JP2004037656A - Driving method, driving circuit, and display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a driving method for a pixel circuit which does not give rise to a delay in assigning intensity levels even during low gradation, a driving circuit, and a display device. <P>SOLUTION: The driving circuit for driving the pixel circuit 28 to perform assigning intensity levels by a current capacity with a current output is provided with a voltage generating section 11 for generating the first prescribed voltage and a current generating section 14 for generating the current corresponding to gradation data 13. When the gradation data 13 is greater than the first prescribed value, the current is outputted from the section 14 for the first prescribed period within one horizontal period and when the gradation 13 is smaller than the first prescribed value, the first prescribed voltage is outputted from the section 11 within the second prescribed period in the first prescribed period in place of the current output or the first prescribed voltage is outputted simultaneously with the current output. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a driving method, a driving circuit, and a display device for outputting a current for driving a pixel circuit such as an organic electroluminescent device that performs a gray scale display by a current amount.
[0002]
[Prior art]
The organic light-emitting element is a self-luminous element, and thus does not require a backlight required for a liquid crystal display device, and is expected as a next-generation display device because of its advantages such as a wide viewing angle.
[0003]
As in the case of organic light-emitting devices, the luminous intensity of the device is not proportional to the electric field applied to the device, and the luminous intensity of the device is proportional to the current density flowing through the device. In contrast to the variation in the signal value, the variation in the light emission intensity can be reduced by performing gradation display by current control.
[0004]
FIG. 24 shows a block configuration of a driving circuit for outputting a current, which is used in a conventional display device for performing a gray scale display by a current amount. In the conventional driving circuit, the current generator 114 generates a current in accordance with the input grayscale data, and supplies the current to an output 118 connected to the source signal line 21a at a predetermined timing. If the grayscale data is different, the current generator 114 generates a current corresponding to the different grayscale data and outputs the same to the output 118 similarly.
[0005]
FIG. 25 illustrates an example of a display device in which a source driver including such a driving circuit is configured using 101. In order to display the organic light emitting element 24 of each pixel 28 shown in FIG. 25, the transistors 22c and 22d are turned on by the signal line 25 within one horizontal scanning period, and the power supply 27 supplies the transistor 22a and the source signal line 21a via the transistor 22a and the source signal line 21a. The current (I3) is drawn into the source driver 101. FIG. 18A shows an equivalent circuit around the transistor 22a in this state. In FIG. 18A, the source driver 101 is shown as a current source 125.
[0006]
At this time, gradation display is performed according to the magnitude of the current amount. Charge corresponding to a gate voltage corresponding to a drain current of the transistor 22a is stored in the capacitor 23. That is, when a current flows through the transistor 22a by being drawn by the current source 125, when a current I3 flows, a voltage V3 determined from the VI characteristic between the source and the drain of the transistor 22a shown in FIG. The electric charge corresponding to the voltage V3 is stored in the capacitor 23.
[0007]
Thereafter, the transistor 22b is turned on by the signal line 26, the transistors 22c and 22d are turned off by the signal line 25, and a current I3 according to the charge of the capacitor 23 flows from the power supply 27 to the organic light emitting element 24 via the transistor 22a. .
[0008]
[Problems to be solved by the invention]
However, in a display device using a conventional driving circuit, the current flowing through the source signal line 21a gradually changes due to the product of the floating capacitance 29a of the source signal line 21a and the resistance between the source and drain of the transistor 22a. Therefore, when the value of the floating capacitance 29a and the resistance value increase, the current may not change to a predetermined value within one horizontal scanning period.
[0009]
For example, consider a case where the current source 125 is controlled to change the current flowing through the transistor 22a from I3 to I1 shown in FIG. According to the characteristics of the transistor 22a in FIG. 18B, the resistance between the source and the drain of the transistor 22a is larger when the current I1 flows than when the current I3 flows.
[0010]
As described above, as the current flowing through the source signal line 21a becomes smaller (lower gradation), the resistance between the source and the drain of the transistor 22a becomes larger. The time constant when the current changes from I3 to I1 is represented by the product of the resistance of the path and the stray capacitance 29a. Therefore, the change takes longer as the current decreases. Depending on the diode characteristics of the transistor 22a and the capacitance of the stray capacitance 29a of the source signal line 21a, for example, it takes 50 μs to change the current flowing through the source signal line 21a to 1 μA. It takes 250 μs.
[0011]
The value of the current flowing through the source signal line 21a is supplied from the power supply 27 to the source signal line 21a via the transistor 22a, and the charge of the floating capacitor 29a is changed to change the voltage of the source signal line 21a. The current flowing through 22a (= current flowing through source signal line 21a) changes. Since the amount of supplied electric charge is small in a region where the current is small, the voltage change of the source signal line 21a is delayed, and as a result, the change of the current value is also delayed.
[0012]
As a result, the horizontal scanning period cannot be shortened, and there is a problem that flicker occurs due to a decrease in the frame frequency depending on the number of display rows.
[0013]
In view of the above problems, it is an object of the present invention to provide a driving method, a driving circuit, and a display device of a pixel circuit which do not cause a delay in gradation display even at a low gradation.
[0014]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a driving method for driving a pixel circuit for performing a gray scale display by a current amount by a current output, wherein the first gray scale data is equal to or more than a first predetermined value. In the case, the current output is performed for a first predetermined period within one horizontal period, and when the first gradation data is smaller than the first predetermined value, a second predetermined period during the first predetermined period is set. A driving method for outputting a first predetermined voltage instead of or simultaneously with the current output during a period.
[0015]
According to a second aspect of the present invention, there is provided a driving circuit for driving a pixel circuit that performs gradation display by a current amount by a current output, wherein the first voltage generating section generates a first predetermined voltage; A first current generator for generating a current corresponding to the grayscale data, wherein when the first grayscale data is equal to or greater than a first predetermined value, the first current generator generates the current from the first current generator. If the first gradation data is output for a first predetermined period within one horizontal period and the first gradation data is smaller than the first predetermined value, the first predetermined voltage is output from the first voltage generator to the first predetermined period. A drive circuit for outputting the first predetermined voltage instead of or simultaneously with the current output during a second predetermined period within one predetermined period.
[0016]
According to a third aspect of the present invention, there is provided a driving circuit for driving a pixel circuit which performs gradation display by a current amount by a current output, wherein the second predetermined voltage, the third predetermined voltage, and the fourth predetermined voltage A second voltage generator for generating at least one of the voltages, a second current generator for generating a current corresponding to the second grayscale data, and a second current generator for generating a current corresponding to the third grayscale data A third current generating section for generating a current; and a fourth current generating section for generating a current corresponding to the fourth gradation data, wherein the second gradation data is equal to or more than a second predetermined value. In this case, a current corresponding to the second grayscale data is output from the second current generator for a first predetermined period within one horizontal period, and the third grayscale data is output as a third predetermined value. In the case described above, the current corresponding to the third grayscale data is output from the third current generator in the first horizontal period. Is output for a predetermined period of time, and when the fourth grayscale data is equal to or greater than a fourth predetermined value, a current corresponding to the fourth grayscale data is output from the fourth current generating unit in the first horizontal period. 1 is output for a predetermined period, and when the second gradation data is smaller than the second predetermined value, the second predetermined voltage is within a second predetermined period of the first predetermined period. If the second predetermined voltage is output instead of the second current output or simultaneously with the second current output, and the third gradation data is smaller than the third predetermined value, In the second predetermined period of the first predetermined period, the third predetermined voltage is used instead of the third current output or simultaneously with the third current output. Output, and when the fourth gradation data is smaller than the fourth predetermined value, the fourth gradation data The second predetermined voltage is output instead of the fourth current output or simultaneously with the fourth current output within a second predetermined period of the first predetermined period. It is a driving circuit.
[0017]
According to a fourth aspect of the present invention, in the driving circuit according to the second aspect, the first predetermined voltage is a voltage corresponding to the lowest first gradation data among the first gradation data. is there.
[0018]
A fifth aspect of the present invention is the drive circuit according to the fourth aspect of the present invention, wherein the first predetermined voltage is a voltage corresponding to zero gradation data of the first gradation data.
[0019]
In a sixth aspect of the present invention, the second predetermined voltage is a voltage corresponding to the lowest second gradation data among the second gradation data, and the third predetermined voltage is A voltage corresponding to the lowest third gradation data among the third gradation data, wherein the fourth predetermined voltage is the voltage corresponding to the lowest fourth gradation data among the fourth gradation data. 9 is a driving circuit according to a third embodiment of the present invention, which has a corresponding voltage.
[0020]
A seventh aspect of the present invention is the driving circuit according to any one of the second to sixth aspects of the present invention, wherein the second predetermined period does not include the end point of the first predetermined period.
[0021]
An eighth aspect of the present invention is the driving circuit according to any one of the second to seventh aspects of the present invention, wherein the second predetermined period includes a start point of the first predetermined period.
[0022]
According to a ninth aspect of the present invention, a first switch connected between an output side of the voltage generation unit and a source signal line of the pixel circuit, and grayscale data are input, and the first switch is connected to the first switch in accordance with the grayscale data. A voltage output control unit for controlling the operation of the first switch; a second switch connected between an output side of the current generation unit and a source signal line of the pixel circuit; and an operation of the second switch And a current output control unit for controlling the driving circuit according to any one of the second to eighth aspects of the present invention.
[0023]
According to a tenth aspect of the present invention, there is provided a driving circuit for driving a pixel circuit that performs a gray scale display by a current amount with a current output, including a current generating unit that generates a current corresponding to the gray scale data, and is used for the pixel circuit. A display time of one display element during one vertical scanning period is 1 / N times (N> 1) a period obtained by subtracting a first predetermined period within one horizontal scanning period from one vertical scanning period; The current output from the current generator is N times as large as the current flowing when the display element is displayed for a period obtained by subtracting a first predetermined period in one horizontal scanning period from one vertical scanning period. Which is a driving circuit.
[0024]
An eleventh aspect of the present invention is the driving circuit according to any one of the second to tenth aspects, wherein the first predetermined period is one horizontal scanning period.
[0025]
According to a twelfth aspect of the present invention, there is provided a source driver including the driving circuit according to any one of the second to eleventh aspects, a source signal line connected to the source driver, a first control signal and a second control signal. A gate driver for outputting a control signal, a first control line connected to the gate driver and transmitting the first control signal, and a first control line connected to the gate driver and transmitting the second control signal A second control line and a plurality of pixel circuits corresponding to the pixels, the pixel circuit comprising: a display element having one end grounded; and a first power supply having a drain connected to a power supply. A second transistor whose source side is connected to the other end of the display element, a third transistor whose drain side is connected to the drain side of the second transistor, A fourth transistor having a source connected to the drain of the transistor, a capacitor having one end connected to the gate of the first transistor, and the other end connected to the drain of the first transistor; A source side of the first transistor is connected to a drain side of the second transistor, a gate side of the second transistor is connected to the second control line, and the third transistor A gate side of the transistor is connected to the first control line, a source side of the third transistor is connected to the source signal line, and a gate side of the fourth transistor is connected to the first control line. The fourth transistor is a display device, wherein a drain side of the fourth transistor is connected to a gate side of the first transistor.
[0026]
According to a thirteenth aspect of the present invention, there is provided a source driver including the driving circuit according to any one of the second to eleventh aspects of the present invention, a source signal line connected to the source driver, a third control signal, A gate driver for outputting a control signal and a fifth control signal, a third control line connected to the gate driver and transmitting the third control signal, and a third control line connected to the gate driver; A display comprising: a fourth control line to which a fourth control signal is transmitted; a fifth control line connected to the gate driver, to which the fifth control signal is transmitted; and a plurality of pixel circuits corresponding to the pixels. The pixel circuit includes a display element having one end grounded, a first transistor having a drain connected to a power supply, and a second transistor having a source connected to the other end of the display element. Transistor A third transistor having a source connected to the source signal line, a fourth transistor having a source connected to the drain of the third transistor, and a source having a source connected to the drain of the third transistor; A fifth transistor connected to the first transistor; a capacitor having one end connected to the gate side of the first transistor and the other end connected to the drain side of the first transistor; The source of the transistor is connected to the drain of the second transistor, the gate of the second transistor is connected to the fifth control line, and the gate of the third transistor is connected to the third transistor. Connected to a control line, the gate side of the fourth transistor is connected to the fourth control line, and the drain side of the fourth transistor is connected The gate side of the first transistor is connected to the gate side of the fifth transistor, the gate side of the fifth transistor is connected to the gate side of the first transistor, and the drain side of the fifth transistor is connected to the first transistor. A display device connected to the drain side.
[0027]
The fourteenth invention is the display device according to the twelfth or thirteenth invention, wherein the display element is an organic light emitting element.
[0028]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
FIG. 1 shows a configuration of a driving circuit according to Embodiment 1 of the present invention. Hereinafter, the configuration and operation of the driving circuit according to the present embodiment will be described with reference to FIGS.
[0029]
The driving circuit shown in FIG. 1 generates a current according to grayscale data 13 which is an example of first grayscale data of the present invention, which is an example of the first predetermined voltage of the present invention. And a voltage generator as an example of a first voltage generator of the present invention that generates a voltage corresponding to zero gradation (hereinafter referred to as a black voltage). 11, a voltage output control unit 12 for controlling an output from the voltage generation unit 11 in accordance with the grayscale data 13, and a second embodiment of the present invention for turning on and off the output from the voltage generation unit 11 under the control of the voltage control unit 12. A switch 16 as an example of the first switch, a current output control unit 15 for controlling the output from the current generation unit 14, and a switch for turning on and off the output from the current generation unit 14 under the control of the current output control unit 15. FIG. 3 is an example of a second switch of the present invention. And a switch 17.
[0030]
FIG. 2 shows an example of a display device configured using the source driver 1 having such a driving circuit.
[0031]
The display device shown in FIG. 2 includes a signal line 25 which is an example of a first control line of the present invention for outputting a first control signal, and a second control of the present invention for outputting a second control signal. The display device includes a gate driver 2 having a signal line 26 which is an example of a line, and a plurality of pixel circuits corresponding to pixels.
[0032]
Here, the configuration of the pixel circuit 28a among the plurality of pixel circuits will be described. Other pixel circuits have the same configuration. The pixel circuit 28a includes an organic light-emitting element 24 which is an example of a display element of the present invention having one end grounded, a transistor 22a which is an example of a first transistor of the present invention having a drain connected to a power supply 27, and An example of the second transistor of the present invention in which the source side is connected to the other end of the organic light emitting element 24, and an example of the third transistor of the present invention in which the drain side is connected to the drain side of the transistor 22b , A transistor 22d, which is an example of a fourth transistor of the present invention, having a source connected to the drain of the transistor b, and one end connected to the gate of the transistor 22a, and the drain of the transistor 22a. And a capacitor 23 connected to the other end.
[0033]
The source of the transistor 22a is connected to the drain of the transistor 22b, the gate of the transistor 22b is connected to the signal line 26, the gate of the transistor 22c is connected to the signal line 25, and the source of the transistor 22c is connected. The side is connected to the source signal line 21a, the gate side of the transistor 22d is connected to the signal line 25, and the drain side of the transistor 22d is connected to the gate side of the transistor 22a.
[0034]
A current corresponding to the gradation data 13 is output from the current generator 14. The control unit 12 detects one horizontal scanning period and sets a conduction period of the switch 16 by a clock, a counter, and the like in order to perform voltage application for the first one to three microseconds within one horizontal scanning period and then output a current. Although the switch 17 may be always in the conductive state, it is preferable that the switch 17 be in the non-conductive state during the conductive period of the switch 16. FIG. 11 shows the operation of the switches 16 and 17 within one horizontal scanning period.
[0035]
In order to display the organic light emitting element 24 of each pixel in FIG. 2, the transistors 22c and 22d are turned on by the signal line 25 within one horizontal scanning period, and the source is supplied from the power supply 27 via the transistor 22a and the source signal line 21a. The driver 1 draws the current (I1). At this time, gradation display is performed according to the magnitude of the current amount. Charge corresponding to a gate voltage corresponding to a drain current of the transistor 22a is stored in the capacitor 23.
[0036]
Thereafter, the transistor 22b is turned on by the signal line 26, the transistors 22c and 22d are turned off by the signal line 25, and a current corresponding to the charge of the capacitor 23 flows from the power supply 27 to the organic light emitting element 24 via the transistor 22a.
[0037]
At this time, in order to speed up the change in the value of the current flowing through the organic light emitting element 24, if a voltage corresponding to a predetermined source current value is applied to the source signal line 21a, the gate potential of the transistor 22a is also reduced by the floating capacitance of the source signal line 21a. And the wiring constant. As a result, the transistor 22a changes so that a predetermined current flows to the source signal line 21a.
[0038]
Since the wiring resistance is much smaller than the resistance between the source and the drain of the transistor 22a, the change becomes very fast. It changes in about 1 to 3 μsec.
[0039]
However, a source voltage for flowing a predetermined current value to the source signal line 21a changes due to a variation in current-voltage characteristics of the transistor 22a. Therefore, in order to compensate for a deviation from the predetermined current value, a current source for flowing the predetermined current value is connected to the source signal line 21a, and the current value flowing to the source signal line 21a is changed to the predetermined current value.
[0040]
In order to realize this, each output unit of the source driver 1 is configured as shown in FIG. 1, and first outputs a black voltage to the source signal line 21a, and then outputs a current corresponding to the gradation data 13. .
[0041]
A current generator 14 that generates a current corresponding to the grayscale data 13 is output to 18, and a current corresponding to the grayscale flows through the source signal line 21. On the other hand, in order to apply a black voltage to the source signal line 21, the voltage generator 11 can be output to 18 via the switch 16.
[0042]
In the method of applying a current corresponding to the gray scale after applying a voltage corresponding to the gray scale, a plurality of voltage sources and a plurality of current sources are required, so that the circuit scale is increased.
[0043]
The change in the current value is such that the apparent resistance of the transistor 22a is smaller in the high gradation display than in the low gradation display, so that the waveform change speed becomes faster as the gradation increases. Therefore, a voltage corresponding to black which is difficult to write is applied, and then a predetermined current value is applied to the source signal line to display a predetermined gradation.
[0044]
As described above, the application of the black voltage at the beginning of the horizontal scanning period facilitates the display of the low gray scale. However, in the above operation, in the high gray scale display, once the black display state is established, the high gray scale display is performed. Therefore, there is a possibility that the horizontal scanning period ends before changing to a high gradation. In the case where high gray scale display is performed over two or more horizontal scanning periods (for example, gray scale A and gray scale B are different from gray scale indicating black), when a black voltage is applied, the state of the source signal line is black. → gradation A → black → gradation B On the other hand, when the black voltage is not applied, the state of the source signal line changes from gradation A to gradation B. Compared with black → gradation B, gradation A → gradation B has a smaller change amount and can be changed faster.
[0045]
Therefore, the control of the switch 16 for applying the voltage generator 11 to the output 18 can be changed according to the display gradation. Specifically, no voltage is applied during high gradation display.
[0046]
For this purpose, the gradation data 13 is input to the voltage output control unit 12 that controls the switch 16, and the output of the voltage output control unit 12 can be changed according to the value of the gradation data 13.
[0047]
For example, in the case of performing 64-gradation display (gradation zero is black and gradation 63 is white), when the switch 16 is non-conductive for one horizontal scanning period, the gradation is from gradation 4 to gradation 63. The first predetermined value of the gradation data 13 is 4, and when the gradation becomes 3 or less, 1 to 3 μsec which is an example of the second predetermined period of the present invention including the start time of one horizontal scanning period. The voltage controller 12 is controlled so that the voltage of the voltage generator 11 is output to 18 only. Further, when the first predetermined value is 1 (that is, when the gradation 1 to the gradation 63 are white), only when the gradation is zero, only 1 to 3 μsec including the start time of one horizontal scanning period is included. The voltage output controller 12 is controlled so that the voltage of the voltage generator 11 is output to 18. Then, after the voltage is output, the current output control unit 15 is controlled so that the current corresponding to the gradation data 13 is output from the current generation unit 14 in a period including the end point of one horizontal period.
[0048]
3 to 7 show examples of the configuration of the current generator. Here, as an example, the case where the grayscale data is 4 bits and 16 grayscales will be described.
[0049]
Reference numeral 34 in FIG. 3 denotes a transistor serving as a current source, through which a current flows according to the gate voltage. A switch 33 is connected between the output 18 and the transistor 34. By changing the number of transistors connected to the switch 33 according to the weight of the data bit, a current corresponding to the data is output to 18. One transistor is connected to the least significant bit, two transistors are connected to the next most significant bit, four transistors are connected to the next most significant bit, and eight transistors are connected to the most significant bit. By turning on and off the switch 33 in accordance with the gradation data 13, the number of transistors connected to the output changes in accordance with the gradation data 13, and gradation display is performed.
[0050]
The adjustment of the step width per gradation is performed by changing the variable resistor 36. The transistor 35 and the transistor 34 have a current mirror configuration, and a current according to a mirror ratio with respect to a current flowing through the transistor 35 flows through the transistor 34. When the value of the variable resistor 36 changes, the current flowing through the transistor 35 changes, so that the amount of current increase per gradation can be changed.
[0051]
FIG. 4 similarly performs gradation display by the number of transistors connected to the output, but differs from FIG. 3 in that the voltage of the transistor 34 that determines the step width per gradation is directly controlled by the voltage source 41. It is the point which was made.
[0052]
FIG. 5 shows a configuration in which a constant current circuit is connected in place of the variable resistor 36 in FIG. The current flowing through the transistor 51 is determined by the voltage value of the voltage source 55 and the resistor 53. The method of changing the current value according to the gradation is the same as in FIGS.
[0053]
FIG. 6 shows a gray scale display by changing the current flowing to the output 18 according to the gate voltage of the transistor 63. The gate voltage changes according to the gradation data 13. The gray-scale data 13 is converted into an analog signal by the digital-to-analog converter 61, and this signal is input to the gate voltage of the transistor 63, thereby changing the current.
[0054]
In response to the current output corresponding to the gray scale generated in FIGS. 3 to 6, a black voltage is generated by the voltage generator 11, and the switch 16 is controlled according to the gray scale data 13 and the time of one horizontal scanning period. Thus, the present invention can be realized.
[0055]
3 to 6 are diagrams for explaining the case of one output. When there are a plurality of columns, in order to output the same current at the same gray scale in all the columns, the current flowing through the transistor 34 needs to be equal in all the columns.
[0056]
FIG. 7 shows an improvement of the current generator 14 in the configuration of FIG. 3 in order to output the same current in a plurality of columns. At least one pair of current mirror units is prepared for the current flowing through the variable resistor 72, and the current is distributed to a plurality of systems by the current mirror. If necessary, a current mirror is further configured to distribute current to a plurality of systems. By connecting the gate signal lines of the distributed transistors 75 to the gate signal lines of the transistors 34 in each column, the same current output can be obtained. At this time, by arranging the transistors forming the respective current mirrors having a common gate signal line in close proximity, the current can be distributed with less variation in the mirror ratio. The configuration beyond the gate signal lines of the transistors 75b and 76c is the same as the configuration of the transistor 75a.
[0057]
In the configuration of FIG. 4, the output of the voltage source 41 is supplied to the gate signal line of the transistor 34 in each row. The difference from the configuration in FIG. 3 is that the output current per gray scale can be controlled by changing the gate voltage of the transistor 34 according to the voltage of the voltage source 41.
[0058]
FIG. 13 shows that the same current can be output over a plurality of columns. A common voltage is applied to all the gate signal lines of the transistors 34 in each column, and the voltage can be supplied by the voltage source 41. For example, the transistor 34a is in the first column, the transistor 34b is in the second column, and the transistor 34c is in the third column. According to this method, when the threshold voltage of the transistor 34 varies from transistor to transistor, the output current value differs even if all outputs have the same gradation, and there is a possibility that stripe unevenness occurs for each signal line. However, when the display is made using crystalline silicon, the difference in threshold voltage between adjacent outputs is small, and the threshold voltage changes smoothly in one direction in one chip. Does not have a streak shape, and the luminance changes smoothly from one end to the other end, so that there is no problem in display characteristics. Thus, the current generator 14 can be formed with a simple configuration.
[0059]
FIG. 5 shows that a constant current source is formed by using the operational amplifier 54, the transistor 52, and the resistor 53, and the current flowing from the constant current source flows to the transistor 34 using the current mirrors of the transistors 51 and 34 in accordance with the mirror ratio. The configuration is as described above. The current flowing through the current source is determined by the values of the voltage source 55, the resistor 53, and the power supply 56 connected to the resistor 53.
[0060]
To supply the same current over a plurality of columns, transistors 51 and 52, a resistor 53, an operational amplifier 54, and a voltage source 55 may be used instead of the transistor 71 and the variable resistor 72 having the configuration shown in FIG. Further, the gate signal line of the transistor 51 may be supplied to the transistors 34 in each column without using the transistors 73 to 75 (FIG. 14). Although the transistor 52 is a bipolar transistor, a current source can be similarly formed by using a MOS transistor.
[0061]
As the pixel circuit in the embodiment of the present invention, a pixel circuit having a configuration shown in FIG. 8 is also conceivable. That is, the pixel circuit shown in FIG. 8 includes a display element 84 having one end grounded, a transistor 82a which is an example of a first transistor of the present invention having a drain connected to a power supply, and a display element 84 other than the display element 84. A transistor 82b which is an example of a second transistor of the present invention having its source connected to an end, a transistor 82c which is an example of a third transistor of the present invention having its source connected to a source signal line 81a, and a transistor 82c A transistor 82d which is an example of a fourth transistor of the present invention having a source connected to the drain of the transistor 82d, and a transistor 82e which is an example of a fifth transistor of the present invention having a source connected to the drain of the transistor 82c. And one end of the transistor 82a is connected to the gate side of the transistor 82a. The other end on the emission side is a, a capacitor 83 connected.
[0062]
The source side of the transistor 82a is connected to the drain side of the transistor 82b, the gate side of the transistor 82b is connected to a signal line 87 which is an example of a fifth control line of the present invention, and the gate side of the transistor 82c is The gate side of the transistor 82d is connected to a signal line 86 which is an example of a fourth control line of the present invention, and the drain side of the transistor 82d is connected to a signal line 85 which is an example of a third control line of the present invention. The gate side of the transistor 82a is connected to the gate side of the transistor 82a, the gate side of the transistor 82e is connected to the gate side of the transistor 82a, and the drain side of the transistor 82e is connected to the drain side of the transistor 82a. The pixel circuit having such a configuration can provide the same effect as described above.
[0063]
As described above, according to the driving circuit of the present embodiment, in the current output type semiconductor circuit, the current at the time of the low gradation display is reduced only in the low gradation region where it takes time to change to the predetermined current value. Output a source voltage for a low gray scale display, apply a predetermined current after applying a black voltage during low gray scale display, and change the current to a predetermined value in a short period of time. Now you can change.
[0064]
(Embodiment 2)
The driving circuit according to the second embodiment relates to a driving circuit for color display.
[0065]
As a method of forming a multi-color display using organic light-emitting elements, a method of sequentially arranging elements emitting red, green, and blue light (RGB side-by-side method), a method of combining a white light-emitting element with a color filter, a method of combining a blue light-emitting element and a color conversion layer (CCM) (Proceeding of International Display Works 1997, p581-584, 1997).
[0066]
Regarding the current characteristics with respect to the luminance of the organic light emitting element, the current values for the same luminance are different as shown in FIG. In the method using a color filter, if there is a difference in the transmittance of the color filter for each color, the current value for the same luminance differs for each color. Also in the case of using the CCM, since the color conversion efficiency is different from blue to red and from blue to green, the current value for the same luminance is basically different for each color. Therefore, the light emission start current also differs for each color. In the example of FIG. 10, red, green, and blue are IR, IG, and IB, respectively.
[0067]
Therefore, the second gradation data of the present invention is referred to as red (R) gradation data, the third gradation data of the present invention is referred to as green (G) gradation data, and the fourth gradation data of the present invention is referred to. The data is blue (B). The voltage generated by the voltage generator 81 which is an example of the second voltage generator of the present invention shown in FIG. 9 is a source signal line voltage when a current required for zero gradation flows through the source signal line. The voltage is different for each color. Further, the current generator 132 which is an example of the second current generator of the present invention generates a current according to the red gradation data, and the current generator 132 which is an example of the third current generator of the present invention. 133, a current corresponding to the green gradation data is generated, and the current generator 134, which is an example of the fourth current generator of the present invention, generates a current corresponding to the blue gradation data.
[0068]
Then, different voltages are supplied from the voltage generators 81 to 91, 92 and 93 for each display color. Reference numeral 91 denotes a voltage corresponding to the source potential when the light emission start current of the red (R) light-emitting element flows, which is an example of the second predetermined voltage of the present invention (that is, the voltage corresponds to the zero gradation data of red). The same applies to 92 and 93, which correspond to the source potential at the time when the emission start current of the green (G) light emitting element flows, which is an example of the third predetermined voltage of the present invention. The voltage (that is, the voltage corresponding to the green zero gradation data, hereinafter referred to as VG) is a voltage when the light emission start current of the blue (B) light emitting element, which is an example of the fourth predetermined voltage of the present invention, flows. A voltage corresponding to the source potential (that is, a voltage corresponding to blue zero gradation data, hereinafter referred to as VB) is supplied.
[0069]
As the supplied voltage value, a light emission start current (Idark) is calculated from the current-luminance characteristics of the organic light emitting device as shown in FIG. If the pixel has a current copier configuration as shown in FIG. 2, the current-voltage characteristic of the transistor 22 a that controls the current flowing through the organic light emitting element 24 indicates that the gate voltage of the transistor 22 a when the current flows through the source signal line 21 by Idark. Is calculated, and this gate voltage is generated in the voltage generator 81.
[0070]
That is, if the red gradation data is larger than the second predetermined value, a current corresponding to the red gradation data is output from the current generator 132 for one horizontal period. VR is output from the voltage generation unit 81 for only 1 to 3 μs including the start time of one horizontal scanning period, and then the current according to the red gradation data is output from the current generation unit 132 at the end of one horizontal period. Included and output. When the green gradation data is larger than the third predetermined value, a current corresponding to the green gradation data is output from the current generator 133 for one horizontal period. When the current is smaller than the third predetermined value, VG is output from the voltage generation unit 81 for 1 to 3 μs including the start time of one horizontal scanning period, and then the current according to the green gradation data is output from the current generation unit 133 at the end of one horizontal period. Included and output. When the blue gradation data is larger than the fourth predetermined value, a current corresponding to the blue gradation data is output from the current generator 134 for one horizontal period. VB is output from the voltage generator 81 for 1 to 3 μs including the start time of one horizontal scanning period, and then the current according to the blue gradation data is output from the current generator 134 at the end time of one horizontal period. Included and output.
[0071]
The present invention can be implemented not only in the case of a current copier configuration but also in a case of a current mirror configuration as shown in FIG. The voltage generator 81 may generate the gate voltage when the current Idark flows through the transistor 82a. That is, regardless of the circuit configuration of the pixel, the voltage generator 81 may generate the gate voltage when the transistor that controls the current flowing through the organic light emitting element flows the current Idark.
[0072]
In addition to the configuration in which the voltage value is different for each display color as shown in FIG. 9, the output of the voltage output control unit 12 may be changed for each display color. For example, for each display color, the conduction time of the switch 16 is changed, or the gradation for making the switch 16 conductive is changed. This is because the time required for the current to change to the predetermined current value differs depending on the current value, and the longer the current, the shorter the time required for the change. This is because the voltage of the voltage generator 81 is applied to facilitate low gradation display.
[0073]
In the case where a multi-color display device is formed by the RGB juxtaposition method in the pixel configuration shown in FIG.
[0074]
Depending on the display characteristics of the luminescent color, low gradation display can be performed without necessarily applying a voltage.
[0075]
For example, when a multi-color display device is made of a red light emitting element (R), a green light emitting element (G), and a blue light emitting element (B) having the luminance-current characteristics shown in FIG. It can be seen that the current value must be smaller in the green light emitting element than in the red light emitting element, depending on the color.
[0076]
In a pixel configuration as shown in FIGS. 2 and 8, and in a display device in which a current flowing through an organic light emitting element changes a gate potential by a transistor current to perform gradation display, the lower the current becomes, the more the current flows through the organic light emitting element. The time required for the current flowing through the transistor for controlling the current to change to a predetermined current value increases. In particular, it takes the longest time to change to the lowest current. As a result, the current value flowing in the previous horizontal scanning period cannot be completely changed to a black gradation current value in the horizontal scanning period, and a current indicating a halfway gradation flows, so that black display is difficult.
[0077]
However, when the light emission start current is large, black display is possible even if the current flowing through the transistor is not always zero. In the case of a red light emitting element, the current only needs to be IR or less. Depending on the length of the horizontal scanning period, when performing black display, the current cannot be changed to a current lower than IG, but a current larger than IG and lower than IB may be obtained. At this time, the red and blue pixels can display black, and only the green pixels cannot display black, without applying the voltage generated by the voltage generator 81.
[0078]
Therefore, as shown in FIG. 12, an enable signal 121 may be input to the voltage output control unit 12 for each display color, and whether to apply the voltage of the voltage generation unit 11 may be selected for each display color. . In the display device of the above example, an enable signal is input to the red and blue 121a and 121c, the switch 16 is turned off in all the horizontal scanning periods regardless of the gray scale, and only the gray scale data 121b is generated. The switch 16 may be closed during a part of the horizontal scanning period when 13 indicates zero gradation. This makes it possible to select whether or not to apply a black voltage for each display color.
[0079]
In addition, this method can reduce the number of types of voltages generated by the voltage generation unit 11 when only a required display color is applied, as compared with the configuration of FIG. In the case of applying a black voltage for only one color, the number can be reduced from three to one, and in the case of applying a two-color black voltage, it can be reduced from three to two, and the circuit scale of the power supply unit can be reduced.
[0080]
As described above, according to the driving circuit of the present embodiment, in a current output type semiconductor circuit for color display, only in a low gradation region where it takes time to change to a predetermined current value, a low By outputting a source voltage corresponding to the current at the time of gray scale display, the current can be changed to a predetermined value in a short time by applying a predetermined current after applying the black voltage at the time of low gradation display, and only the current at the time of high gradation display. Can quickly change to a predetermined value.
[0081]
In the description of the present embodiment, it has been described that the second gradation data is red gradation data, the third gradation data is green, and the fourth gradation data is blue. However, the second to fourth gradation data may be data of another color. If the luminance-current characteristics of each color show the same characteristics as those in FIG. Can be.
[0082]
(Embodiment 3)
The driving circuit according to the third embodiment relates to a driving circuit that does not cause a delay in gradation display without applying a black voltage.
[0083]
When the gray level is zero due to the application of the black voltage, the time required to change to a predetermined current value is shortened. However, the time during which the current is changed does not change at the time of halftone display. Therefore, in order to shorten the change time in all the gradations other than the gradation 0, the current value to be output to the output 18 is flowed by a predetermined N times (N> 1) (that is, the organic light emitting element 24 is turned on for one vertical scanning period). N times the current that flows when the display is performed over a period in which one horizontal scanning period is subtracted flows N times), and by increasing the lighting time by 1 / N times the conventional value, a predetermined luminance is obtained. did.
[0084]
FIG. 15 shows a circuit configuration for one pixel corresponding to the configuration of the output section for one column of the source driver 1. In order to allow a current N times the predetermined current value to flow through the source signal line 21, the current flowing to the low current source by the voltage source 55 or the resistor 53 is made N times, and the current flowing to the transistor 51 becomes N times. Thus, the current flowing through the transistor 34 forming the current mirror also becomes N times, so that the current flowing through the source signal line 21 can be made N times. In this way, instead of making the grayscale data 13 N times to flow the N times current, the current flowing per one of the transistors 34 is made N times so that the N times current can be easily supplied to the source signal line. 21 can be output.
[0085]
Next, the output waveform of the gate driver 2 is changed to make the lighting time of the organic light emitting element 24 1 / N times. Paying attention to the pixel 28, the transistor 22b is a switch for selecting whether or not the current of the driving transistor 22a for controlling the current from the power supply flows to the organic light emitting element 24, so that the conduction time of the transistor 22b is reduced to 1 / N times. Then, the lighting time becomes 1 / N times. Therefore, as shown in FIG. 16, the waveform of the gate signal line 26 is changed from FIG. 16A to FIG. 16B, and the conduction period is changed to the period 161 (that is, one vertical scanning period (1 The lighting time was set to 1 / N times by changing from the display time during the frame) to a period of 162 (that is, 1 / N times a period obtained by subtracting one horizontal scanning period from one vertical scanning period).
[0086]
By increasing the current value flowing through the source signal line 21, the current flowing through the transistor 22a that controls the current flowing from the power supply also increases, and the apparent resistance value of the transistor 22a decreases. Thus, when a current is supplied from the power supply through the transistor 22a, the rounding of the waveform due to the stray capacitance 29 of the source signal line 21 and the apparent resistance of the transistor 22a is reduced due to a small time constant. This shortens the time required for the waveform to change to the predetermined current value for all gradations.
[0087]
Note that this method can also be realized by the configurations of FIGS. 3 and 4 other than the configuration of the current generator 14 other than the configuration made by the low current source and the current mirror. This is because an N-fold current output can be realized by changing the gate potential of the transistor 34.
[0088]
In the above description, when the display time of the organic light emitting element 24 is a period obtained by subtracting the first predetermined period in one horizontal scanning period from one vertical scanning period, this period is multiplied by 1 / N ( N> 1), and the flowing current may be N times.
[0089]
The pixel configuration of the display unit can be realized not only with the current copier configuration but also with a current mirror configuration. In FIG. 17, the conduction time of the switch 82b may be controlled by the gate signal line 87 so that the lighting time of the organic light emitting element 84 can be increased by 1 / N.
[0090]
As described above, according to the driving circuit of the present embodiment, in the current output type semiconductor circuit, the voltage generation unit that generates the black voltage even in the low gradation region where it takes time to change to the predetermined current value The current can be changed to the predetermined value in a short period of time without the need for
[0091]
In the above description, the transistors constituting the driving circuit and the display device of the present invention have been illustrated and described as n-type MOS transistors, but may be p-type MOS transistors. FIG. 19 illustrates an example in which the display device illustrated in FIG. 15 is configured using p-type MOS transistors. 20 illustrates an example in which a current mirror type pixel circuit is used as the pixel circuit in the display device illustrated in FIG. Further, FIG. 21 shows a case where the driving circuit shown in FIG. 4 is used, FIG. 22 shows a case where the driving circuit shown in FIG. 3 is used, and FIG. 23 shows a case where the driving circuit shown in FIG. Here is an example.
[0092]
Further, in the above description, the configuration of the current generating unit shown in each drawing has been described by way of example in the case where the grayscale data is 4 bits and 16 grayscales. is there. In that case, this can be realized by preparing a number of transistors and switches corresponding to the bit weights. For example, in the circuit shown in FIG. 6, the number of input bits of the digital / analog conversion unit 61 can be increased or decreased. Just fine.
[0093]
Further, in the above description, it has been described that the current output is performed within one horizontal period when each gradation data is equal to or more than each predetermined value. (Predetermined period). When each gradation data is smaller than each predetermined value, each predetermined voltage output is performed within a second predetermined period (1 to 3 μsec) of the first predetermined period, and thereafter, during a first predetermined period. Current output may be performed until the end of the operation. In that case, the second predetermined period does not include the end point of the first predetermined period. Further, the second predetermined period may not include the start point of the first predetermined period. That is, if the voltage output is performed in an appropriate period within the first predetermined period and the current flowing through the transistor 22a can be changed within the first predetermined period by the current output, the same effect as described above can be obtained. Can be.
[0094]
In the above description, a voltage is output from the start of the first predetermined period, and then the current is output. However, the current may be output simultaneously with the output of the voltage. . Also in this case, if the voltage output is completed by the end of the first predetermined period, the same effect as described above can be obtained.
[0095]
Further, in the above description, each predetermined voltage is described as a voltage corresponding to zero gradation data (that is, a black voltage) in each gradation data, but each predetermined voltage is close to the black voltage. It may be a voltage. In this case, the same effect as described above can be obtained if a voltage is output to the extent that there is no delay in the gradation display of the pixel while the current is being output after the voltage is output.
[0096]
Further, in the above description, each predetermined voltage is described as a voltage corresponding to zero gradation data in each gradation data. However, each predetermined voltage is not equivalent to zero gradation. Alternatively, a voltage corresponding to the lowest gradation data among the gradation data may be used. In that case, the same effect as described above can be obtained.
[0097]
In the above invention, the transistor has been described as a MOS transistor. However, a MIS transistor or a bipolar transistor can be similarly applied.
[0098]
The present invention can be applied to any transistor such as crystalline silicon, low-temperature polysilicon, high-temperature polysilicon, amorphous silicon, and gallium arsenide.
[0099]
Although the description has been given of the organic light-emitting element as the display element, any display element having a proportional relationship between current and luminance, such as an inorganic electroluminescent element and a light-emitting diode, can be used.
[0100]
【The invention's effect】
According to the present invention, it is possible to provide a driving method, a driving circuit, and a display device of a pixel circuit which do not cause a delay in gradation display even at a low gradation.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a current output unit and a voltage output unit according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an example of a pixel configuration of a display device that performs grayscale display according to a current flowing through a source signal line.
FIG. 3 is a diagram illustrating a case where a current generating unit is formed by a current mirror configuration in the configuration of FIG. 1;
FIG. 4 is a diagram in which current can be adjusted by applying a voltage to a gate signal line of a transistor serving as a low current source in the configuration of FIG. 1;
FIG. 5 is a diagram showing a case where a current generating portion is formed by a current mirror configuration in the configuration of FIG. 1, and a current output transistor and a current input of a transistor forming a current mirror are performed by a low current source; It is.
FIG. 6 is a diagram showing a configuration in which a current output corresponding to a gray scale can be output by changing a potential of a gate signal line of a transistor according to a gray scale in the configuration of FIG. 1;
FIG. 7 is a diagram showing a configuration of a current generator when the same current value can be output to a plurality of columns by using the current generator of the configuration of FIG. 3;
FIG. 8 is a diagram illustrating an example of a pixel configuration of a display device that performs gradation display according to a current flowing through a source signal line.
FIG. 9 is a diagram showing a configuration in which a current output corresponding to a gray scale and a black voltage can be applied to a plurality of columns having different display colors.
FIG. 10 is a diagram illustrating an example of a luminance-current characteristic for each display color of the organic light emitting device.
FIG. 11 is a diagram showing timings of current output and voltage output during a certain horizontal scanning period.
FIG. 12 is a diagram in a case where the voltage output of the voltage generating unit is one system in the configuration of FIG. 9;
FIG. 13 is a diagram showing a configuration of a current generator when the same current value can be output to a plurality of columns by using the current generator of the configuration of FIG. 4;
14 is a diagram showing a configuration of a current generating unit when the same current value can be output to a plurality of columns by using the current generating unit having the configuration of FIG. 5;
FIG. 15 is a diagram illustrating a configuration of a pixel having a current copier configuration and a source driver output unit for one column.
FIG. 16 is a diagram showing a gate signal line waveform within one frame in the configuration of FIG. 15;
FIG. 17 is a diagram illustrating a configuration of a pixel having a current mirror configuration and a source driver output unit for one column.
FIG. 18 is a diagram illustrating an operation of the driving circuit according to one embodiment of the present invention.
FIG. 19 is a diagram illustrating an example in which the display device according to one embodiment of the present invention is configured by p-type MOS transistors;
FIG. 20 is a diagram illustrating an example in which the display device according to one embodiment of the present invention is configured by p-type MOS transistors;
FIG. 21 is a diagram illustrating an example in which the drive circuit according to one embodiment of the present invention is configured by p-type MOS transistors;
FIG. 22 is a diagram illustrating an example in which the drive circuit according to one embodiment of the present invention is configured by p-type MOS transistors;
FIG. 23 is a diagram illustrating an example in which the drive circuit according to one embodiment of the present invention is configured by p-type MOS transistors;
FIG. 24 is a diagram illustrating a configuration of a conventional driving circuit.
FIG. 25 is a diagram illustrating a configuration of a conventional display device.
[Explanation of symbols]
1 Source driver
2 Gate driver
11, 81 Voltage generator
12 Voltage output controller
13 Gradation data
14 Current generator
15 Current output controller
16, 17 switch
18 Output signal line
21a Source signal line
22a-e transistor
23 Capacitor
24 Organic light emitting device
25, 26 signal line

Claims (14)

In a driving method of driving a pixel circuit that performs gradation display by a current amount with a current output,
When the first gradation data is equal to or greater than a first predetermined value, the current output is performed for a first predetermined period within one horizontal period,
When the first gradation data is smaller than the first predetermined value, the first output is replaced with the current output or simultaneously with the current output within the second predetermined period of the first predetermined period. A driving method for outputting a predetermined voltage. In a driving circuit that drives a pixel circuit that performs gradation display by a current amount by using a current output,
A first voltage generator that generates a first predetermined voltage;
A first current generation unit that generates a current according to the first gradation data,
When the first grayscale data is equal to or more than a first predetermined value, the current is output from the first current generation unit for a first predetermined period within one horizontal period,
When the first grayscale data is smaller than the first predetermined value, the first predetermined voltage is supplied from the first voltage generation unit within a second predetermined period of the first predetermined period. A driving circuit for outputting the first predetermined voltage instead of or simultaneously with the current output. In a driving circuit that drives a pixel circuit that performs gradation display by a current amount by using a current output,
A second voltage generator that generates at least one of a second predetermined voltage, a third predetermined voltage, and a fourth predetermined voltage;
A second current generator that generates a current according to the second grayscale data;
A third current generator that generates a current according to the third grayscale data;
A fourth current generation unit that generates a current according to the fourth grayscale data.
If the second grayscale data is equal to or greater than a second predetermined value, a current corresponding to the second grayscale data is output from the second current generator for a first predetermined period within one horizontal period. ,
When the third grayscale data is equal to or greater than a third predetermined value, a current corresponding to the third grayscale data is output from the third current generator for a first predetermined period in one horizontal period. ,
If the fourth grayscale data is equal to or greater than a fourth predetermined value, a current corresponding to the fourth grayscale data is output from the fourth current generator for a first predetermined period within one horizontal period. ,
When the second gradation data is smaller than the second predetermined value, the second predetermined voltage is applied to the second current output within a second predetermined period of the first predetermined period. Alternatively or simultaneously with the output of the second current, the second predetermined voltage is output,
When the third gradation data is smaller than the third predetermined value, the third predetermined voltage is applied to the third current output within a second predetermined period of the first predetermined period. Alternatively or simultaneously with the third current output, the second predetermined voltage is output,
When the fourth gradation data is smaller than the fourth predetermined value, the fourth predetermined voltage is applied to the fourth current output within a second predetermined period of the first predetermined period. A driving circuit that outputs the second predetermined voltage instead or simultaneously with the fourth current output. The driving circuit according to claim 2, wherein the first predetermined voltage is a voltage corresponding to the lowest first gradation data among the first gradation data. The driving circuit according to claim 4, wherein the first predetermined voltage is a voltage corresponding to zero gradation data of the first gradation data. The second predetermined voltage is a voltage corresponding to the lowest second gradation data among the second gradation data,
The third predetermined voltage is a voltage corresponding to the lowest third gradation data among the third gradation data,
4. The driving circuit according to claim 3, wherein the fourth predetermined voltage is a voltage corresponding to the lowest fourth gradation data among the fourth gradation data. 5. The driving circuit according to any one of claims 2 to 6, wherein the second predetermined period does not include an end point of the first predetermined period. The driving circuit according to any one of claims 2 to 7, wherein the second predetermined period includes a start point of the first predetermined period. A first switch connected between an output side of the voltage generation unit and a source signal line of the pixel circuit;
Grayscale data is input, and a voltage output control unit that controls the operation of the first switch according to the grayscale data;
A second switch connected between an output side of the current generation unit and a source signal line of the pixel circuit;
The driving circuit according to claim 2, further comprising: a current output control unit that controls an operation of the second switch. In a driving circuit that drives a pixel circuit that performs gradation display by a current amount by using a current output,
A current generator that generates a current corresponding to the grayscale data;
The display time of a display element used in a pixel circuit during one vertical scanning period is 1 / N times (N> 1) a period obtained by subtracting a first predetermined period within one horizontal scanning period from one vertical scanning period. And
The current output from the current generator is N compared to the current flowing when the display element is displayed over a period obtained by subtracting a first predetermined period within one vertical scanning period from one vertical scanning period. Driving circuit that is double. The driving circuit according to claim 2, wherein the first predetermined period is one horizontal scanning period. A source driver comprising the driving circuit according to claim 2,
A source signal line connected to the source driver,
A gate driver for outputting a first control signal and a second control signal;
A first control line connected to the gate driver, to which the first control signal is transmitted;
A second control line connected to the gate driver and to which the second control signal is transmitted;
A plurality of pixel circuits corresponding to the pixels, and a display device,
The pixel circuit includes:
A display element having one end grounded;
A first transistor having a drain connected to the power supply;
A second transistor having a source connected to the other end of the display element;
A third transistor having a drain connected to a drain of the second transistor;
A fourth transistor having a source connected to a drain of the second transistor;
A capacitor having one end connected to the gate side of the first transistor and the other end connected to the drain side of the first transistor;
A source side of the first transistor is connected to a drain side of the second transistor;
A gate side of the second transistor is connected to the second control line;
A gate side of the third transistor is connected to the first control line;
A source side of the third transistor is connected to the source signal line,
A gate side of the fourth transistor is connected to the first control line;
The display device, wherein a drain side of the fourth transistor is connected to a gate side of the first transistor. A source driver comprising the driving circuit according to claim 2,
A source signal line connected to the source driver,
A gate driver for outputting a third control signal, a fourth control signal, and a fifth control signal;
A third control line connected to the gate driver, to which the third control signal is transmitted;
A fourth control line connected to the gate driver, to which the fourth control signal is transmitted;
A fifth control line connected to the gate driver, to which the fifth control signal is transmitted;
A plurality of pixel circuits corresponding to the pixels, and a display device,
The pixel circuit includes:
A display element having one end grounded;
A first transistor having a drain connected to the power supply;
A second transistor having a source connected to the other end of the display element;
A third transistor having a source connected to the source signal line;
A fourth transistor having a source connected to a drain of the third transistor;
A fifth transistor having a source connected to the drain of the third transistor;
A capacitor having one end connected to the gate side of the first transistor and the other end connected to the drain side of the first transistor;
A source side of the first transistor is connected to a drain side of the second transistor;
The gate side of the second transistor is connected to the fifth control line,
A gate side of the third transistor is connected to the third control line;
A gate side of the fourth transistor is connected to the fourth control line,
A drain side of the fourth transistor is connected to a gate side of the first transistor;
A gate side of the fifth transistor is connected to a gate side of the first transistor;
The display device, wherein a drain side of the fifth transistor is connected to a drain side of the first transistor. 14. The display device according to claim 12, wherein the display element is an organic light emitting element.

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