display period of time so that the at least two light emitting elements time-divisionally emit the corresponding ones of the colors during the display period of time.
The pixel circuit of a display device according to claim 31, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least two sub frames, and the at least two light emitting elements are time-divisionally driven in accordance with the at least two sub frames inside the one frame.
The pixel circuit of a display device according to claim 31, wherein the display period of time is one frame, the sub display period of time is a sub frame, the one frame is divided into at least three sub frames, the at least two light emitting elements are time-divisionally driven in accordance with at least two of the sub frames inside the one frame, and one of the at least two light emitting elements is driven again or the at least two light emitting elements are simultaneously driven in a remaining one of the sub frames.
The pixel circuit of a display device according to claim 32, wherein a light emitting time of the at least two light emitting elements is controlled to control white balance.
a plurality of pixels, each said pixel comprising red, green and blue EL devices and at least one thin film transistor coupled to the red, green and blue EL devices to drive the red, green and blue EL devices,
wherein the red, green and blue EL devices of each said pixel comprise first electrodes commonly coupled to the at least one thin film transistor and second electrodes commonly connected to a reference voltage(Vss), and the red, green and blue EL devices are time-divisionally emitted by the at least one thin film transistor in each said pixel.
The display device according to claim 35, wherein the red, green and blue EL devices are time-divisionally driven inside one frame comprising at least three sub frames, in accordance with the sub frames.
The display device according to claim 35, wherein the pixels are arranged in stripe type, delta type or mosaic type.
EP07109819A 2003-11-14 2004-10-18 Display device and driving method thereof Withdrawn EP1821282A3 (en)
EP04090400A EP1531452B1 (en) 2003-11-14 2004-10-18 Pixel circuit for time-divisionally driven subpixels in an OLED display
EP04090400A Division EP1531452B1 (en) 2003-11-14 2004-10-18 Pixel circuit for time-divisionally driven subpixels in an OLED display
EP1821282A2 true EP1821282A2 (en) 2007-08-22
EP1821282A3 EP1821282A3 (en) 2008-01-23
EP07109819A Withdrawn EP1821282A3 (en) 2003-11-14 2004-10-18 Display device and driving method thereof
EP04090400A Active EP1531452B1 (en) 2003-11-14 2004-10-18 Pixel circuit for time-divisionally driven subpixels in an OLED display
EP (2) EP1821282A3 (en)
CN105659311B (en) * 2013-10-21 2018-01-23 夏普株式会社 Display device
EP1936597B1 (en) 2012-04-25 Organic light emitting diode display