JP2003295785A - Organic el display device and its driving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a transverse cross talk of display in an organic EL display device 100. <P>SOLUTION: In a wiring connection between a panel 20 in which an organic EL structure body is held between a scanning electrode 2 and a data electrode 3 and a driving IC 10, the scanning electrode 2 is connected linearly to a scanning electrode driving circuit IC, a first data electrode driving circuit 1A is arranged on the upper side of the panel 20, a second data electrode driving circuit 1B is arranged on the lower side of the panel 20, and each output terminal groups of the scanning electrode driving circuit 1C, the first data electrode driving circuit 1A, and the second data electrode driving circuit 1B are arranged along one side of a left side of the panel 20. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a passive drive type organic EL display device and its drive device.

[0002]

2. Description of the Related Art An organic EL display device is a current drive type display device which emits light spontaneously by supplying a current to an organic thin film disposed between a cathode and an anode provided opposite to each other. The equivalent circuit is shown in FIG. The organic EL element has characteristics similar to those of a semiconductor light emitting diode and is therefore also called an organic LED.

The anode side of this organic EL element is set to the high voltage side, and a predetermined voltage is applied between both electrodes to supply a current to the organic thin film to emit light. On the contrary, when the cathode side is set to a high potential, almost no current flows and no light is emitted. The organic thin film sandwiched between both electrodes has a capacitance that cannot be ignored.

When a constant voltage is applied to the organic thin film of the organic EL element, the emission brightness of the organic EL element greatly fluctuates due to changes in temperature and changes with time. However, the variation of the emission brightness of the organic EL element with respect to the current value is small. When performing display using the organic EL element, a constant current circuit is provided in the drive circuit in order to obtain a predetermined display brightness, and a constant current is supplied to each organic EL element forming the display screen. In the case of an organic EL display device, it is common to use a constant current driving method.

An organic EL display device in which an organic EL element is arranged in each pixel portion of a matrix electrode has already been realized. 8 is a plan view, FIG. 10 (a) is a perspective view, and FIG.
A sectional view is shown in FIG. A plurality of anode wirings 3 connected to the anode or forming the anode itself and a plurality of cathode wirings 2 connected to the cathode or forming the cathode itself are arranged in a direction orthogonal to the anode wirings 3.

The intersection of the cathode wiring 2 and the anode wiring 3 becomes a pixel 5, and the organic thin film 4 is sandwiched between both electrodes. In this way, the pixels formed of the organic EL elements are arranged in a plane on the glass substrate 6 in a matrix.

Generally, the cathode wiring 2 is formed of a metal, and the anode wiring 3 is formed of a transparent conductive thin film such as ITO (indium / tin / oxide). Next, a simple matrix driving method for the organic EL display device will be described. Less than,
One of the anode wiring and the cathode wiring serves as a scanning electrode and the other serves as a data electrode.

First, scan electrodes are connected to a scan wiring drive circuit provided with a constant voltage circuit. The scan electrodes are driven with a constant voltage. Then, the scan electrodes are sequentially scanned, and one of the scan electrodes is set in a selected state and the other is set in a non-selected state, and the scan electrodes are selected every predetermined period. In general, scanning is performed from one end of the scan electrode to the other end, all the scan electrodes are scanned during a certain period, and a predetermined drive voltage is applied.

Next, the data electrode is connected to the data electrode driving circuit having a constant current circuit at the output stage. Display data corresponding to the display pattern of the selected scan electrode is supplied to all data electrodes in synchronization with scanning. The current pulse _ID supplied from the constant current circuit to the data electrode flows to the selected scan electrode through the organic EL element located at the intersection of the selected scan electrode and the data electrode.

The pixel of the organic EL element emits light only while the scan electrode connected to the pixel is selected and the current is supplied from the data electrode. When the supply of current from the data electrode is stopped, the light emission also stops.

In this way, a current is supplied to the organic EL element sandwiched between the data electrode and the scanning electrode,
Scanning of all scan electrodes is sequentially repeated. Then, the light emission / non-light emission of the pixels of the entire display screen is controlled according to a desired display pattern.

When driving, the anode and cathode of the organic EL element can be set to either scan electrodes or data electrodes. That is, the anode can be used as the scanning electrode and the cathode can be used as the data electrode, or the anode can be used as the data electrode and the cathode can be used as the scanning electrode. Both electrodes are compatible in driving. The relationship between the polarities of the organic EL elements and the electrodes may be adjusted and arranged.

Generally, the data electrode is often associated with the anode and the scan electrode is often associated with the cathode. Hereinafter, the driving method and the display state of the organic EL display device will be described in which the cathode is the scanning electrode and the anode is the data electrode.

Regardless of whether the display screen is viewed by a human being vertically or horizontally, the pixels arranged in the direction parallel to the scanning wiring are "rows", and the pixels arranged in the direction parallel to the data wiring. The sequence of is also called a "column".

First, the scanning electrode connected to the cathode of the organic EL element needs to satisfy the following potential conditions. That is, the potential of the selected scan electrode must be set lower than the potential of the non-selected scan electrode. for that reason,
The scan electrode in the selected state is set to the ground (ground) potential, and the scan electrode in the non-selected state is driven to give a potential higher than the ground potential.

A constant current is supplied to the data electrode on the column side when the output data is ON data that causes the "pixel" to emit light. When the output data is off data that makes the "pixel" not emit light, an output of a constant voltage equal to the ground potential is supplied. That is, it is configured to switch between constant current output and constant voltage output depending on whether the "pixel" is on or off. The constant current output to the data electrode is for controlling the emission brightness by the current value as described above.

The direction of the current flowing through the organic EL element is set so as to flow from the data electrode, which is the anode, through the organic thin film, to the scan electrode, which is the cathode. Therefore, the potential of the data electrode is set higher than the ground potential which is the potential of the scan electrode in the selected state. In the organic EL display device,
When the entire display screen is made to emit light, the current flowing into one scanning electrode in the selected state increases in proportion to the number of columns when the number of rows is constant. Also, as the number of rows increases, the scanning electrodes correspondingly lengthen. Therefore, the total resistance value of the scanning electrodes from the left end to the right end of the screen also becomes large.

Further, the wiring drawn to connect the scan electrode to the drive circuit outside the organic EL display device also has a resistance. When the current flowing into the scan electrode having a predetermined resistance and the lead-out wiring becomes large, the potential of the scan electrode, which should originally be the ground potential, becomes higher than the ground potential.

When the organic EL display device is driven by the simple matrix driving method, the potential of the scanning electrode (cathode) at the time of whole surface emission may become higher than the original ground potential. Then, the following problems occurred.

When driving the organic EL display device,
A data electrode drive circuit having a constant current circuit on the column side is used. Therefore, as described above, even if the potential of the scan electrode rises, a predetermined current _ID is supplied from the data electrode drive circuit to the data electrode. This is because the emission of the organic EL element is basically driven by current. Therefore, the potential of the data electrode rises to the potential to which the potential increase is added. There is a relation of “data wiring potential = scanning electrode potential + terminal voltage of organic EL element”.

However, when the potential increase on the side of the scan electrodes facing each other is large, the potential of the data electrode rises to a potential close to the power supply voltage of the data electrode drive circuit. Then, the drivability of the constant current circuit of the data electrode drive circuit is saturated, and the potential of the data electrode cannot be raised sufficiently. Then, a predetermined current does not sufficiently flow in the organic EL element forming the pixel, and the emission brightness of the pixel becomes darker than a desired set value.

As a result, there occurs a phenomenon that the emission luminance becomes darker in a row having a larger number of light emitting pixels, that is, a row having a larger increase in the potential of the scanning electrode. Figure 11 shows the normal status
It shows in (a). On the other hand, if the potential increase of the scanning electrode is large, horizontal band-shaped unevenness occurs according to the display pattern (FIG. 11B). This is called horizontal crosstalk.

Next, the arrangement of the drive circuit and electrodes in the organic EL display device will be described. Regarding the passive drive type organic EL display device, the wiring system between the drive circuit and each electrode of the panel for displaying an image has the same configuration as that of the passive drive type liquid crystal display device. An output terminal of the scan electrode drive circuit and an output terminal of the data electrode drive circuit are provided on each of two sides of the drive IC so as to be connected to each electrode of the panel (see FIG. 5).

Further, FIG. 12 shows a one-chip type drive IC.
1 shows a conventional organic EL display device 50 mounted on a film by using. The output terminals of the drive IC 10 are arranged along the lower side of the panel 20 in which the scan electrodes 2 and the data electrodes 3 are orthogonally arranged, and the first scan electrode drive circuit 1C and the second scan electrode drive circuit 2C are driven. The IC 10 is separately arranged at both ends. Leading wirings are arranged from the left side and the right side of the panel 20 to the scanning electrodes. The wiring from the data electrode driving circuit 1A to the data electrode 3 is short and arranged substantially linearly. In this organic EL display device 50, a voltage rise occurs in the lead wiring of the scan electrodes, and horizontal crosstalk occurs in the display.

If the same layout configuration as in the passive drive type liquid crystal display device is adopted for routing the wiring from the drive circuit to the electrodes as in these conventional examples, the panel 20 is used.
The output terminals of the drive IC 10 are arranged along the lower side of the data electrode 3. In this case, the panel 20
Wirings 1C from the respective output terminals of the scan electrode drive circuits 1C and 2C for the scan electrodes 2 located in the left and right direction of
The effective wiring length of -L and 2C-L becomes long.

As a result, there is an unnecessary electric resistance between the output terminal of the scan electrode driving circuit for driving the scan electrode and the connecting end portion of the scan electrode. In addition, since a large current is required for selecting the scan electrodes in the multiplex drive, a voltage drop due to electric resistance occurs in each part of the scan electrodes from the routing wiring, causing a change in the drive potential.

Variations in driving conditions from the scan electrode drive circuit to the scan electrodes, for example, variations in drive potential depending on the position between the left end portion and the right end portion of the scan electrode are displayed as described above. It is visually recognized as horizontal crosstalk on the screen (see Japanese Patent Application No. 2001-353260).

[0028]

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to obtain a circuit configuration of a drive system of an organic EL display device which can satisfy an optimum drive condition. Further, in the organic EL display device, it is another object of the present invention to reduce the size of the device and improve the mechanical strength of the connection by using the driving device mounted on the substrate as one component, especially the chip-on-glass method. Another object is to obtain an organic EL display device that is easy to mount and has a narrow frame area. Another object is to obtain a driving device for an organic EL display device having a new layout of output terminals.

[0029]

That is, according to the first aspect of the present invention, a scan electrode, a data electrode, and a light emitting layer are provided on a substrate, a drive device is configured by an integrated circuit, and the scan electrode drive circuit is provided in the drive device. And a data electrode drive circuit, the scan electrode is connected to the scan electrode drive circuit, the data electrode is connected to the data electrode drive circuit, and the drive device is near one side of the display surface formed by the scan electrode and the data electrode. In the provided organic EL display device, the driving device is arranged along the side on the side connected to the scanning electrodes, and the output terminals of the scanning electrode driving circuit are connected to the scanning electrodes one-to-one.
The data electrode driving circuit is divided into two regions so that the number of data electrodes is divided into two, and the first data electrode driving circuit is arranged on one end side of the data electrode.
The organic EL display device is characterized in that the data electrode driving circuit is arranged on the other end side of the data electrode.

In the second aspect, the scanning electrodes, the data electrodes, and the light emitting layer are provided on the substrate, the driving device is configured by an integrated circuit, and the driving device is provided with the scanning electrode driving circuit and the data electrode driving circuit. Is connected to the scan electrode drive circuit, the data electrode is connected to the data electrode drive circuit,
The driving device is an organic EL display device provided in the vicinity of one side of the display surface composed of the scan electrodes and the data electrodes, and the driving device is arranged along the side on the connection side of the scanning electrodes, and the scanning electrode driving circuit is provided. The output terminals of are connected to the scan electrodes in a one-to-one relationship, the output terminals of the data electrode drive circuit are arranged on one side of the drive device, and the wiring from the data electrode drive circuit to the data electrodes is provided along only one side of the display surface. Provided is an organic EL display device characterized by being arranged.

Aspect 3 provides the organic EL display device according to Aspect 1 or 2, wherein a chip-shaped driving device is arranged on a substrate.

Aspect 4 is the organic E according to Aspect 1, 2 or 3, wherein the average wiring length of the lead wiring from the output terminal of the scan electrode drive circuit to the end of the scan electrode is 20 mm or less.
An L display device is provided. In order to achieve miniaturization as a display device, it is preferably 10 mm or less.

Aspect 5 is a drive device provided with a scan electrode drive circuit and a data electrode drive circuit for respectively driving the scan electrode and the data electrode of the organic EL display device, wherein the scan electrode drive circuit and the data electrode drive circuit are provided. A driving IC or a chip provided in one package, wherein the data electrode driving circuit is roughly divided into a first data electrode driving circuit and a second data electrode driving circuit, and a first data electrode driving circuit. And a drive device in which the output terminal group of the scan electrode driving circuit is arranged between the output terminal groups of the first and second data electrode driving circuits.

Aspect 6 provides the driving device according to Aspect 5, wherein the output terminals of the scan electrode drive circuit corresponding to the scan electrodes to be driven are 30 or more.

Aspect 7 is an aspect 5 in which the output terminals of the data electrode drive circuit corresponding to the data electrodes to be driven are 20 or more.
Alternatively, the drive device according to the sixth aspect is provided.

Aspect 8 is an aspect in which the maximum drive current per data electrode × the number of data electrodes ≧ 10 mA.
Alternatively, the drive device according to Item 7 is provided.

Further, in each of the above aspects, it is preferable that the width of the leading wiring connecting the data electrode and the data electrode driving circuit is 10 to 100 μm. The electrodes can be configured to be suitable for a high-definition screen, and the frame portion outside the display surface can be configured to be small.

Further, it is preferable that the voltage drop from the output terminal of the scan electrode drive circuit to the connection end of the scan electrode is within 1.0V. Further, it is preferable that the screen size of the number of scanning electrodes × the number of data electrodes is 40 mm or more in a diagonal direction. Even with a screen size that can be driven by one driving device, good display can be provided by adopting an electrode configuration suitable for the screen display.

The voltage drop from the output terminal of the data electrode drive circuit to the connection terminal of the data electrode is 1.0V.
The following is preferable. Further, it is preferable that the voltage drop from the other ends of the connection ends of all the scan electrodes to the output terminals of the drive circuit is 1.5 V or less. As a result, a display device having a uniform screen brightness can be obtained.

[0040]

BEST MODE FOR CARRYING OUT THE INVENTION In the present invention, an arrangement is made so as to shorten the routing of wiring from the output terminal of the drive circuit to the electrode of the organic EL display device. Wiring from each output terminal of the scan electrode drive circuit and data electrode drive circuit to each connection end of the scan electrode and data electrode is reduced in electrical influence and the effective wiring length on the scan electrode side is shortened. To configure.

Particularly, when the scan electrode driving circuit and the data electrode driving circuit are provided in one integrated circuit, the arrangement of the output electrodes arranged substantially in a line along substantially one side or three sides ( 6 and 7), the output terminals of the scan electrodes and the data electrodes are arranged so as to be balanced with respect to the display surface, and the total effective wiring length in the drive circuit system is designed to be short. Do.

The drive circuit may be provided in a plurality of packages, but it is preferable that the drive circuit is an integrated circuit made up of one package. Further, it is particularly preferable that the chip-on-glass is mounted on the periphery of the glass substrate in a chip state. This is preferable because the packaging density per unit area can be improved, the display device can be downsized, and the scale of peripheral circuits can be suppressed.

A transparent electrode such as ITO is used on the front side of the scanning electrodes and the data electrodes arranged orthogonally for displaying. It is preferable to use laminated metal electrodes on the back side. Then, the transparent electrode on the front side is used as a data electrode,
It is preferable to use the back electrode as the scanning electrode.

In the present invention, the routing wiring from the drive circuit to the scan electrodes is designed to be relatively shorter than the routing wiring from the drive circuit to the data electrodes. This is because a large current flows through the scan electrodes. At this time, it is preferable that both the leading wiring to the scanning electrode and the leading wiring to the data electrode are metal wiring or stacked wiring containing metal.

In addition, a current of "maximum drive current per orthogonal data electrode × number of data electrodes" can flow through the scanning electrodes during selection. Therefore, it is preferable to use a low resistance metal material for the lead wiring connected to the scan electrodes. For example, it is preferable to use metal wiring in which chromium / aluminum, molybdenum / aluminum, or the like are stacked.

Further, the sheet resistance of the lead wiring from the output terminal of the drive circuit to the connection end of the panel electrode is 0.0.
2Ω / □ or more. For example, in the case of aluminum wiring with a thickness of about 3000Å, its sheet resistance is about 0.1.
Ω / □, and it is preferable that the wiring has a predetermined thickness from the viewpoint of a normal manufacturing process and production cost. Next, production of a substrate provided with an organic EL light emitting element will be described.
The target panel brightness is 200 cd / m ² .

ITO having a film thickness of 200 nm is etched to form a data electrode leading wiring having a line width of 10 to 100 μm. The data electrode functions as an anode. Further, polyimide is applied thereon as an insulating film to remove a square or rectangular region which emits light in each pixel.

On top of this, an organic thin film of an organic EL element is laminated by a vacuum evaporation method. First, a 20-nm-thick copper phthalocyanine film is formed as the first hole-transporting layer, and a 40-nm-thick film of α-NPD is formed as the second hole-transporting layer. Then, Alq is used as a host compound of the light-emitting layer and the fluorescence of the guest compound is formed. Coumarin 6 is simultaneously vapor-deposited as a pigment to form a film thickness of 60 nm. Further, 0.5 as LiF as a cathode interface layer.
nm vapor deposition.

Finally, as a cathode, a scan electrode is formed of aluminum having a film thickness of 100 nm and connected to a scan electrode drive circuit. It is possible to secure a line width within a range in which the width of the scanning electrode is allowed on the substrate so that the pixel size becomes a predetermined pixel size. This is because the output terminal of the scan electrode drive circuit and the connection end of the scan electrode can be connected substantially linearly.

In order to prevent moisture from entering the organic thin film, the organic EL element thus formed on the glass substrate is
Another glass substrate is placed opposite to each other and the two substrates are joined together by a peripheral sealing material, and the data electrode drive circuit and the scan electrode drive circuit are connected to the data electrode and the scan electrode drawn out from the inside to the outside, respectively. At this time, it is preferable to provide a hygroscopic agent inside the space between the two substrates facing each other. In the following examples, a metal electrode having a laminated structure containing aluminum or aluminum or chromium having a thickness of about 3000 Å was used for the leading wiring.

The present invention is suitable for use in a portable display device having a diagonal size of about 50 mm and a vehicle-mounted display device having a diagonal size of 10 cm or less.

[0052]

EXAMPLES (Example 1) FIG. 1 is an example in which one driving IC 10 is arranged on the left side of an organic EL display device 100 of the present invention. The area of the output terminal is provided so as to divide the drive IC 10 into three parts, and the first data electrode drive circuit 1A, the scan electrode drive circuit 1C, and the second data electrode drive circuit 1B are sequentially arranged.

The panel 20 has a data electrode 3 and a scan electrode 2
Are arranged orthogonally to each other, a light emitting layer made of an organic EL structure is sandwiched between both electrodes, and spontaneous emission is caused by supplying a current. Driving is performed so as to turn on / off a pixel at a desired position in the XY matrix, and an image is displayed on the panel 20.

The output terminal of the driving IC 10 is shown in FIG. 6 or 7.
The arrangement shown in FIG. Substantially in line with the panel 20, they are arranged. The wiring lines 1A-L extending from the output of the first data electrode driving circuit 1A to the panel 20 are arranged along the upper side of the panel 20.

Lead wiring 1B from the output terminal of the second data electrode driving circuit 1B to the data electrode 3 of the panel 20.
-L is located along the lower edge of the panel.

From the scan electrode driving circuit 1C to the connection end portion of the scan electrode 2 of the panel 20, the connection is made substantially linearly with a short wiring length. When the organic EL display device of this example was driven, it was possible to display a good image without horizontal crosstalk and in which the brightness of each pixel on the screen was uniform.

Example 2 FIG. 2 shows an organic EL display device 1 of this example.
01 schematically shows the arrangement configuration. In this example, the data electrode drive circuit 1A is provided on one side (panel 20) of one drive IC.
And the scan electrode driving circuit is arranged on the other side of the driving IC (the lower side of the panel 20). The wiring extending from the scan electrode driving circuit 1C to the connection end of the scan electrode 2 of the panel 20 was linear, and the wiring length could be shortened. When the organic EL display device of this example was driven, a clear display was obtained as in Example 1.

Example 3 FIG. 3 shows an organic EL display device 1 of this example.
10 shows a layout configuration of 10. This example is the reverse of Example 1, and the data electrode 3 connected to the first data electrode driving circuit 1A located on the upper side of the panel 20 is located on the left side of the panel 20.

The data electrode 3 connected to the second data electrode drive circuit 1B located on the lower side of the panel 20 is the panel 2
It is arranged so as to be located on the right side of 0. Similar to Example 1, the leading wiring from the output terminal of the scan electrode driving circuit 1C to the connection terminal of the scan electrode 2 was linear, and the wiring length could be shortened. When driving was performed, it was possible to display a good image without horizontal crosstalk and in which the brightness of each pixel on the screen was uniform.

Example 4 An organic EL display device 111 of this example is shown in FIG. The routing wirings 1B-L to the end portions of the data wirings in this example are arranged so as to have an opposite relationship to the layout configuration of Example 2 when the panel surface is used as a reference. When the organic EL display device of this example was driven, a clear display was obtained as in Example 3.

(Example 5) In this example, the leading wirings reaching the data electrodes are arranged every other data wiring above and below the panel. The leading wirings reaching the even and odd rows of the data electrode wirings are separately arranged on the upper side and the lower side of the panel. In this example, a sufficient space can be secured at the connection end portion of the lead wiring to the data electrode, so that the width of the lead wiring can be widened as a whole, and the resistance value can be further reduced. Organic E of this example
When the L display device was driven, a clear display could be obtained.

Example 6 In each of Examples 1 to 5 described above, an organic EL display device was manufactured by using one chip-on-glass as the method of mounting the drive circuit on the substrate. The peripheral circuit can be downsized, and the frame area outside the display surface can be reduced. Further, an organic EL display device having excellent display characteristics could be obtained.

[0063]

According to the present invention, the effective wiring length from the output terminal of the scan electrode drive circuit to the scan electrode is shortened, unnecessary voltage drop during driving is reduced, and stable display characteristics are easily obtained. You can

Further, the wiring around the display surface can be compacted, which contributes to downsizing of the display device.
Further, the driving device can be a single driving IC, which facilitates mounting of the organic EL display device. In addition, production efficiency can be improved.

Further, when a low resistance material capable of driving a large current is used for the scanning electrodes, for example, by forming an electrode structure in which a plurality of metals such as aluminum and molybdenum are laminated, higher brightness and uniform brightness can be obtained. You can get an indication of the

Further, when a chip-shaped integrated circuit is used as a driving device and mounted on a substrate and connected to the scan electrodes and data electrodes of the organic EL display device, the mechanical strength of the connection between the organic EL display device and the driving device is increased. Improved and FP to the outside
Since the number of C-mounted terminals is reduced, the mechanical reliability of the connection can be sufficiently ensured.

[Brief description of drawings]

FIG. 1 is a schematic plan view of Example 1 of the present invention.

FIG. 2 is a schematic plan view of Example 2 of the present invention.

FIG. 3 is a schematic plan view of Example 3 of the present invention.

FIG. 4 is a schematic plan view of Example 4 of the present invention.

FIG. 5 is a schematic plan view of a drive device of a conventional example.

FIG. 6 is a first configuration example of the output terminal of the drive IC in the present invention.

FIG. 7 is a second configuration example of the output terminal of the drive IC in the present invention.

FIG. 8 is a schematic plan view of a conventional organic EL display device.

FIG. 9 is an equivalent circuit diagram of an organic EL element.

FIG. 10 is a schematic perspective view (a) and a schematic sectional view (b) of an organic EL display device.

FIG. 11 shows a normal display screen of an organic EL display device (a),
Horizontal crosstalk display (b).

FIG. 12 is a schematic plan view of a conventional example.

[Explanation of symbols]

1: Output terminal 2: Scan electrode 3: Data electrode 10: Drive IC 20: Panel 1A-L, 1B-L: Lead wiring for data electrodes 1C-L: Lead wiring to scan electrodes

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification symbol FI theme code (reference) G09G 3/30 G09G 3/30 J H05B 33/14 H05B 33/14 AF term (reference) 3K007 AB17 BA06 BB07 CC04 DB03 GA00 5C080 AA06 BB05 DD10 DD25 DD28 FF12 JJ01 JJ06 5C094 AA03 AA09 BA01 BA27 CA19 DA09 DB01 EA10 FA01 FB12 HA08 HA10 JA04 JA08 5G435 AA01 AA16 BB05 CC09 EE37 EE44 HH12 KK05 KK09 KK09 KK09

Claims (8)

[Claims] 1. A scan electrode, a data electrode, and a light-emitting layer are provided on a substrate, a driving device is formed by an integrated circuit, a driving electrode is provided with a scanning electrode driving circuit and a data electrode driving circuit, and the scanning electrode is scanned. The driving device is an organic EL display device connected to an electrode driving circuit, the data electrode is connected to the data electrode driving circuit, and the driving device is an organic EL display device provided in the vicinity of one side of a display surface composed of the scanning electrode and the data electrode. Are arranged along the sides on the side connected to the scan electrodes, the output terminals of the scan electrode drive circuit are connected to the scan electrodes in a one-to-one relationship, and the data electrode drive circuit is arranged so that the number of data electrodes is roughly divided into two. , The first data electrode driving circuit is arranged on two sides, and the first data electrode driving circuit is arranged on one end side of the data electrode.
2. The organic EL display device characterized in that the data electrode drive circuit of is arranged on the other end side of the data electrode. 2. A scan electrode, a data electrode, and a light emitting layer are provided on a substrate, a driving device is constituted by an integrated circuit, a driving electrode is provided with a scanning electrode driving circuit and a data electrode driving circuit, and the scanning electrode is scanned. The driving device is an organic EL display device connected to an electrode driving circuit, the data electrode is connected to the data electrode driving circuit, and the driving device is an organic EL display device provided in the vicinity of one side of a display surface composed of the scanning electrode and the data electrode. Are arranged along the side of the scan electrode connection side, the output terminals of the scan electrode drive circuit are connected to the scan electrodes in a one-to-one relationship, and the output terminals of the data electrode drive circuit are arranged on one side of the drive device, An organic EL display device characterized in that wiring extending from an electrode driving circuit to a data electrode is arranged along only one side of a display surface. 3. The organic EL display device according to claim 1, wherein the chip-shaped driving device is arranged on the substrate. 4. The organic EL display device according to claim 1, 2 or 3, wherein an average wiring length of the leading wiring from the output terminal of the scan electrode driving circuit to the end portion of the scan electrode is 20 mm or less. 5. A drive device provided with a scan electrode drive circuit and a data electrode drive circuit for respectively driving a scan electrode and a data electrode of an organic EL display device, the scan electrode drive circuit and the data electrode drive circuit being one. A drive IC or a chip provided in the package, wherein the data electrode drive circuit includes a first data electrode drive circuit and a second data electrode drive circuit.
Drive device in which the output electrode group of the scan electrode drive circuit is arranged between the output terminal groups of the first data electrode drive circuit and the second data electrode drive circuit. 6. The drive device according to claim 5, wherein the output terminals of the scan electrode drive circuit corresponding to the driven scan electrodes are 30 or more. 7. The output terminal of a data electrode drive circuit corresponding to a data electrode to be driven is 20 or more.
The drive device according to. 8. The maximum drive current per data electrode × the number of data electrodes ≧ 10 mA.
The drive device according to.