JP4316915B2 - Image display apparatus and driving method thereof - Google Patents

Description

[0001]
The present invention relates to an image display device, and more particularly to a high-quality image display device suitable for an organic electroluminescence (EL) display device and a driving method thereof.
[0002]
[Prior art]
In recent years, displays configured by arranging light emitting elements in a matrix have been developed. As a light emitting element used in such a display, for example, there is an organic EL element using an organic material as a light emitting layer. An organic EL element basically includes a cathode electrode, an anode electrode, and a light emitting layer composed of at least one organic material sandwiched between the electrodes. Further, a simple matrix method is known as a display driving method using this organic EL element.
[0003]
In this simple matrix system, an organic EL element is arranged at each intersection of data electrodes D1-Dm and scan electrodes S1 to Sm arranged in a matrix, and the cathode of this element is connected to the scan electrode and the anode is connected to the data electrode. . Then, the scanning electrodes are scanned and driven at regular time intervals, and the data electrodes are driven in synchronization with the scanning electrodes to selectively emit any organic EL element. At this time, the driving period of the scanning electrode is set to be longer than the period in which the human eye can distinguish blinking. This makes it possible to recognize as if the organic EL elements at each intersection are continuously emitting light, and display an image. The luminance of the image at this time is obtained by averaging the light emitted from the organic EL element during scanning driving. Therefore, the light emission luminance of the normal matrix display device is less than or equal to the value obtained by dividing the light emission luminance during driving by the number of scanning electrodes.
[0004]
Conventionally, it has been known that when such a simple matrix drive is performed, the voltage applied to the element to be turned on by the capacitance component of the organic EL element does not rise at high speed. The driving method disclosed in Japanese Patent Publication No. Hokukai is proposed. This is to solve the above-mentioned problems by discharging the charge accumulated in the capacitive component by connecting the cathode and anode of the element to the same reset voltage at fixed time intervals when the scan electrode is driven to scan. .
[0005]
However, it has been found that such a drive system has the following problems. This problem will be described with reference to FIGS. The entire flow is such that the discharge operation is secondly performed from the state in which the scan electrode S3 is scan-driven, and the scan drive of the scan electrode S1 is thirdly performed.
[0006]
FIG. 2 is a schematic diagram showing a first state when a 3 × 4 dot region of a display panel which is one form of the image display device is driven by simple matrix driving. The organic EL elements to be driven are represented by diode symbols, and the other organic EL elements are represented by capacitor symbols. Further, in the vicinity of each element, the voltage across the both ends is shown. In this first state, the scanning electrode S3 is selected, and all data lines are driven. The potentials of both electrodes of each organic EL element at this time are indicated by Vf, Vc and 0 in the figure. Here, 0 is a GND potential, Vc is a power supply voltage supplied to the panel, and Vf is a voltage necessary for causing the organic EL element to emit light with a desired instantaneous luminance. This Vf potential is determined from If flowing from a constant current source that drives the data line, and IV characteristics of the organic EL element. In this state, the organic EL element connected to the selected scan electrode S3 emits light by applying a voltage Vf in the forward direction. On the other hand, a reverse bias voltage is applied to the organic EL elements connected to the other scanning lines, and the voltage is Vc−Vf.
[0007]
Next, the discharge operation in the second state shown in FIG. 3 is performed for a predetermined reset period. In this example, the GND potential is used as the reset voltage, and the scan electrodes and the data electrodes are all connected to the GND potential. By this reset operation, the charges accumulated in the organic EL element connected to the scan electrode S3 scanned immediately before and the organic EL elements connected to other scan electrodes are discharged.
[0008]
The time required for this reset is
(Amount of charge accumulated in all organic EL elements) / (Current value that can be supplied by a switch for selecting a potential)
Determined by Here, the switch element for selecting the potential is usually composed of a transistor such as a bipolar transistor or an FET, and such a transistor is economical. Many of the commonly used transistors have IV characteristics as shown in FIG. In this case, the amount of current that can be passed by the switch needs to be able to realize 16 gradations even using the saturation current Ic in the figure.
[0009]
Next, as shown in FIGS. 4 and 5, driving in the next scanning period is performed as the third state. Here, a case where the number of driven elements is extremely large and a small number is considered. Here, FIG. 4 shows the case where the driven element is dominant among the organic EL elements connected to the selected scanning line, and FIG. 5 shows the case where the non-driven element is dominant.
[0010]
First, the case shown in FIG. 4 will be described. After the reset period is finished, the scan electrode of S1 is selected, and the other scan electrodes are connected to Vc, and at the same time, most of the data lines are connected to a constant current source for driving the organic EL element. At this time, the element in which the accumulated charge becomes 0 in the reset period starts to be charged, and the direction of the charging current changes from the scanning electrode to the parasitic capacitance of the EL element to the data electrode as indicated by an arrow in the figure.
[0011]
Here, since the end of the data electrode is connected to the constant current source by the switch, the direction of the charging current of the data electrode is opposite to the polarity of the data electrode, and eventually the organic EL element connected to the selected scan electrode Through to GND. The total sum of impedances of the selected organic EL elements at this time is usually sufficiently higher than the total sum of impedances of the switch elements connected to the non-selected scan electrodes, due to its IV characteristics and pixel size. Therefore, all the electrodes once approach the Vc potential, and the data electrodes decrease to Vf as charging progresses. This potential change with time is expressed as overshoot Os shown in D1 (a) of FIG.
[0012]
When this overshoot occurs, the current flowing into the selected organic EL element increases. For this reason, the instantaneous luminance is equal to or higher than the set value, and is recognized brighter than the preset luminance. The degree to which this instantaneous luminance is larger than the set value is determined by the sum of the impedance of the selection switch connecting the data line to GND, the sum of the impedance of the selection switch connected to the non-selected scan electrode, and the selection EL. It is determined by the sum of the impedance and parasitic capacitance of the element. That is, it changes depending on the number of selected organic EL elements. Note that the sum of the impedances of the selected organic EL elements is determined by the IV characteristics and the pixel size (area).
[0013]
Next, the case of FIG. 5 will be described. After the reset period ends, the scan electrode of S1 is selected, and the other scan electrodes are connected to Vc, and at the same time, a part of the data line is connected to a constant current source for driving the organic EL element. At this time, the element in which the accumulated charge becomes 0 in the reset period starts to be charged, and the direction of the charging current changes from the scanning electrode to the parasitic capacitance of the EL element to the data electrode as indicated by an arrow in the figure. Here, since the end of the data electrode is connected to the GND potential by the switch, the current flows into the GND.
[0014]
At this time, if the sum of the impedances of the data electrode side switch elements connecting the data electrodes to GND is sufficiently lower than the sum of the impedances of the scan electrode side switch elements connected to the non-selected scan electrodes, The scan electrode once approaches the GND potential, and the voltage of the non-selected scan electrode rises to Vc as charging progresses. This potential change with time is expressed as an undershoot Us shown in D1 (a) of FIG.
[0015]
If this undershoot occurs, If flowing from the constant current source connected to the selected data electrode is also consumed for charging the parasitic capacitance of other non-selected organic EL elements, a loss occurs and instantaneous luminance Becomes less than the set value and is recognized darker than the set value. To the extent that this instantaneous luminance is smaller than the set value, the sum of the impedance of the selection switch connecting the data line to GND, the sum of the impedance of the selection switch connected to the scan electrode in the non-selected state, and non-selection It is determined by the sum of the impedance and parasitic capacitance of the EL element. That is, it varies depending on the number of organic EL elements that are not selected.
[0016]
As described above, when the driving method disclosed in Japanese Patent Application Laid-Open No. 9-232074 is used, overshoot or undershoot occurs, and an error occurs with respect to desired light emission luminance. This phenomenon causes significant image quality degradation. Further, this overshoot or undershoot is determined to be overshoot or undershoot depending on the number of organic EL elements selected after the reset period, and the magnitude of the error changes.
[0017]
By the way, Japanese Patent Laid-Open No. 2000-66639 (hereinafter referred to as Patent Document 2) describes all the scanning lines in a reset period from the end of a scanning period for scanning an arbitrary scanning line to the start of scanning of the next scanning line. Describes a driving method in which a first reset voltage is applied and a second reset voltage higher than the first reset voltage is applied to all the drive lines. However, in the embodiments of these documents, no reset period is provided immediately before the preset period. In the case of such driving, the discharge of the parasitic capacitance of the organic EL element charged with the reverse bias is also performed via the transistor Ic having the scanning electrode connected to Vc. For this reason, if the preset is finished at a desired time, Ic of the transistor must be made sufficiently large, which is uneconomical.
[0018]
Japanese Patent Laying-Open No. 2000-305521 (hereinafter, Patent Document 3) discloses that light can be emitted to a second light emitting element provided on a second negative electrode next to a first light emitting element provided on a first negative electrode. In the display device driving method, the electric current accumulated in the light emitting element is removed for a predetermined period when the electric current is applied, and then the electric current is supplied to the second light emitting element. The luminance of the second light emitting element when there is little or no charge accumulation is assumed to be Le, and the emission luminance Lp satisfying the relationship of Lp = A × Le (A is 0.9 to 0.95). A driving method of a display device is described in which the discharge period Rt is set so as to satisfy the relationship of Tx <Rt, where Tx is a corresponding discharge period and Rt is a discharge period that is actually discharged. .
[0019]
In the embodiment disclosed in Patent Document 3, the reset time of the above-mentioned Japanese Patent Laid-Open No. 9-232074 is defined in the range of luminance and rise time.
[0020]
In Japanese Patent Application Laid-Open No. 2001-236039 (hereinafter referred to as Patent Document 4), a scan selection pulse is sequentially applied to a plurality of scan electrodes and a desired constant current pulse is applied to the plurality of data electrodes in synchronization with the scan selection pulse. In the period in which each organic EL element emits light with a desired luminance by supplying and the scan selection pulse is switched to the next scan electrode, all the data electrodes are connected to a time constant circuit having a predetermined time constant, and the data A driving method of an organic EL display characterized by discharging electric charges accumulated in electrodes is described. That is, a time constant circuit is provided outside the data electrode and the selection switch, and presetting is performed using this time constant circuit. However, this document does not combine reset and preset. For this reason, if the preset is finished at a desired time, Ic of the transistor must be made sufficiently large, which is uneconomical.
[0021]
Japanese Patent Application Laid-Open No. 8-305318 (hereinafter referred to as Patent Document 5) discloses a method of precharging to a reference voltage before data writing. This is done at all data electrodes. In this case, the organic EL element connected to the next selected scanning line is once charged to a reverse bias and discharged to 0 potential or reverse charged to Vf during the scanning period. This is undesirable because it results in increased power consumption. In addition, the function of selecting the potential of the scan electrode has three states, which makes the device expensive and uneconomical.
[0022]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 9-232074
[Patent Document 2]
JP 2000-66639 A
[Patent Document 3]
JP 2000-305521 A
[Patent Document 4]
JP 2001-236039 A
[Patent Document 5]
JP-A-8-305318
[0023]
[Problems to be solved by the invention]
An object of the present invention is to realize an image display device and a driving method thereof in which the overshoot and undershoot caused by the change in the number of selected elements are reduced and the displayed image quality is improved.
[0024]
[Means for Solving the Problems]
  In order to achieve the above object,In the lightIs configured as follows.
  (1) A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by current at intersections thereof, and a first potential at which the scan electrodes are at least selected and a second at which the scan electrodes are not selected A scan electrode side switch connected to any one of the potentials, a constant current source for supplying at least a predetermined constant current to the data electrodes, and a data electrode side switch connected to any one of the first potentials which are inoperative. And having
  An image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scan electrodes,
  When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
  Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided.,
  The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
  By adjusting the time width of the preset time depending on the temperature, the overshoot or undershoot is within 10%.Image display device.
  (2)A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; at least a first potential for selecting the scan electrode and a second potential for selecting the scan electrode; A scan electrode side switch connected to any one of the data electrodes; a constant current source supplying at least a predetermined constant current to the data electrode; and a data electrode side switch connected to any one of the first potential to be in an inoperative state. With
  An image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scan electrodes,
  When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
  Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
  The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
  The time width of the preset time is adjusted according to the number of thin film display elements to be selectively driven next.The overshoot or undershoot within 10%Image display device.
  (3A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; a first potential at which the scan electrode is at least selected; and a second potential at which the scan electrode is not selected. A scan electrode side switch connected to any one of the above, a constant current source that supplies at least a predetermined constant current to the data electrode, and a data electrode side switch connected to any one of the first potential to be inoperative. And having
  A driving method of an image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scanning electrodes,
  When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
  Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
  The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
  By adjusting the time width of the preset time depending on the temperature, the overshoot or undershoot is within 10%.Driving method of image display apparatus.
  (4) A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by current at intersections thereof, and a first potential at which the scan electrodes are at least selected and a second at which the scan electrodes are not selected. A scan electrode side switch connected to any one of the potentials, a constant current source for supplying at least a predetermined constant current to the data electrodes, and a data electrode side switch connected to any one of the first potentials which are inoperative. And having
  A driving method of an image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scanning electrodes,
  When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
  Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
  The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
  A method for driving an image display apparatus, wherein an overshoot or undershoot is made within 10% by adjusting a time width of the preset time according to the number of thin film display elements to be selectively driven next.
[0025]
As described above, some of the prior arts that define the reset period and the preset period are also found, but the techniques disclosed in these documents are different from the present invention as follows.
[0026]
JP 2000-66639 A (hereinafter referred to as Patent Document 2)
In the embodiment of Patent Document 2, no reset period is provided immediately before the preset period. In the case of such driving, the discharge of the parasitic capacitance of the organic EL element charged with the reverse bias is also performed via the transistor Ic having the scanning electrode connected to Vc. For this reason, if the preset is finished at a desired time, Ic of the transistor must be made sufficiently large, which is uneconomical.
[0027]
On the other hand, in the invention of this application, a reset period is once provided, and the scan electrode is discharged through the transistor Ic connected to the GND, and then the scan electrode is connected through the transistor Ic connected to the Vc. The transistor Ic having the scan electrode connected to GND is designed to be sufficiently large so that all IF flowing through the organic EL element connected during the scan selection period can flow. By using this for the discharge in the reset period, a high-speed discharge is performed, and the preset in a sufficiently short time is economical even if it is performed through the transistor Ic having the scan electrode connected to Vc in the subsequent preset period. Can be done. Further, since the preset itself uses the Vc potential, it is not necessary to prepare a new power source and can be easily implemented.
[0028]
JP 2000-305521 A (hereinafter referred to as Patent Document 3)
In the embodiment disclosed in Patent Document 3, the reset time of the above-mentioned Japanese Patent Laid-Open No. 9-232074 is defined in the range of luminance and rise time. On the other hand, the invention of this application aims to improve the image quality using the reset time and the subsequent preset time, and the means are different. In the invention of this application, the determination of the reset time does not necessarily require measurement of luminance and rise time.
[0029]
Japanese Patent Laid-Open No. 2001-236039 (hereinafter referred to as Patent Document 4)
In Patent Document 4, a time constant circuit is provided outside the data electrode and the selection switch, and presetting is performed using this time constant circuit. On the other hand, in the present application, presetting is performed based on the parasitic capacitance of the organic EL element and the drive current amount of the selection switch. Therefore, the publicly known example and the present application are completely different configurations. In the invention of this application, presetting is performed after a reset period is provided, but this is not performed in Patent Document 4. The usefulness of performing after preset after reset is as follows.
[0030]
JP-A-8-305318 (hereinafter referred to as Patent Document 5)
In this document, a method of precharging to a reference voltage before data writing is disclosed. This is done at all data electrodes. In this case, the organic EL element connected to the next selected scanning line is once charged to a reverse bias and discharged to 0 potential or reverse charged to Vf during the scanning period. This is undesirable because it results in increased power consumption. In addition, the function of selecting the potential of the scan electrode has three states, which makes the device expensive and uneconomical.
[0031]
On the other hand, in the invention of this application, precharge is performed by connecting the scanning line selected next time and the other scanning lines to different potentials. The reason why the problem is solved by performing such driving is that the display device performs matrix driving using a thin-film light emitting display element such as an organic EL element. On the other hand, since Patent Document 5 mainly relates to a field emission device display device, there is no disclosure about selectively changing the potential of the row voltage source during precharging. In addition, no study has been made on how much the amount of overshoot and undershoot can be suppressed to realize a satisfactory image quality.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
The image display device of the present invention has a plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by current at the intersection, and the scan electrode is at least selected with a first potential that is in a selected state. Connected to one of the scan electrode side switch connected to one of the second potentials to be in a state, the constant current source for supplying at least a predetermined constant current to the data electrode, and the first potential to be in an inoperative state And an image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scanning electrodes. When a display signal is supplied to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance, and then a scan electrode selected during the next scan period The first potential is obtained by providing all data simultaneously electrodes Connecting other scanning electrode to a second potential preset period connected to the first potential.
[0033]
Thus, in passive driving of a simple matrix device having a reset period, the scan electrode selected during the next scan period is set to the first potential to be selected before the next data write, and the other scan electrodes are not selected. By providing a preset period in which all the data electrodes are connected to the first potential at the same time as the connection to the second potential, the overshoot and undershoot that occur in the data electrode drive signal can be effectively suppressed.
[0034]
Next, a display device and a driving method thereof according to the present invention will be described with reference to the drawings.
[0035]
FIG. 2 is a schematic diagram showing a first state when a 3 × 4 dot region of a display panel which is one form of the image display device is driven by simple matrix driving. 2 and 3 are the same as those described in the above prior art, so the description will be simplified. In the first state, it is a scanning period in which the electrode S3 is selected, and all the data lines are driven. The potentials of both electrodes of each organic EL element at this time are indicated by Vf, Vc and 0 in the figure. In this state, the organic EL element connected to the selected scan electrode S3 emits light by applying a voltage Vf in the forward direction. On the other hand, a reverse bias voltage is applied to the organic EL elements connected to the other scan electrodes, and the voltage is Vc−Vf.
[0036]
Next, the discharge operation in the second state shown in FIG. 3 is performed for a predetermined reset period. In this example, the GND potential is used as the reset voltage, and the scan electrodes and the data electrodes are all connected to the GND potential. By this reset operation, the charges accumulated in the organic EL element connected to the scan electrode S3 scanned immediately before and the organic EL elements connected to other scan electrodes are discharged.
[0037]
The time required for this reset is
(Amount of charge accumulated in all organic EL elements) / (Current value that can be supplied by a switch for selecting a potential)
Determined by
[0038]
Next, as shown in FIG. 6, a preset operation is performed. In this example, the scanning electrode S1 selected during the next scanning period is connected to a first potential that is selected, that is, GND, and the other scanning electrode S2-3 is connected to a second potential Vc that is to be in a non-selected state. At the same time, all the data electrodes D1-D4 are connected to the first potential, that is, GND. At this time, the organic EL elements EL (1,1) to EL (1,4) connected to the scan electrodes to be selected remain at the GND potential, but are connected to the other non-selected scan electrodes. A charging current flows through the EL element, and attempts to be charged until the voltage reaches Vc. The voltage across the element is Vc on the scanning electrode side and Vc−V ′ on the data electrode side.
[0039]
Here, the voltage V ′ is a voltage accumulated in the organic EL element by the preset, and the controlled current (Ic) determined by the parasitic capacitance C of the organic EL element and the characteristics of the switch element (transistor) that connects the scanning electrode to Vc. And a preset time Tpre. That is,
V ′ = Ic × Tpre / C
It is expressed.
[0040]
Next, as shown in FIGS. 7 and 8, the driving in the next scanning period is performed as the third state. Here, in order to make it easy to understand the occurrence of overshoot and undershoot and their suppression mechanism, a case where the number of driven elements is extremely large and a case where there are few elements will be described. Here, FIG. 7 shows the case where the driven element is dominant among the organic EL elements connected to the selected scanning line, and FIG. 8 shows the case where the non-driven element is dominant. And most cases of the drive state correspond to these, or it can be grasped as an intermediate state between them. In other words, these illustrated cases are conditions that maximize overshoot and undershoot. Overshoot and undershoot decrease with the transition to the intermediate state, and vice versa. Migrate to Therefore, it can be seen that it is sufficient to confirm that overshoot and undershoot can be suppressed in these extreme cases.
[0041]
First, as shown in FIG. 7, when a large number of organic EL elements are selected, a preset operation is performed to reduce the amount of charge flowing into the organic EL elements connected to the selected scan electrode. . That is, the parasitic capacitance of the organic EL element connected to the non-selected scanning line is already charged to the potential of V ′. For this reason, almost no charging current flows at the time of data writing, and almost no current flows into GND via the organic EL element. Accordingly, as shown in D1 (b) of FIG. 1, the overshoot Os can be suppressed small by providing the preset period. At this time, if Vc−V ′ <Vf, the overshoot can be made zero.
[0042]
Next, as shown in FIG. 8, when there are a large number of unselected organic EL elements, the total charge amount of If flowing into the unselected scan electrodes is reduced by performing the preset operation. That is, the parasitic capacitance of the organic EL element connected to the non-selected scanning line is already charged to the potential of V ′. For this reason, the current If flowing through the write data electrode D1 hardly flows except for the selection element (1, 1). Therefore, as shown in D1 (b) of FIG. 1, the undershoot Us can be reduced by providing the preset period. At this time, if V ′> Vf, the undershoot becomes 0 (zero).
[0043]
As described above, it can be understood that it is desirable to set V '= Vf = 1/2 Vc in order to minimize overshoot and undershoot. However, an overshoot and undershoot of ± 10% or less are sufficient to realize a panel with 16 gradations. Further, if the preset period is lengthened in order to suppress overshoot and undershoot, there is a problem that the substantial light emission luminance is reduced. For this reason, it is desirable to keep the element driving time as long as possible while keeping the overshoot and undershoot within the allowable range.
[0044]
Here, the overshoot / undershoot is expressed as a time integral value in the time transition of the fluctuating voltage caused by the overshoot and the undershoot. Further, when this integral value is a ratio to the ideal drive voltage Vf × scanning time, The ratio of shoot / undershoot can be expressed and can be quantitatively grasped.
[0045]
As described above, in order to suppress overshoot and undershoot to the maximum, it is desirable that V '= Vf = 1/2 Vc, but it has been found that it is acceptable up to ± 10%. However, the characteristics of the organic EL element change depending on the temperature. For example, in the case of a general element, the temperature coefficient is about −0.06 / ° C. That is, Vf that causes the organic EL element to emit light decreases as the temperature increases, and increases as the temperature decreases.
[0046]
On the other hand, in an image display device generally composed of organic EL elements, a constant current source regulates a power supply voltage supplied from the outside and outputs a constant current. By using the regulator in this way, the device can be manufactured at low cost, which is economical. Examples of the constant current regulator include constant current elements, FETs, constant current circuits that combine transistors, and the like. A typical example can be realized by a current mirror circuit.
[0047]
However, when the ambient temperature of the display device using the regulated constant current source increases, Vf decreases due to the above-described temperature coefficient. This voltage fluctuation will be absorbed by the constant current source, which means that the power loss in the constant current source will increase, and if that loss exceeds the allowable loss of the constant current source, finally the constant current source Lead to destruction. Here, since the permissible loss of the constant current source itself decreases as the ambient temperature increases, the range of the permissible operating temperature significantly decreases. On the other hand, when the ambient temperature of the display device decreases, Vf increases, so that constant current operation becomes impossible when Vf higher than the input power supply voltage is required, and the luminance is kept constant. I can't keep it. For these reasons, the allowable operating temperature range of the display device is narrowed to a range that is the value of the temperature coefficient of the organic EL element, the allowable loss of the constant current source, and the input power supply voltage.
[0048]
This problem can be solved by measuring the ambient temperature of the display device and adjusting the value of the power supply voltage according to the value. Further, the temperature coefficient of the regulator may be as close as possible to the temperature coefficient of the element. Specifically, it should be as close as possible to be within the safe operation area (ASO). The ambient temperature can be measured easily with a thermistor, a temperature measuring element using platinum or the like, a thermocouple, etc., and these are connected to the control element and control circuit according to a known control technique. And use it.
[0049]
However, when this drive circuit and drive method are applied, Vc and Vf differ depending on the ambient temperature, so that overshoot and undershoot may be larger than the prescribed values. Accordingly, the preset time is adjusted according to the ambient temperature, and this makes it possible to realize an image display device that maintains a constant image quality even when used in a wide temperature range.
[0050]
Of course, the function for detecting the temperature does not have to be the same device as the function for controlling scanning, and may be attached to the power supply, both driver ICs, the organic panel, or the like, or may be an independent device.
[0051]
As described above, it was found that by adjusting the preset time according to the ambient temperature, uniform image quality can be maintained in a wide temperature range. By the way, by controlling the preset time in consideration of the number of elements to be driven, a higher quality image can be obtained.
[0052]
As described above, the amount of undershoot and overshoot depends on the number of data electrodes selected in the next scanning period. Therefore, by counting the number of data electrodes selected in the next scanning period and controlling the preset time according to the number, it is possible to realize an image display device with higher image quality.
[0053]
Specifically, the change of the preset period by the selected data line may be controlled so that the overshoot / undershoot is within the above range and good image quality is obtained. As one method, control is performed so that the driving time / number of selected data electrodes is as close as possible to a predetermined value obtained in advance. This “constant value” can be obtained experimentally in advance or by calculating each parameter in the circuit. Usually, if the element controls the scanning electrode and the data electrode, the number of data electrodes selected in the next scanning period can be detected in advance, so that the control becomes easy. Of course, the function of counting the number of data electrodes selected in the next scanning period does not need to be the same device as the function of controlling scanning, and can be provided in the power supply, both driver ICs, and the organic panel. However, it may be an independent device.
[0054]
Note that the present invention is not limited to organic EL elements, and can be applied to all thin film light-emitting elements that are driven by a current and have parasitic capacitance as in the organic EL elements.
[0055]
For example, as shown in FIG. 10, the display device of the present invention has a main control unit 104 that provides data to be displayed on a display and data related to display, and an organic EL according to display data provided from the main control unit 104. It has a display control control unit 105 for sending a scan electrode drive signal and a data electrode drive signal which are signals for driving the scan electrode and data electrode of the display. Further, connected to the display control control unit 105, data for expanding display data given from the main control unit 104 or the like into matrix data, bitmap data, etc., data of predetermined display contents, and the like are stored. The display data storage unit 106, and the scan electrode drive signal and data electrode drive signal from the display control control unit 105, the scan electrode drive unit 102 for driving the scan electrode and data electrode of the organic EL panel (organic EL display main body) 101, And a data electrode driver 103.
[0056]
The main control unit 104 gives display data to be displayed on the organic EL display 101, designates display data stored in the display data storage unit 106, and gives timing and control data necessary for display. The main control unit 104 can usually be configured by a general-purpose microprocessor (MPU) and a control algorithm on a storage medium (ROM, RAM, etc.) connected to the MPU. The main control unit 104 can be used regardless of the mode of the processor such as CISC, RISC, and DSP, and may be configured by a combination of other logic circuits such as ASIC. In this example, the main control unit 104 is provided independently. However, the main control unit 104 may be integrated with the display control control unit 105, a control unit of a device equipped with a display, or the like.
[0057]
The display control control unit 105 analyzes display data or the like given from the main control unit 104 or the like, searches for data stored in the display data storage unit 106 if necessary, and stores the display data on a predetermined organic EL display. Is converted into matrix data for display at the position. That is, when the image (image or character) data to be displayed is dot data in pixel units of an organic EL element given at the intersection of each matrix, a signal for driving the scanning electrode and data electrode giving the dot coordinates is given. appear. Further, driving in units of frames as described above, driving ratio (duty) control of the scanning electrodes and data electrodes, and the like are also performed.
[0058]
The display control control unit 105 includes, for example, a processor or a composite logic circuit having a predetermined arithmetic function, a buffer for the processor to exchange data with an external main control unit, a timing signal to the control circuit, a display Timing signal generation circuit (oscillation circuit) that gives timing signals and reading to external storage means, write timing signals, etc., storage element control circuit for sending and receiving display data from external storage means, reading from external storage elements, etc. , A drive signal sending circuit for sending display data given from the outside or obtained by processing it as a drive signal, various kinds of data for storing a display function given from outside, a display to be displayed, control commands, etc. A register or the like can be used.
[0059]
The display data storage unit 106 includes data (conversion table) for developing image data given from the outside as matrix data on the display, data obtained by developing predetermined character data and image data into matrix data as they are, and the like. The data is stored and can be read (written) by designating a storage position (address) as necessary. As such display data storage means, semiconductor storage elements such as RAM (VRAM), ROM and the like can be preferably cited. However, the display data storage means is not limited to this, and a storage medium (CD-R) applying light or magnetism. , DVD, HD, etc.) may be used.
[0060]
In addition, it is possible to provide temperature control for adjusting the preset period and drive voltage by detecting the external temperature as described above, and a control function for adjusting the preset period according to the number of drive electrodes.
[0061]
The scan electrode drive unit 102 and the data electrode drive unit 103 drive the scan electrode and the data electrode according to the scan electrode drive signal and the data electrode drive signal supplied from the display control control unit 105. An organic EL element constituting the organic EL display is a light emitting element that emits light by current drive. Therefore, a constant current source (constant current circuit) is used as the power supply when selecting the data electrode, but a constant voltage source may be used. The drive current is usually about 0.001 to 1 mA on the data side and about 0.001 to 300 mA on the scanning side.
[0062]
More specifically, a scanning electrode and a data electrode at a predetermined position are driven using a switching element such as a voltage-current conversion element having a necessary current capacity or an amplifying element (power amplification). Examples of the configuration of such a drive circuit include a push-pull circuit. As a switching element such as a voltage-current conversion element or an amplifying element, it is conceivable to use a contact device such as a relay. However, in consideration of high-speed operation, reliability, etc., transistors, FETs and the like are equivalent. A semiconductor element having a function is preferable. These may be integrated circuits such as ICs. These semiconductor elements connect scan electrodes and data electrodes to either the selected power source side or the non-selected power source side. Here, the selected power source side and the non-selected power source side include not only the case of connecting directly to the voltage source, the current source, and the ground line, but also the case of connecting via elements such as a current limiting resistor, a protection device, and a regulator. .
[0063]
The organic EL panel 101 is arranged so that a plurality of scanning electrodes and data electrodes intersect with each other, and a specific pixel (organic EL element) emits light by a drive signal given to these two arbitrary electrodes. It has become. The number of scanning electrodes and the number of data electrodes in the matrix portion are appropriately determined depending on the size and definition of the display, but usually the number of scanning electrodes is 1 to 768 and the number of data electrodes is about 1 to 3072.
[0064]
The above circuit is merely an example of a circuit configuration for driving the organic EL panel (organic EL display main body), and other circuit configurations can be used as long as they have equivalent functions. Further, the display control unit, the scan electrode driving unit, the data electrode driving unit, and the like may be integrated integrally without being clearly divided. Note that these circuit devices are usually configured as one or more types of ICs and their peripheral components.
[0065]
As a display driven by the apparatus of the present invention, for example, a display of home appliances such as a microwave oven, an electric rice cooker, an air conditioner, a video, an audio device, an automobile, a speedometer of a two-wheeled vehicle, a tachometer, a navigation system, an audio panel, etc. The various instruments used in various displays, various aircraft, control facilities, etc. are suitably used.
[0066]
Next, the element which comprises the organic electroluminescent panel (display) used for this invention is demonstrated.
[0067]
An organic EL panel has an organic layer containing an organic substance involved in at least a light emitting function between a scanning electrode (electron injection electrode) and a data electrode (hole injection electrode) arranged in a matrix on a substrate. Between these electrodes, a hole injection / transport layer that is an organic layer, a light emission and electron injection transport layer, and a protective layer as necessary are laminated, and a sealing plate such as glass is further disposed thereon.
[0068]
An organic EL element is comprised by the organic layer containing the following light emitting layers, and the electrode arrange | positioned above and below this organic layer.
[0069]
The light emitting layer has a hole (hole) and electron injection function, a transport function thereof, and a function of generating excitons by recombination of holes and electrons. It is preferable to use a relatively electronically neutral compound for the light emitting layer.
[0070]
The hole injecting and transporting layer has a function of facilitating the injection of holes from the hole injecting electrode, a function of stably transporting holes, and a function of blocking electrons. The electron injecting and transporting layer is composed of electrons from the electron injecting electrode. It has a function of facilitating the injection of electrons, a function of stably transporting electrons, and a function of blocking holes. These layers increase and confine holes and electrons injected into the light emitting layer, optimize the recombination region, and improve the light emission efficiency.
[0071]
The thickness of the light emitting layer, the thickness of the hole injecting and transporting layer, and the thickness of the electron injecting and transporting layer are not particularly limited and vary depending on the forming method, but are usually about 5 to 500 nm, particularly 10 to 300 nm. It is preferable.
[0072]
The thickness of the hole injecting and transporting layer and the thickness of the electron injecting and transporting layer may be the same as the thickness of the light emitting layer or about 1/10 to 10 times depending on the design of the recombination / light emitting region.
[0073]
The light emitting layer of the organic EL element contains a fluorescent substance that is a compound having a light emitting function. Examples of such a fluorescent substance include at least one selected from compounds such as those disclosed in JP-A 63-264692, such as quinacridone, rubrene, and styryl dyes. In addition, quinoline derivatives such as metal complex dyes having 8-quinolinol or a derivative thereof such as tris (8-quinolinolato) aluminum as a ligand, tetraphenylbutadiene, anthracene, perylene, coronene, 12-phthaloperinone derivatives, and the like can be given. . Further, phenylanthracene derivatives described in JP-A-8-12600, tetraarylethene derivatives described in JP-A-8-12969, and the like can be used.
[0074]
Moreover, it is also preferable to use it in combination with a host substance that can emit light by itself, and it is also preferable to use it as a dopant. In such a case, the content of the compound in the light emitting layer is preferably 0.01 to 20% by mass, more preferably 0.1 to 15% by mass. When used in combination with a host material, the emission wavelength characteristic of the host material can be changed, light emission shifted to a longer wavelength can be achieved, and the light emission efficiency and stability of the device can be improved.
[0075]
As the host substance, a quinolinolato complex is preferable, and an aluminum complex having 8-quinolinol or a derivative thereof as a ligand is more preferable. Examples of such aluminum complexes are those disclosed in JP-A-63-264692, JP-A-3-255190, JP-A-5-70733, JP-A-5-258859, JP-A-6-215874, and the like. Can be mentioned.
[0076]
As other host materials, phenylanthracene derivatives described in JP-A-8-12600, tetraarylethene derivatives described in JP-A-8-12969, and the like are also preferable.
[0077]
The light emitting layer is preferably a mixed layer of at least one hole injecting and transporting compound and at least one electron injecting and transporting compound, if necessary, and further contains a dopant in the mixed layer. It is preferable to make it. The content of the dopant in such a mixed layer is preferably 0.01 to 20% by mass, more preferably 0.1 to 15% by mass.
[0078]
For the hole injecting and transporting layer, for example, JP-A 63-295695, JP-A 2-191694, JP-A 3-792, JP-A-5-234681, JP-A-5-239455, Various organic compounds described in JP-A-5-299174, JP-A-7-126225, JP-A-7-126226, JP-A-8-100192, EPO650955A1, and the like can be used. For example, tetraarylbenzidine compounds (triaryldiamine or triphenyldiamine: TPD), aromatic tertiary amines, hydrazone derivatives, carbazole derivatives, triazole derivatives, imidazole derivatives, oxadiazole derivatives having amino groups, polythiophenes, etc. . These compounds may be used alone or in combination of two or more. When two or more types are used in combination, they may be laminated as separate layers or mixed.
[0079]
The electron injecting and transporting layer includes a quinoline derivative such as an organometallic complex having 8-quinolinol or a derivative thereof such as tris (8-quinolinolato) aluminum (Alq3) as a ligand, an oxadiazole derivative, a perylene derivative, a pyridine derivative, Pyrimidine derivatives, quinoxaline derivatives, diphenylquinone derivatives, nitro-substituted fluorene derivatives, and the like can be used. The electron injecting and transporting layer may also serve as the light emitting layer. In such a case, it is preferable to use tris (8-quinolinolato) aluminum or the like. The electron injecting and transporting layer may be formed by vapor deposition or the like, similar to the light emitting layer.
[0080]
In forming the hole injecting and transporting layer, the light emitting layer, and the electron injecting and transporting layer, it is preferable to use a vacuum deposition method because a homogeneous thin film can be formed. When the vacuum deposition method is used, a homogeneous thin film having an amorphous state or a crystal grain size of 0.2 μm or less can be obtained. If the crystal grain size exceeds 0.2 μm, non-uniform light emission occurs, the drive voltage of the device must be increased, and the charge injection efficiency is also significantly reduced.
[0081]
The conditions for vacuum deposition are not particularly limited, but 10^-Four It is preferable that the degree of vacuum is less than or equal to Pa, and the deposition rate is about 0.01 to 1 nm / sec. Moreover, it is preferable to form each layer continuously in a vacuum. If formed continuously in a vacuum, impurities can be prevented from adsorbing to the interface of each layer, so that high characteristics can be obtained. Further, the driving voltage of the element can be lowered, and the generation / growth of dark spots can be suppressed.
[0082]
In the case of using a vacuum deposition method for forming each of these layers, when a plurality of compounds are contained in one layer, it is preferable to co-deposit each boat containing the compounds by individually controlling the temperature.
[0083]
The electron injecting and transporting layer and the hole injecting and transporting layer may be inorganic layers using an inorganic material such as Si or Ge. In addition to the organic layer, the organic EL display has a functional thin film such as a hole injection electrode and an electron injection electrode formed so as to sandwich the organic layer on the substrate.
[0084]
As the electron injection electrode, a material having a low work function is preferable. For example, a simple metal element such as K, Li, Na, Mg, La, Ce, Ca, Sr, Ba, Al, Ag, In, Sn, Zn, or Zr. In order to improve the stability, it is preferable to use a two-component or three-component alloy system containing them. As an alloy system, for example, AgMg (Ag: 0.1 to 50 atomic%), AlLi (Li: 0.01 to 14 atomic%), InMg (Mg: 50 to 80 atomic%), AlCa (Ca: 0.01) ˜20 atomic%), LiF and the like. Note that the electron injection electrode can also be formed by vapor deposition or sputtering.
[0085]
The thickness of the electron injection electrode thin film may be a certain thickness or more that can sufficiently perform electron injection, and may be 0.5 nm or more, preferably 1 nm or more, more preferably 3 nm or more. Moreover, although there is no restriction | limiting in particular in the upper limit, Usually, a film thickness should just be about 3-500 nm. An auxiliary electrode or a protective electrode may be further provided on the electron injection electrode.
[0086]
The pressure during vapor deposition is preferably 1.33 × 10^-Four~ 1.33 × 10^-1 Pa (1 × 10^-8 ~ 1x10^-Five Torr), the heating temperature of the evaporation source is preferably about 100 to 1400 ° C. for a metal material and about 100 to 500 ° C. for an organic material.
[0087]
The hole injection electrode is preferably a transparent or translucent electrode for extracting emitted light. Transparent electrodes include ITO (tin-doped indium oxide), IZO (zinc-doped indium oxide), ZnO, and SnO.₂ , In₂O_Three Of these, ITO (tin-doped indium oxide) and IZO (zinc-doped indium oxide) are preferred. ITO is usually In₂O_Three And SnO are contained in a stoichiometric composition, but the amount of O may be somewhat deviated from this. If the hole injection electrode does not require transparency, an opaque known metal material or the like may be used.
[0088]
The thickness of the hole injection electrode is sufficient if it has a certain thickness that allows sufficient hole injection, and is preferably in the range of 50 to 500 nm, more preferably 50 to 300 nm. The upper limit is not particularly limited, but if it is too thick, there is a concern about peeling. If the thickness is too thin, there are problems in terms of film strength, hole transport capability, and resistance value during manufacture.
[0089]
The hole injection electrode layer can be formed by vapor deposition or the like, but is preferably formed by sputtering, particularly DC sputtering.
[0090]
The electrode on the light extraction side preferably has an emission wavelength band, usually 350 to 800 nm, and particularly has a light transmittance of 50% or more, particularly 60% or more, and more preferably 70% or more for each emission light. After forming the hole injection electrode layer, a protective film using an inorganic material such as SiOx, an organic material such as Teflon (registered trademark), a fluorocarbon polymer containing chlorine, or the like may be formed.
[0091]
The emission color may be controlled by using a color filter film, a color conversion film containing a fluorescent substance, or a dielectric reflection film on the substrate.
[0092]
The organic EL panel is driven by direct current or pulse, and can be driven by alternating current. The driving voltage is usually about 2 to 30V. The light emission threshold voltage Vth of the organic EL element is usually about 2 to 6V.
[0093]
【Example】
[Example 1]
A panel was produced in which organic EL elements having a parasitic capacitance C of 18 pF / dot were arranged at a length of 64 dots and a width of 240 dots. When this panel is driven using a scan driver with Ic = 10 mA under the conditions of 1 scan time of 100 μs, Vc of 17.5 V, and Vf of about 11 V, the reset time is set to 4.8 μs and the preset time is set to 1.6 μs. did.
[0094]
The preset charging voltage V ′ of this display device was about 4 V, and overshoot and undershoot were suppressed to ± 10% or less at the maximum, and good image quality could be obtained.
[0095]
[Example 2]
In the panel of Example 1, the change due to the temperature of the power supply voltage was brought as close to −0.06 V / ° C. as possible to −0.1 V / ° C. At the same time, the change with temperature in the preset period was made as close to −26 ns / ° C. as possible, and it was driven at −25.6 ns / ° C. As a result, good images could be obtained in the temperature range from -20 ° C to 85 ° C.
[0096]
Example 3
In the panel of Example 1, control was performed by changing the preset period as close as possible to −66 ns / line by the selected data line. A better image could be obtained by this driving.
[0097]
【The invention's effect】
As described above, according to the present invention, it is possible to reduce the overshoot and undershoot that occur due to the change in the number of selected elements, and to realize an image display device that improves the displayed image quality and a driving method thereof. .
[Brief description of the drawings]
FIG. 1 is a chart showing a voltage applied to an electrode of an image display device.
FIG. 2 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus.
FIG. 3 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus.
FIG. 4 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus.
FIG. 5 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus.
FIG. 6 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus according to the embodiment of the present invention.
FIG. 7 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus according to the embodiment of the present invention.
FIG. 8 is a partial circuit diagram illustrating the operation and configuration of the image display apparatus according to the embodiment of the present invention.
FIG. 9 is a graph showing IV characteristics of commonly used transistors.
FIG. 10 is a block configuration diagram showing a basic configuration of an apparatus according to the present invention.
[Explanation of symbols]
101 Organic EL panel
102 Scan electrode driver
103 Data electrode driver
104 Main control unit
105 Display control unit
106 Display data storage unit

Claims (4)

A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; at least a first potential for selecting the scan electrode and a second potential for selecting the scan electrode; A scan electrode side switch connected to any one of the data electrodes; a constant current source supplying at least a predetermined constant current to the data electrode; and a data electrode side switch connected to any one of the first potential to be in an inoperative state. With
An image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scan electrodes,
When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided ,
The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
An image display device in which overshoot or undershoot is within 10% by adjusting a time width of the preset time depending on temperature . A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; at least a first potential for selecting the scan electrode and a second potential for selecting the scan electrode; A scan electrode side switch connected to any one of the data electrodes; a constant current source supplying at least a predetermined constant current to the data electrode; and a data electrode side switch connected to any one of the first potential to be in an inoperative state. With
An image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scan electrodes,
When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
An image display device in which overshoot or undershoot is within 10% by adjusting a time width of the preset time according to the number of thin film display elements to be selectively driven next. A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; at least a first potential for selecting the scan electrode and a second potential for selecting the scan electrode; A scan electrode side switch connected to any one of the data electrodes; a constant current source supplying at least a predetermined constant current to the data electrode; and a data electrode side switch connected to any one of the first potential to be in an inoperative state. With
A driving method of an image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scanning electrodes,
When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
A method for driving an image display apparatus, wherein an overshoot or undershoot is made within 10% by adjusting a time width of the preset time depending on temperature . A plurality of scan electrodes, a plurality of data electrodes, and a thin film display element driven by a current at the intersection thereof; at least a first potential for selecting the scan electrode and a second potential for selecting the scan electrode; A scan electrode side switch connected to any one of the data electrodes; a constant current source supplying at least a predetermined constant current to the data electrode; and a data electrode side switch connected to any one of the first potential to be in an inoperative state. With
A driving method of an image display device for driving the thin film display element to form an image by supplying a display signal to the data electrode in synchronization with the sequential selection of the scanning electrodes,
When supplying a display signal to the data electrode, a reset period for connecting all the electrodes to an arbitrary reset potential is provided in advance.
Subsequently, a preset period for connecting all the data electrodes to the first potential at the same time as connecting the scan electrodes selected during the next scan period to the first potential and the other scan electrodes to the second potential is provided,
The preset period prevents the potential of the data electrode selected during the next scanning period from overshooting or undershooting 10% or more above and below a specified voltage,
A method for driving an image display apparatus, wherein an overshoot or undershoot is made within 10% by adjusting a time width of the preset time according to the number of thin film display elements to be selectively driven next.

Images