The present invention claims the benefit of Japanese Patent Application No. 2010-23287, filed in Japan on Feb. 4, 2010, which is hereby incorporated by reference.
1. Field of the Invention
The present invention relates to a display device in which pixel data for display is written into each pixel arranged in matrix, and to a drive method for the display device.
2. Description of the Related Art
There have been proposed various types of display devices, typified by the one disclosed in Japanese Patent Application Laid-open No. 1998-214060, in which gradation display is performed by dividing each frame period into a plurality of sub-frame periods for driving.
In a normal driving mode, the data line voltage is controlled to control a current of the transistor Tr12, thereby controlling the emission amount (luminance) of the organic EL element EL. Further, in the normal driving mode, the transistor Tr12 is used in the saturation region, and the current flowing through the transistor Tr12 is a current Id, which is determined by a threshold voltage Vth, mobility μ, a gate width W, and a gate length L of the transistor Tr12, as expressed in the following expression.
I
d
=μC
o(W/L)(Vgs−Vth)2
where Vgs is a gate-source potential difference and Co is a gate capacitance per unit area. In a thin film transistor (TFT) formed on a glass substrate, especially a low-temperature polysilicon (LIPS) TFT, the values of the threshold voltage Vth and the mobility μ are varied among pixels, resulting in a problem of uneven display.
As a method for solving the problem, the data voltage on the data line is written so that the transistor Tr12 may be completely turned ON to serve as a simple switch (linear region operation) for directly applying “(positive power supply voltage PVDD)-(negative power supply voltage CV)” to the organic EL element, thereby performing gradation display under lighting control with each frame divided into a plurality of sub-frames.
The voltage-driven type device illustrated in
In view of the above-mentioned problems, as in Japanese Patent Application Laid-open No. 2002-351357, a time-division gradation display device using a current-driven type pixel drive circuit has been proposed. However, such a display device has problems that luminance becomes uneven because of fluctuations in individual current writing and that sufficient write time cannot be ensured.
As exemplified in Japanese Patent Application Laid-open No. 2006-243060, some ideas concerning the problem of the write time inherent in the current-driven type have been proposed. However, there still remains a problem in cost because a multi-bit current source driver has a complicated configuration and it is difficult to set individual current values with accuracy. Further, because the current luminous efficiency of the organic EL element is improving year by year, it is not unusual that a maximum drive current in one pixel of the display device is 1 mA or less. In such a case, a problem of the accuracy in minimum gradation arises.
The present invention provides a display device including pixels arranged in matrix, each including a current-driven type light emitting element and a drive transistor for supplying a current to the current-driven type light emitting element, in which: the current-driven type light emitting element is driven by dividing each frame period into a plurality of sub-frame periods for lighting time; and the drive transistor is controlled under current write driving using two write currents having a ratio of 1:1/2N and a sum of the two write currents.
Further, it is preferred that the display device according to the present invention further include two current sources for generating the two write currents, and that each write current be generated by a combination of the two write currents from the two current sources.
Further, it is preferred that, in the display device according to the present invention, when defining that a lighting period in a shortest sub-frame of the plurality of sub-frame periods is 1, a total of the lighting periods of the plurality of sub-frame periods be 2N−1 so as to perform N-bit gradation display, and to perform 2N-bit gradation display when combined with a drive current value of the write current.
Further, it is preferred that, in the display device according to the present invention, when defining that a shortest sub-frame period among the plurality of sub-frame periods is 1, each frame be constituted by one sub-frame having a length of 2k, where k is 0 to N−3, and three sub-frames each having a length of 2N-2, thereby providing redundancy to reduce false contouring of a moving image.
It is possible to suppress the influence of voltage rise due to fluctuations in the drive TFTs and the temporal change in the current-driven type light emitting element, and to perform uniform display operation.
In the accompanying drawings:
Now, an embodiment of the present invention is described below with reference to the accompanying drawings.
In this embodiment, pixel portions are subjected to current write type control, in which a write current having a maximum current value and a write current having another current value are set. The another current value is suppressed to a relatively small ratio of 1/2N, such as 1/8 or 1/16, of the maximum current value so that lighting time control is performed within a range for high-speed writing by using the two write current values of the maximum current and 1/2N thereof.
In this way, the order in a section for time gradation control is reduced by N bits, thereby solving the problem of the write time, which is inherent in a display device using a current-driven type circuit of time gradation display mode, to realize high-order gradation display. In addition, providing only two current set values offers an advantage in cost because of simple management and simple circuitry. It is also possible to improve luminance uniformity in the display device as a whole by integrating a circuit for correcting the two current values into a current writing section so that fluctuations in current among source lines may be corrected.
As illustrated in
The source driver 12 is connected to a current detection correction value writing section 14. The current detection correction value writing section 14 detects each current value of current sources provided for each column in the source driver 12 as described later, and determines a correction value therefor. The current detection correction value writing section 14 is connected to a correction memory 16, and the determined correction value of the current sources for each column is written into the correction memory 16 by the current detection correction value writing section 14. A current correction control section 18 reads out the correction value stored in the correction memory 16 according to a column having pixels to be written, and supplies the read correction value to the source driver 12. Therefore, each constant current value of the two current sources provided for each column in the source driver 12 is corrected by the correction value stored in the correction memory 16.
A vertical control signal from the timing control current selection circuit 10 is supplied to a gate driver 20. The gate driver 20 sequentially supplies power to gate lines Gate provided for rows of pixels 22. In other words, the source driver 12 sequentially receives the current selection signals on the pixels and outputs the image signal on the pixels in each column, and the image signal is controlled to be supplied to a corresponding row selected by the gate driver 20.
Note that, each pixel 22 is supplied with power supply voltages PVDD and CV. In general, one of the power supply voltages is connected to a supply electrode of an organic electroluminescence (EL) element and another thereof is connected to a drive transistor.
The pixel 22 is constituted by three transistors and one capacitor. A transistor Tr1 has a source connected to a data line DataB and a drain connected to a gate of a transistor Tr3. A transistor Tr2 has a source connected to a data line DataA and a drain connected to a source of the transistor Tr3. A storage capacitor Ch is disposed between the gate and source of the transistor Tr3. The transistor Tr3 has a drain connected to the power source PVDD having a voltage VPVDD. The source thereof is connected to an anode of an organic EL element EL. The organic EL element EL has a cathode connected to the power source CV having a voltage VCV. Note that, in the organic EL element EL, the anode serves as a pixel electrode and the cathode serves as a common electrode for all the pixels.
In the source driver 12, two current sources 24A and 24B are provided. The current source 24A has a constant current Imax and the current source 24B has a constant current Imax/2N. The current source 24A and the current source 24B are connected in common via a switch 26A and a switch 26B, respectively. A common connection terminal of the switches 26A and 26B is connected to a negative input terminal of an operational amplifier 28. A positive input terminal of the operational amplifier 28 is connected to a power source VX and supplied with a voltage Vx. An output terminal thereof is connected to the data line DataB. The common connection terminal of the switches 26A and 26B, which is connected to the negative input terminal of the operational amplifier 28, is further connected to the data line DataA. The example of
In the configuration described above, the circuits used as the pixel circuit and the source driver have a simple 3T-1C configuration and form a feedback loop in two source lines by the operational circuit and the current sources illustrated in the upper part of
In the configuration described above, when a horizontally-extending gate line n (Gate) is changed to high level to turn ON selection TFTs (transistor Tr1 and transistor Tr2), the circuit including the operational amplifier operates as a voltage follower. Then, a gate voltage of the transistor Tr3 is controlled so that a source potential Vx′ of the transistor Tr3 may be equal to the voltage Vx at the positive input terminal of the operational amplifier 28.
On this occasion, the reference voltage Vx of the voltage follower is set to a voltage for turning OFF the organic EL element EL as a light emitting element, and hence the current Ix drawn into the current source 24 becomes equal to a current Ix′ flowing through the transistor Tr3. Then, the gate potential of the transistor Tr3 at that time is charged into the storage capacitor Ch.
In other words, if both of the transistors Tr1 and Tr2 are turned ON, as illustrated in
Subsequently, the gate line n is changed to low level to turn OFF the transistors Tr1 and Tr2, and the voltage charged in the storage capacitor Ch maintains the gate-source voltage of the transistor Tr3, allowing the organic EL element to emit light by bootstrapping. In other words, the transistor Tr3 maintains the current Ix, and an anode voltage of the organic EL element EL is increased to a voltage Vz which is obtained when the current Ix flows through the organic EL element, with the result that the organic EL element emits light.
In
When the transistors Tr1 and Tr2 are turned OFF, the data line DataA and the data line DataB are disconnected from the pixel circuit but the gate-source voltage Vgs of the transistor Tr3 is maintained, and hence the current Ix′ of the transistor Tr3 and the current I of the organic EL element EL are both made equal to the current Ix.
Next, description is given of gradation control with the current amounts of the current sources 24A and 24B set to Imax and Imax/8, which is 1/8 of Imax, respectively.
In Drive Example 1, those two kinds of drive currents and three kinds of sub-frames (T1, 2T1, and 4T1) are used to perform gradation display of 6 bits in total.
If the minimum average luminance is obtained when the pixel is lit with Imax/8 for T1, the maximum average luminance corresponds to the case of lighting with “Imax/8+Imax” for a whole period, and is estimated as (1+8)×(1+2+4)=63 times the minimum average luminance. In other words, luminance obtained by lighting with the current “Imax/8+Imax” for a period 7T1 is a maximum average luminance Lmax, and an average luminance obtained by lighting with the current Imax/8 only for the period T1 takes Lmax/63. The gradation expression of 6 bits from 0 to 63 can be performed by a combination of Lmax×1/63, Lmax×2/63, Lmax×4/63, and Lmax×8/63 illustrated in
As illustrated in
As Drive Example 2,
Further, as illustrated in
Still further, it is also preferred that the outputs of the circuits in the source driver 12 be cramped to VCV during turn-OFF operation, thereby performing the turn-OFF operation reliably and speedily. In other words, in a sub-frame in which light is OFF, during the write period, VCV may be supplied to the positive input terminal of the operational amplifier 28 while bypassing VX in
This configuration has a problem of occurrence of false contouring. Specifically, for example, a gradation change point as illustrated in
Regarding such a large change point, the longest sub-frame is divided into two, and as illustrated in
Further, if the source driver in the configuration of
Note that, the configuration of this embodiment is also applicable to a display device using other current-driven type light emitting elements than the organic EL element.
Number | Date | Country | Kind |
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2010-023287 | Feb 2010 | JP | national |