1. Field of the Invention
The present invention relates to a light emission drive circuit for an organic electroluminescence element and a display device incorporating the drive circuit.
2. Description of the Related Art
Conventionally known is a display panel having organic electroluminescence elements (hereinafter simply referred to as organic EL elements), or one type of a capacitive light-emitting element, disposed in a matrix. An active display device designed to drive a display panel having organic EL elements has a light emission drive circuit configured for each pixel as shown in FIG. 1.
The light emission drive circuit for a single pixel shown in
Now, the operation of the light emission drive circuit will be described below. First, when a scan pulse is supplied to the gate G of the FET 1 via the scan line Yi, the FET 1 turns on, allowing a current corresponding to the voltage of a data signal supplied via the data line Xj to the source S to flow from the source S to the drain D. During the ON period of the FET 1, the capacitor 3 is charged, and the charge voltage is supplied to the gate G of the FET 2. The FET 2 turns on (in an active state or in its saturation state) in response to the charge voltage. When the FET 2 is in the ON state, a forward voltage greater than or equal to a light emission threshold voltage is applied to the EL element 5 to pass a drive current from the ground line 6 through the source S—the drain D of the FET 2 and the EL element 5, thereby causing the EL element 5 to emit light. When the scan pulse is no longer supplied to the gate G of the FET 1, the FET 1 becomes an OFF state, and the FET 2 allows the charge stored in the capacitor 3 to hold the voltage of the gate G, and maintain the drive current as well as the light emission of the EL element 5 until the EL element 5 is scanned again.
As described above, in the light emission drive circuit for a conventional display device, as the FET 1 for writing a data signal via a data line onto a capacitor, the light emission drive circuit for a conventional display device employs a MOS-FET switching element of an organic semiconductor serving as a channel material. With such a MOS-FET switching element, it is necessary to scale up the MOS-FET itself in order to provide a current flowing therethrough in its ON state and sufficiently large enough to flow through a typical low-temperature polysilicon TFT (Thin Film Transistor) in a display panel. On the other hand, an increase in size of the MOS-FET would cause the parasitic capacitance between the gate and drain of the MOS-FET to increase accordingly. The presence of the gate-drain parasitic capacitance would cause an on-off control pulse signal voltage applied to the gate other than a drain-source ON current to be differentiated by the gate-drain parasitic capacitance into a charge/discharge current, which is in turn introduced into a data hold capacitor resulting in a change in the original capacitor hold voltage. This phenomenon is also found in a typical TFT of a polysilicon-based material. However, since its mobility of carriers of the organic semiconductor material is extremely lower than that of the typical polysilicon-based material, the drain-source current is relatively reduced to degrade the ratio between a current induced by the drain-source parasitic capacitance and the drain-source current. This causes the phenomenon to be evident to such an extent of interfering with the operation of the TFT formed of an organic semiconductor material. As a result, there was a problem that a voltage corresponding to a predetermined desired brightness was not applied to the gate of the FET 2, thereby causing a variation in the light emission brightness of the EL element 5.
It is therefore an object of the present invention to provide an active light emission drive circuit and a display device which enable an organic EL element to emit light at a brightness corresponding to a data signal without a capacitor hold voltage for holding data being disturbed by an write operation.
An active type of light emission drive circuit according to the present invention comprises: a switching element which turns on in response to an ON command pulse to pass a data signal therethrough; a capacitive element which holds the data signal passed through the switching element during the ON state of the switching element; and a drive element which supplies a forward drive current to an organic electroluminescence element in response to the data signal held in the capacitive element to cause the organic electroluminescence element to emit light, wherein the switching element is a switching diode element which turns on by a potential difference between the ON command pulse and the data signal when the ON command pulse is supplied.
A display device according to the present invention comprises: a display panel having a plurality of data lines, a plurality of scan lines intersecting with the plurality of data lines, and a plurality of sets each of which has an organic electroluminescence element and an active type of light emission drive circuit, the sets being disposed at the respective intersections of the plurality of data lines and the plurality of scan lines; and a controller which supplies a scan pulse in sequence at predetermined time intervals to one scan line of the plurality of scan lines and supplies a data signal to at least one data line of the plurality of data lines to allow an organic electroluminescence element located at an intersecting portion of the one data line and the at least one data line to emit light, wherein the light emission drive circuit includes: a switching diode element which turns on by a potential difference between the scan pulse and the data signal when the scan pulse is supplied through the one scan line; a capacitive element which holds the data signal passed through the diode element while the diode element is in the ON state; and a drive element which supplies a forward drive current to the organic electroluminescence element in response to the data signal held in the capacitive element to cause the organic electroluminescence element to emit light.
Now, the present invention will be explained below in more detail with reference to the accompanying drawings in accordance with the embodiments.
The display panel 11 has an active matrix array of m by n pixels, which have EL light emission drive circuits 111,1 to 11m,n, respectively, as shown in FIG. 2. The EL light emission drive circuits 111,1 to 11m,n are all configured in the same manner and connected to the scan pulse supply circuit 12 via scan lines Y1 to Yn as well as to the data signal supply circuit 13 via data lines X1 to Xm, respectively. The controller 15 generates a scan control signal and a data control signal in response to input image data. The scan control signal including a Y transfer clock signal and a Y transfer pulse is supplied to the scan pulse supply circuit 12. The data control signal including an X transfer clock signal, an X transfer pulse, and a serial m-bit data signal is supplied to the data signal supply circuit 13. The X transfer clock signal has a higher frequency than the Y transfer clock signal so that m clocks of X transfer clock signals are generated in one clock period of the Y transfer clock signal.
As shown in
As shown in
Since the light emission drive circuits 111,1 to 11m,n are configured in the same manner as described above, the configuration of the light emission drive circuit 111,1 will be described below.
As shown in
Now, the operation of the light emission drive circuit 111,1 for allowing the organic EL element 25 to emit light will be described below. First, a scan pulse is supplied to one end of the capacitor 23 from the scan pulse supply circuit 12 via the scan line Y1. The scan pulse is a write pulse for writing a data signal on the capacitor 23. As shown in
When the scan pulse ends the write period, the light emission drive circuit 111,1 now in a hold period, causes the potential of the scan line Y1 to change from 0V to Va. This in turn causes the capacitor 23 to hold the charge stored thereon and the potential Vg of the other end of the capacitor 23 to increase by Va from the hold level at the point in time of ending the write operation, as shown in FIG. 5C. The diode 22 is reverse biased and thus turned off. On the other hand, the FET 21 to the gate of which the potential Vg increased by Va is applied is in an ON state (including an active state) corresponding to the level of the potential Vg. Accordingly, a drive current responsive to the conduction state of the FET 21 flows through the organic EL element 25, which in turn emits light. The light-emission brightness corresponds to the value of the drive current.
The diode 22 shown in
When the scan pulse ends the write period, the light emission drive circuit 111,1, now in a hold period, causes the potential of the scan line Y1 to change from Va to 0V. This in turn causes the capacitor 23 to hold the charge stored thereon and the potential Vg of the other end of the capacitor 23 to decrease by Va from the hold level at the point in time of ending the write operation, as shown in FIG. 7C. The diode 22 is reverse biased and thus turned off. On the other hand, the FET 21 to the gate of which the potential Vg decreased by Va is applied is in an ON state (including an active state) corresponding to the level of the potential Vg. Accordingly, a drive current responsive to the conduction state of the FET 21 flows through the organic EL element 25, which in turn emits light. The light-emission brightness corresponds to the value of the drive current.
In
As described with reference to each of the aforementioned embodiments, the organic diode element can be used as a switching element for writing the data signal to write the data signal at higher speeds when compared with a light emission drive circuit employing the organic MOS-FET in a prior art display device, and as well applied to a moving image according to a video signal. Furthermore, the diode element can provide a large current in a small area, thereby reducing the stray capacitance of the diode element as well as leakage to the capacitor caused by a distortion in pulse waveform at its rising and trailing edges. Accordingly, it is possible to prevent the light emission brightness of the EL element from being disturbed.
Since light emission drive circuits 311,1 to 31m,n on the display panel 31 in the display device of
As shown in
The light emission drive circuits 311,1 and 311,2 are configured in the same manner as the light emission drive circuit 311,1. The light emission drive circuit 311,2 is connected to the scan lines Y1, Y2 as well as to the data line X1, while the light emission drive circuit 311,3 is connected to the scan lines Y2, Y3 as well as to the data line X1.
The scan pulse supply circuit 32 generates the scan pulse in sequence from the scan line Y0 toward Yn. A scan line is at 0V when the scan pulse is supplied thereto and the other scan lines are at potential Va. First, the scan pulse from the scan line Y0 is supplied to the light emission drive circuit 311,1 as a reset signal. As shown in
Then, when the scan pulse supply circuit 32 stops supplying the scan pulse to the scan line Y0, the scan line Y0 is at potential Va to turn off the organic diode 43. Thereafter, the scan pulse supply circuit 32 supplies the scan pulse to one end of the capacitor 44 via the scan line Y1. This scan pulse serves as an address signal for writing the data signal to the capacitor 44. As shown in
The scan pulse of the scan line Y1 is supplied to the light emission drive circuit 311,2 as a reset signal. Like the light emission drive circuit 311,1 being reset as described above, the light emission drive circuit 311,2 is also reset.
When the scan pulse ends the write period via the scan line Y1, the light emission drive circuit 311,1, now in a hold period, causes the potential of the scan line Y1 to change from 0V to Va. This in turn causes the capacitor 44 to hold the charge stored thereon and the potential Vg of the other end of the capacitor 44 to increase by Va from the hold level at the point in time of ending the write operation, as shown in FIG. 10D. The diode 42 is reverse biased and thus turned off. On the other hand, the FET 41 to the gate of which the potential Vg increased by Va is applied is in an ON state (including an active state) corresponding to the level of the potential Vg. Accordingly, a drive current responsive to the conduction state of the FET 41 flows through the organic EL element 45, which in turn emits light. The light-emission brightness corresponds to the value of the drive current.
The organic diodes 42, 43 shown in
The light emission drive circuits 311,1 to 31m,n on the display panel 31 in the display device of
As shown in
In
The operations of the light emission drive circuit 311,1 of
Then, when the scan pulse supply circuit 32 stops supplying the scan pulse to the scan line Y0, the scan line Y0 is at potential Va to turn off the organic diode 43. Thereafter, the scan pulse supply circuit 32 supplies the scan pulse to one end of the capacitor 44 via the scan line Y1. This scan pulse serves as an address signal for writing the data signal to the capacitor 44. As shown in
The scan pulse of the scan line Y1 is supplied to the light emission drive circuit 311,2 as a reset signal. Like the light emission drive circuit 311,1 being reset as described above, the light emission drive circuit 311,2 is also reset.
When the scan pulse ends the write period via the scan line Y1, the light emission drive circuit 311,1, now in a hold period, causes the potential of the scan line Y1 to change from 0V to Va. This in turn causes the capacitor 44 to hold the charge stored thereon and the potential Vg of the other end of the capacitor 44 to increase by Va from the hold level at the point in time of ending the write operation, as shown in FIG. 14D. The diode 42 and the diode 47 are reverse biased and thus turned off. On the other hand, the FET 41 to the gate of which the potential Vg increased by Va is applied is in an ON state (including an active state) corresponding to the level of the potential Vg. Accordingly, a drive current responsive to the conduction state of the FET 41 flows through the organic EL element 45, which in turn emits light. The light-emission brightness corresponds to the value of the drive current.
During this hold period, the diode 46 is turned on according to the potential at connection point P between the diode 42 and the diode 47. As shown in
The organic diodes 42, 43, 46, 47 shown in
On the other hand, it is also possible to employ a capacitor in place of the diode 46. The arrangement for preventing crosstalk caused by the diodes 46 and 47 can also be added to an arrangement that includes no reset operation function of
In each of the aforementioned embodiments, a light emission drive circuit for a single pixel has been illustrated; however, for color display, three or R, G, and B light emission drive circuits constitute one pixel.
Furthermore, in each of the aforementioned embodiments, the present invention is implemented as a light emission drive circuit for use with a display panel, but may also be applicable to an independent light emission drive circuit. The independent light emission drive circuit would be supplied with an ON command pulse, in place of the scan pulse, to turn on a switching element for writing data in the light emission drive circuit.
As described above, according to the present invention, an organic EL element is allowed to emit light at a brightness corresponding to a data signal without having to scale up a switching element for writing the data signal.
This application is based on a Japanese Patent Application No. 2002-291175 which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2002-291175 | Oct 2002 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5990629 | Yamada et al. | Nov 1999 | A |
6556176 | Okuyama et al. | Apr 2003 | B1 |
6583775 | Sekiya et al. | Jun 2003 | B1 |
6587087 | Ishizuka | Jul 2003 | B1 |
Number | Date | Country | |
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20040066359 A1 | Apr 2004 | US |