JP2005275263A - El display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an EL display device whose luminance is enhanced and cost is reduced. <P>SOLUTION: In the EL display panel 12, the respective scanning electrodes 14(1), 14(2), ... are formed so as to simultaneously drive EL elements 16 existing in three continuous lines among EL elements 16 arranged like a matrix. The EL elements 16 to be simultaneously driven are connected to different data electrodes 15, respectively. The respective data electrodes 15 are constituted of rectangular element formation parts 15a formed according to arranged positions like a matrix of the EL elements 16 and linear connection parts 15b which sequentially connect the element formation parts 15a of the EL elements 16 to be driven by mutually different scanning electrodes 14. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention provides a dot matrix in which a plurality of scanning electrodes are provided on one surface side of an EL light emitting layer, a plurality of data electrodes are provided on the other surface side, and EL elements are formed at positions where these scanning electrodes and data electrodes overlap. The present invention relates to an EL display device including a type EL display panel.

  FIG. 5 shows a schematic electrical configuration of a conventional EL display device. The EL display device 1 includes an EL display panel 2 and a drive device 3. In the dot matrix type EL display panel 2, in general, the scanning electrode 4 has a smaller number of vertical and horizontal pixels (usually vertical: rows) and the data electrode 5 has a larger number (usually horizontal: columns) depending on the number of display pixels. The EL element 6 is formed at the intersection of the scanning electrode 4 and the data electrode 5. In FIG. 5, only the 12 × 4 pixel portion of the EL display panel 2 is shown, but actually more pixels, for example, 600 × 800 pixels are formed.

  The driving device 3 includes a scanning side driver IC 7 that drives the scanning electrode 4, a data side driver IC 8 that drives the data electrode 5, and the like. The scanning-side driver IC 7 and the data-side driver IC 8 that are used for general purposes incorporate a predetermined number of driving circuits (number of output channels), and the number of scanning electrodes 4 and the number of output channels of the scanning-side driver IC 7 ( = The number of drive circuits) determines the number of scanning side driver ICs 7 to be used, and the number of data electrodes 5 and the number of output channels of the data side driver IC 8 determine the number of data side driver ICs 8 to be used.

  For example, when the number of pixels of the EL display panel is 600 × 800 and the number of output channels of the scanning side driver IC 7 and the data side driver IC 8 is 60 channels and 160 channels, respectively, 10 scanning side driver ICs 7 and 5 data side driver ICs 8 are provided. I need one. However, since the scanning-side driver IC 7 requires a higher breakdown voltage than the data-side driver IC 8, when the number of scanning-side driver ICs 7 used increases, the cost of the driving device 3 and hence the EL display device 1 increases accordingly. Furthermore, as the definition of the EL display panel 2 increases, an increase in the number of scanning electrodes causes a decrease in the scanning speed (driving frequency) of one screen, resulting in a problem that luminance decreases.

As means for solving such a problem, there is a display device disclosed in Patent Document 1. This display device is called a so-called vertical division drive system (dual scan system), and has a structure in which the data electrodes of the display panel are divided into upper and lower parts, and a data driver is provided independently on the upper and lower sides, thereby scanning one screen. The (driving frequency) is halved from the conventional one. In this document, the number of scanning side driver ICs required is halved by pairing the upper and lower scanning electrodes.
JP-A-61-252582

  However, in the display device described in the above literature, when uneven film thickness occurs in the film formation on the upper half surface and lower half surface of the EL display panel, the load (capacitance component) of the upper and lower data drivers becomes different, and the upper half surface A luminance difference is produced between the lower half surface and the lower half surface. Even if this luminance difference is slight, it is displayed side by side in the panel surface, so that it is visually recognized by the user as a significant luminance difference. Further, in the display device described in the above document, the effect of improving the screen scanning speed and reducing the number of scanning side driver ICs used is limited to twice.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an EL display device capable of increasing luminance and reducing cost.

  According to the means described in claim 1, each of the scanning electrodes simultaneously drives a plurality of consecutive rows (N rows: N ≧ 2) of EL elements (pixels). The rows driven by the different scan electrodes are different from each other. Since EL elements driven simultaneously by the same scan electrode are connected to different data electrodes, independent light emission is possible for each EL element. In other words, the EL elements (pixels) arranged in rows in the vertical direction are divided into pixel groups composed of N consecutive EL elements, and the EL elements belonging to the same pixel group are connected to different data electrodes. Yes. Each EL element belonging to a different pixel group is typically connected to a corresponding data electrode.

  If the number of rows of pixels of the EL display panel is n and the number of columns is m, the number of scanning electrodes, that is, the number of channels of the scanning side drive circuit required for driving the scanning electrodes, is n / N (when a remainder occurs) N / N + 1), which is 1 / N of the number of scanning electrodes (= number of channels of the scanning side drive circuit) n required conventionally. According to this means, since the number of scanning electrodes becomes 1 / N, the scanning speed (driving frequency, scanning frequency) of one screen, and hence the luminance can be increased. Further, since the number of channels of the scanning side driving circuit having a high withstand voltage and high cost becomes 1 / N, the number of scanning side driver ICs having a plurality of scanning side driving circuits built therein can be reduced, and the cost of the EL display device can be reduced. Can be reduced. Furthermore, the degree of freedom of the number of driver ICs used in designing increases.

  According to the means described in claim 2, the scanning electrode is formed so as to include all EL elements existing in a plurality of continuous rows. The data electrode element forming portion and the EL light emitting layer are formed corresponding to the positions and shapes of the EL elements arranged in a matrix. Thus, by providing (patterning) the EL light emitting layer at the position where the scanning electrode and the data electrode element formation portion overlap, light emission at the data electrode connecting portion can be prevented. Of the data electrodes, a portion for sequentially connecting element forming portions of EL elements driven by different scanning electrodes is formed as a connecting portion.

  According to a third aspect of the present invention, the connection portion of the data electrode is a boundary between a group of EL elements driven by one scanning electrode and a group of EL elements driven by the scanning electrode adjacent to the scanning electrode. The element forming portions of the data electrodes corresponding to the EL elements having a symmetrical arrangement (that is, mirror inversion arrangement) are connected with the line as the axis of symmetry. As a result, the data electrodes can be formed planarly so as not to intersect.

  According to the means described in claim 4, since the data electrode is constituted by the transparent conductive film having a sufficient film thickness in order to prevent the resistance of the portion of the data electrode where the wiring width is reduced (for example, the connection portion) from being increased. The desired brightness can be ensured.

  According to the means described in claim 5, since the data electrode is composed of a metal film or a metal film and a transparent conductive film, the resistance can be reduced as compared with the case where only the transparent conductive film is used. And higher luminance can be obtained.

  According to the means described in claim 6, since the data electrode can be taken out from one side of the EL display panel, the frame area of the EL display panel can be reduced, and the size of the EL display panel can be reduced accordingly. it can.

  According to the means described in claim 7, by setting the number N of simultaneously driven rows by the scanning electrodes to 2 or 3, a particularly large brightness improvement effect and cost reduction effect can be obtained. That is, when the number N of simultaneously driven rows is increased, the capacity to be driven by the scanning side drive circuit also increases. Therefore, there is a limit point where the luminance cannot be increased even if the scanning speed of one screen is increased. Further, when the number of simultaneously driven rows N is increased, the number of channels of the scanning side drive circuit is increased by 1 / N, while the number of channels of the data side drive circuit is increased by N times. There is a minimum of cost. In consideration of these, in the case of the number of commonly used pixels (as an example, 600 × 800) and the number of commonly used scanning side driver IC and data side driver IC channels (as an example, 60 channels, 160 channels), N = 2. Or about N = 3 is the most effective.

An embodiment in which an EL display device according to the present invention is applied to a dot matrix inorganic EL display device will be described below with reference to FIGS.
FIG. 1 shows a planar arrangement structure of scan electrodes and data electrodes in an EL display panel, and shows a schematic electrical configuration of the EL display device. The EL display device 11 includes an EL display panel 12 and a driving device 13. The EL display panel 12 includes a plurality of scanning electrodes 14 extending in the horizontal direction and having a row, and a plurality of scanning electrodes 14 extending in the vertical direction. A data electrode 15 is formed. In the following description, when it is necessary to distinguish each scanning electrode 14, reference numerals 14 (1), 14 (2), 14 (3), and 14 (4) are used to distinguish each data electrode 15. If there is, 15 (1), 15 (2),..., 15 (12) are used.

  An EL element 16 serving as a pixel is formed at a position where the scanning electrode 14 and the data electrode 15 (more precisely, an element forming portion 15a described later) overlap. The actual EL display panel 12 has more electrodes than those shown in FIG. 1, for example, 200 scanning electrodes 14 and 2400 data electrodes 15. In this case, a display panel having 600 × 800 pixels is provided. can get. In the plan view shown in FIG. 1, since the EL element 16 and the element forming portion 15a appear to overlap each other, two reference numerals 15a and 16 are given to the pixel forming positions.

  FIG. 4 is a diagram schematically showing an AA cross section of the EL display panel 12 in FIG. The EL element 16 includes a glass substrate 17 which is an insulating substrate, a scanning electrode 14 (first electrode), a first insulating layer 18, a light emitting layer 19, a second insulating layer 20, a data electrode 15 (second electrode), a cover glass. 21 are sequentially laminated. The data electrode 15 shown in FIG. 4 is an element forming portion 15a, and the connecting portion 15b is omitted. In the actual EL display panel 12, the scanning electrode 14, the first insulating layer 18, the light emitting layer 19, the second insulating layer 20, and the data electrode 15 are extremely thin with respect to the glass substrate 17 and the cover glass 21.

Of the scanning electrode 14, the first insulating layer 18, the second insulating layer 20, and the data electrode 15, at least the light extraction side (display side: usually the cover glass side) is made of a light-transmitting material. In the present embodiment, the first insulating layer 18 and the second insulating layer 20 are made of an Al ₂ O ₃ / TiO ₂ laminated structure film (ATO film) in which Al ₂ O ₃ layers and titanium oxide TiO ₂ layers are alternately laminated. The scanning electrode 14 and the data electrode 15 are configured by a transparent conductive film such as an ITO (Indium Tin Oxide) film.

  As shown in FIG. 1, the scanning electrodes 14 are not provided for each row of the EL elements 16 arranged in a matrix, but are provided for every three consecutive rows (simultaneous. Number of driving rows N = 3). That is, the scanning electrode 14 (1) is formed in a horizontally long rectangular shape so as to include all 12 (2400 in the case of 600 × 800 pixels) EL elements 16 existing from the first row to the third row. 12 adjacent to the scanning electrode 14 (1), there are 12 other scanning electrodes 14 (2) from the fourth row to the sixth row (2400 in the case of 600 × 800 pixels). ) So as to include all the EL elements 16. The same applies to the other scanning electrodes 14 (3) and 14 (4).

  In such a configuration, the EL elements 16 for three rows are simultaneously driven by one scanning electrode 14. In this case, each EL element 16 is connected to a different data electrode 15 so that each EL element 16 driven simultaneously can emit light independently. The EL elements 16 driven by the scanning electrodes 14 are connected to the EL elements 16 driven by the other scanning electrodes 14 via the data electrodes 15 respectively. That is, three (= N) data electrodes 15 are required to drive the EL elements 16 forming one column.

  Each data electrode 15 includes a rectangular element forming portion 15a formed in accordance with a matrix-like arrangement position of the EL elements 16, and an element forming portion 15a of the EL elements 16 driven by different scanning electrodes 14. It is comprised from the linear connection part 15b connected to a vertical direction sequentially. This is different from the data electrode 5 (see FIG. 5) extending linearly with a constant width in the vertical direction as in the conventional EL display panel 2.

  In order to prevent the connecting portions 15b from crossing each other, the connecting portion 15b includes a group of EL elements 16 driven by one scanning electrode 14 (for example, 14 (1)) and a scanning electrode 14 (for example, 14 adjacent to the scanning electrode 14). The element forming portions 15a corresponding to the EL elements 16 having a symmetrical arrangement (that is, mirror inversion arrangement) are connected to each other with the boundary line with the group of EL elements 16 driven by (2)) as the axis of symmetry. Is formed. In FIG. 1, for each column, the EL elements 16 in the first, sixth, seventh, and twelfth lines, the second, fifth, eighth, and eleventh EL elements 16, 3 The EL elements 16 in the rows, the fourth row, the ninth row, and the tenth row are driven by the same data electrode 15, respectively.

  In the case of the conventional EL display device 1 (see FIG. 5), the light emitting layer is formed over the entire surface of the EL display panel 2. However, in the EL display device 11 of the present embodiment, there is a portion where the scanning electrode 14 and the data electrode 15 (connecting portion 15b) overlap in addition to the formation position of the EL element 16, and thus the light emitting layer 19 is provided on the entire panel surface. If provided, light is emitted at the overlapping portion. Therefore, the light emitting layer 19 is provided only at a position where the scanning electrode 14 and the element forming portion 15a of the data electrode 15 overlap by patterning. Thereby, it is possible to prevent light emission other than the pixel portions arranged in a matrix.

  However, if the light emitting layer 19 does not exist in the portion where the scanning electrode 14 and the data electrode 15 (connecting portion 15b) overlap, all the voltages between the two electrodes are applied to the first insulating layer 18 and the second insulating layer 20. Therefore, it is necessary to design a film in consideration of this point. Further, since the connection portion 15b of the data electrode 15 has a reduced wiring width and an increased resistance, it is preferable to determine the film pressure of the ITO film while taking into account a decrease in luminance.

  In FIG. 1, each scanning electrode 14 is connected from the left end of the EL display panel 12 to an output terminal of a scanning driver IC 22 mounted on a substrate (not shown) through an FPC (Flexible Printed Circuit). . FIG. 2 shows the electrical configuration of the scanning-side driver IC 22 and the scanning voltage supply circuits 28 and 29 that incorporate four drive circuits. In practice, a scanning-side driver IC having a larger number (for example, 60 channels) of driving circuits is used.

  As shown in FIG. 2, each driving circuit built in the scanning side driver IC 22 is a push-pull circuit including a P-channel FET 23 and an N-channel FET 24 connected to the scanning electrode 14. A scanning voltage is applied to each scanning electrode 14 in accordance with the driving signal. Diodes 26 and 27 having the polarities shown are connected to the FETs 23 and 24, respectively.

  The scanning voltage supply circuits 28 and 29 supply a scanning voltage to the scanning side driver IC 22. The scanning voltage supply circuit 28 includes switching elements 30 and 31 and supplies the write voltage Vr or the ground voltage 0 V to the positive voltage power supply line L1 of the scanning side driver IC 22 according to the on / off state. ing. On the other hand, the scanning voltage supply circuit 29 includes switching elements 32 and 33, and applies a voltage (−Vr + Vm) or an offset voltage (Vm) to the negative voltage power supply line L2 of the scanning side driver IC 22 according to the on / off state. It comes to supply.

  On the other hand, in FIG. 1, each data electrode 15 is connected to the output terminal of a data side driver IC 34 mounted on a substrate (not shown) from above the EL display panel 12 via the FPC. FIG. 3 shows an electrical configuration of a data side driver IC incorporating four drive circuits. Actually, a data-side driver IC having a larger number (for example, 160 channels) of driving circuits is used.

  As shown in FIG. 3, each drive circuit built in the data side driver IC 34 is also a push-pull circuit composed of a P-channel FET 35 and an N-channel FET 36 connected to the data electrode 15, from the control circuit 37. A data voltage is applied to each data electrode 15 in accordance with the drive signal. Diodes 38 and 39 having polarities shown in the figure are connected to the FETs 35 and 36, respectively. A DC voltage (modulation voltage) Vm is supplied to the source side common line of the FET 35, and a ground voltage 0 V is supplied to the source side common line of the FET 36.

Next, the operation of this embodiment will be described.
First, a method for driving the positive field will be described. During the positive field drive period, the switching elements 30 and 33 are turned on, and the switching elements 31 and 32 are turned off. At this time, the power supply line L1 of the scanning side driver IC 22 is at the write voltage Vr, and the power supply line L2 is at the offset voltage Vm. Further, all the FETs 35 in the data side driver IC 34 are turned on. As a result, all the scan electrodes 14 become the offset voltage Vm by the action of the diode 27, and all the data electrodes 15 become the offset voltage Vm through the FET 35. In this state, the drive voltage of all the EL elements 16 is 0 V and no light is emitted.

  Thereafter, the driving FET 23 of the scanning electrode 14 (1) in the scanning driver IC 22 is turned on, and the voltage of the scanning electrode 14 (1) is set to the writing voltage Vr. At this time, the other scanning electrodes 14 (2) to 14 (4) are in a floating state by holding all the driving FETs 23 and 24 in the OFF state.

  On the other hand, each of the three data-side driver ICs 34 existing in FIG. 1 emits light among the three rows of EL elements 16 (12 in FIG. 1) located on the scanning electrode 14 (1) based on the display data. The FET 35 connected to the data electrode of the EL element to be turned off is turned off, and the FET 36 is turned on. Further, the FET 35 connected to the data electrode of the EL element that does not emit light is held in the on state, and the FET 36 is held in the off state. Data corresponding to the wiring pattern of the scanning electrode 14 and the data electrode 15 is transmitted to the data side driver IC 34.

  As a result, the EL element that emits light emits light when the voltage of the data electrode becomes the ground voltage and a voltage Vr higher than the light emission threshold voltage Vth is applied between the electrodes. Further, the EL element that does not emit light does not emit light because the voltage of the data electrode becomes the offset voltage Vm and a voltage (Vr−Vm) lower than the emission threshold voltage Vth is applied between the electrodes.

  After that, the driving FET 23 of the scanning electrode 14 (1) is turned off to place the scanning electrode 14 (1) in a floating state, and then the driving FET 24 of the scanning electrode 14 (1) is turned on, whereby the scanning electrode 14 ( 1) All the above EL elements 16 (12 in FIG. 1) are set to emit no light. In this case, the FETs 35 and 36 connected to the data electrodes of the emitted EL elements are maintained in an off state and an on state, respectively, for a predetermined time. Thereafter, the scanning electrodes 14 (2) to 14 (4) are similarly driven.

When the positive field driving is completed, the negative field driving is performed.
During the negative field drive period, the switching elements 30 and 33 are turned off, and the switching elements 31 and 32 are turned on. At this time, the power supply line L1 of the scanning driver IC 22 is at the ground voltage, and the power supply line L2 is at the offset voltage (−Vr + Vm). Further, all the FETs 36 in the data side driver IC 34 are turned on. As a result, all the scanning electrodes 14 and all the data electrodes 15 are at the ground voltage. In this state, the drive voltage of all the EL elements 16 is 0 V and no light is emitted.

  Thereafter, the driving FET 24 of the scanning electrode 14 (1) in the scanning side driver IC 22 is turned on, and the voltage of the scanning electrode 14 (1) is set to (−Vr + Vm). At this time, the other scanning electrodes 14 (2) to 14 (4) are in a floating state by holding all the driving FETs 23 and 24 in the OFF state.

  On the other hand, in each data-side driver IC 34, the data electrodes of the EL elements that emit light among the three rows of EL elements 16 (12 pieces in FIG. 1) positioned on the scanning electrode 14 (1) based on the display data. The connected FET 35 is turned on and the FET 36 is turned off. Further, the FET 35 connected to the data electrode of the EL element that does not emit light is held in the off state, and the FET 36 is held in the on state.

  As a result, the EL element that emits light emits light when a voltage −Vr whose absolute value exceeds the light emission threshold voltage Vth is applied between the electrodes. Further, an EL element that does not emit light does not emit light because a voltage (−Vr + Vm) whose absolute value is lower than the light emission threshold voltage Vth is applied between the electrodes. After that, the drive FET 24 of the scan electrode 14 (1) is turned off to place the scan electrode 14 (1) in a floating state, and then the drive FET 23 of the scan electrode 14 (1) is turned on, whereby the scan electrode 14 ( 1) All the above EL elements 16 (12 in FIG. 1) are set to emit no light. In this case, the FETs 35 and 36 connected to the data electrodes of the light-emitting EL elements are maintained in an on state and an off state, respectively, for a predetermined time. Thereafter, the scanning electrodes 14 (2) to 14 (4) are similarly driven.

According to this embodiment, the following effects can be obtained.
If the number of rows of pixels of the EL display panel is n and the number of columns is m, the number of scanning electrodes, that is, the number of channels of the scanning side drive circuit required when driving the scanning electrodes 14 is n / N, and the number of data electrodes That is, the number of channels of the data side driving circuit required when driving the data electrode 15 is N × n. The same 12 × 4 pixels are shown in the EL display device 11 shown in FIG. 1 and the EL display device 1 shown in FIG. 5. In the EL display device 11, three rows of scanning electrodes 14 are continuous (N = 3). The number of the scanning side driver ICs 22 and the number of the data side driver ICs 34 incorporating the four-channel driving circuits is 1/3 times that of the EL display device 1 (that is, one). ) 3 times (that is, 3).

  As a result, as a first effect, the scanning speed (driving frequency, scanning frequency) of one screen can be increased by reducing the number of scanning electrodes to 1 / N, and thereby the emission luminance can be increased. However, in the present embodiment in which the scanning electrodes 14 drive the EL elements 16 in a plurality of rows (N rows: N ≧ 2), the capacity to be driven by the scanning side drive circuit is almost N times, so that the scanning speed of one screen There is a limit point where the luminance cannot be increased even if the value is increased.

  As a second effect, the number of scanning side driver ICs 22 can be reduced by reducing the number of scanning electrodes to 1 / N, and thus the cost of the EL display device 11 can be reduced. The write voltage Vr for the EL element 16 needs to be about 200 V, and this voltage is output from the scanning side driver IC 22. For this reason, the scanning-side driver IC 22 requires a higher withstand voltage than the data-side driver IC 34, and the cost of components is accordingly high at present. According to this embodiment, the cost of the scanning side driver IC 22 can be reduced to approximately 1 / N.

  However, while the number of scanning electrodes is 1 / N times, the number of data electrodes, that is, the number of channels of the data side drive circuit is N times, the cost of the EL display device 11 decreases as the number N of simultaneously driven rows increases. It will not be. Further, if the drive capability of the scan side driver IC 22 is increased in order to cope with an increase in the load on the scan electrode 14, the cost increases. Therefore, there is a minimum point where the cost is most reduced when the number N of simultaneously driven rows is increased.

  Considering these, in the case of the number of commonly used pixels (as an example, 600 × 800) and the number of channels of the commonly used scanning side driver IC 22 and data side driver IC 34 (as an example, 60 channels, 160 channels), the scanning electrode 14 Is configured to drive the EL elements 16 of two consecutive rows (N = 2) or three rows (N = 3) at the same time, and is expected to be most effective in improving luminance and reducing costs. . However, this is a trial calculation based on the number of channels, drive capability, and cost of currently used driver ICs. If these circumstances change, the effective number of simultaneously driven rows N is 4, 5 ,... Or 10 or more.

  The data electrode 15 sequentially arranges EL elements 16 in a symmetrical arrangement (that is, mirror inversion arrangement) with respect to the EL element 16 formed on the adjacent scan electrode 14 with the boundary line between the two scan electrodes 14 as the axis of symmetry. Since the connection is made, the data electrodes 15 can be formed in a plane so as not to intersect as shown in FIG. Further, if such data electrode 15 is adopted, the data electrode 15 can be taken out from only one side of the EL display panel 12, so that the frame area of the EL display panel 12 can be reduced, and the size of the EL display panel 12 can be reduced accordingly. Can be reduced. Further, unlike the vertical division driving method, the data electrode 15 is not divided in the middle of the column direction, so that there is no problem of luminance difference at the center of the panel.

The present invention is not limited to the embodiment described above and shown in the drawings. For example, the present invention can be modified or expanded as follows.
The present invention can be applied to a passive driving device and an active driving device for organic EL and inorganic EL, respectively.
In the stacked structure shown in FIG. 4, the first electrode may be the data electrode 15 and the second electrode may be the scanning electrode 14.

In the above-described embodiment, the scanning electrodes 14 are all configured to drive the EL elements 16 for three rows at the same time. However, the scanning elements 14 may be configured to simultaneously drive different numbers of EL elements 16 for each scanning electrode 14.
The data electrode 15 may be extracted from a plurality of sides (for example, an upper side and a lower side) of the EL display panel 12.
Since the connection portion 15b of the data electrode 15 has a reduced wiring width and increased resistance, the data electrode 15 is formed of a metal film or a metal film and a transparent conductive film (ITO film) in order to obtain higher luminance. May be.

FIG. 2 is a diagram illustrating a planar arrangement structure of scan electrodes and data electrodes in an EL display panel and a schematic electrical configuration of an EL display device according to an embodiment of the present invention. The figure which shows the electrical structure of a scanning side driver IC and a scanning voltage supply circuit The figure which shows the electrical constitution of data side driver IC The figure which shows the structure of the AA cross section in FIG. 1 typically 1 equivalent diagram showing the prior art

Explanation of symbols

  11 is an EL display device, 12 is an EL display panel, 14, 14 (1), 14 (2), 14 (3), 14 (4) are scanning electrodes, 15, 15 (1), 15 (2),. , 15 (12) is a data electrode, 15a is an element forming portion, 15b is a connecting portion, 16 is an EL element, and 19 is a light emitting layer (EL light emitting layer).

Claims (7)

A dot matrix type EL display in which a plurality of scanning electrodes are provided on one surface side of an EL light emitting layer, a plurality of data electrodes are provided on the other surface side, and EL elements are formed at positions where these scanning electrodes and data electrodes overlap. In an EL display device comprising a panel, and configured to selectively emit light by applying a scanning voltage and a data voltage to the scanning electrode and the data electrode, respectively,
Each scan electrode is formed so that a plurality of rows of EL elements can be driven simultaneously,
An EL display device, wherein EL elements driven by the same scanning electrode are connected to different data electrodes. Each of the scanning electrodes is composed of electrodes including all EL elements existing in a plurality of continuous rows,
Each of the data electrodes is composed of an element forming part formed in accordance with the arrangement position of the EL element and a connection part for sequentially connecting element forming parts of EL elements driven by different scanning electrodes.
2. The EL display device according to claim 1, wherein an EL light emitting layer is formed at a position where the scanning electrode and the element forming portion of the data electrode overlap each other.   The connection portion of the data electrodes has a symmetrical arrangement with a boundary line between a group of EL elements driven by one scan electrode and a group of EL elements driven by a scan electrode adjacent to the scan electrode as an axis of symmetry. The EL display device according to claim 2, wherein element formation portions of the data electrodes corresponding to the EL elements are connected to each other.   4. The EL display device according to claim 1, wherein the data electrode is made of a transparent conductive film having a film thickness sufficient to ensure a predetermined luminance.   4. The EL display device according to claim 1, wherein the data electrode is formed of a metal film or a metal film and a transparent conductive film.   6. The EL display device according to claim 1, wherein the data electrode is formed so as to be taken out from one side of the EL display panel. 7. The EL display device according to claim 1, wherein each scanning electrode is formed so as to be able to simultaneously drive two consecutive rows of EL elements or three consecutive rows of EL elements. 8.

Images