JP2728567B2 - Aging method of EL panel - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of aging a thin film EL panel having electrodes having a matrix structure, and more particularly to a method of aging a thin film EL panel in which one electrode group is formed of a resistor such as a transparent electrode.

[0002]

2. Description of the Related Art FIG. 2 is a perspective view showing the structure of a thin-film EL panel 11 having a double insulating film structure. As shown in FIG. 2, the thin-film EL panel 11 having a double insulating film structure
A plurality of strip-shaped transparent electrodes 2 made of ITO (Indium Tin Oxide) or the like are provided in parallel, a dielectric material layer 3 such as silicon nitride (Si ₃ N ₄ ) and an active material such as manganese (Mn) are formed thereon. EL layer 4 made of zinc sulfide (ZnS) doped with N and a dielectric material layer 5 made of silicon nitride (Si ₃ N ₄ ) are formed by a vacuum deposition method, a sputtering method, or the like to form a three-layer structure. Further, a plurality of strip-shaped metal electrodes 6 made of a metal such as aluminum (Al) are provided in parallel on the dielectric material layer 5 in a direction orthogonal to the transparent electrode 2. The thin film EL panel 11 having such a structure is a capacitive element in terms of an equivalent circuit, and is sandwiched between intersections of both electrodes by applying a predetermined alternating voltage to a desired transparent electrode and a metal electrode. The small area portion emits light to constitute one picture element for displaying characters, symbols, patterns, and the like.

A thin film E based on the structure shown in FIG.
The L panel 11 is used for the purpose of stabilizing a change with time in light emission luminance and the like, and removing a defective element due to an initial failure.
It is necessary to perform the aging process while applying an AC voltage between the transparent electrode group 2 and the metal electrode group 6 for a certain period after the production of the thin film EL panel. In this aging process, in order to simplify the aging drive circuit and the necessity of simultaneously processing display picture elements, as shown in FIG. 8, the transparent electrodes 2 drawn in one direction are combined into one common electrode. Further, the metal electrodes 6 on the opposite side are combined into one common electrode to form a set of common electrodes. As shown in FIG. 8, the aging drive circuit 21
Aging is performed by applying an AC voltage pulse and causing all the intersections (picture elements) to emit light at the same time.

[0004]

FIG. 9 is a diagram showing an equivalent circuit of an EL panel. FIG. 9A is an equivalent circuit of one picture element, where C represents the capacity of the light emitting picture element, and R represents the resistance value of the transparent electrode. FIG. 9B is a diagram illustrating an equivalent circuit when a plurality of picture elements are arranged. In order to perform the aging process on such a picture element, a voltage VD is applied.

When the display capacity is small, the time constant CR is small with respect to the applied pulse width.
As shown in FIG. 10A, a predetermined waveform is applied.
However, when the display capacitance increases and the time constant CR becomes larger than the pulse width, a predetermined waveform is not applied to the portion of the transparent electrode remote from the terminal portion, as shown in FIG. 10B. The pulse width cannot be increased more than necessary due to other characteristics.
The problem arises that not all picture elements can be aged uniformly.

In order to solve the above problems, the present inventors have proposed the following aging method. In this aging method, as shown in FIG. 1, all the transparent electrodes 2 are short-circuited, and every other metal electrode 6 is short-circuited to form two metal electrode groups 6A and 6B. 6
By applying a voltage to the transparent electrode 2 at the same potential at both ends of A and 6B, all the picture elements formed by the metal electrode group and the transparent electrode group are charged to the same polarity. Next, by setting the transparent electrode group in a floating state and applying a voltage between the terminals of the metal electrode group, the charges accumulated in the pixels on one metal electrode group are transferred to the pixels on the other metal electrode group. To cause the picture element to emit light.

In the above-described aging method, the current flowing when a pulse is applied flows from one metal electrode group to the other metal electrode group, and is not affected by the electrode resistance of the transparent electrode 2. Therefore, it is effective as an aging drive method for an EL panel having a large area and a large display capacity.

The above-mentioned aging driving method will be described in detail with reference to FIGS. 1, 3 and 11. Here, FIG. 3 is a circuit diagram showing the configuration of the aging drive circuit, and FIG.
Is a timing chart for explaining the aging driving method.

In FIG. 3, a capacitor ELA represents a picture element of the EL panel 11 formed by the odd-numbered metal electrode group 6A and the transparent electrode group 2, and a capacitor ELB represents an even-numbered metal electrode group 6B and the transparent electrode group. 2 represent the picture elements of the EL panel 11 formed by the above. Each of the switching circuits TH1 to TH6 includes a thyristor, and includes a thyristor control circuit that controls the thyristor so as to be turned on / off in response to control signals S1 to S6 from the control circuit 9.

The switching circuit TH1 is a circuit for applying a voltage (supplying a charge) to the odd-numbered metal electrode group 6A, and the switching circuit TH2 is for grounding (discharging the charge) the odd-numbered metal electrode group 6A. Circuit. The switching circuit TH3 is a circuit for applying a voltage to the even-numbered metal electrode group 6B.
Reference numeral 4 denotes a circuit for grounding the even-numbered metal electrode group 6B. The switching circuit TH5 is a circuit for applying a voltage to the transparent electrode group 2, and the switching circuit TH6 is a circuit for grounding (discharging) the transparent electrode.
Further, diodes D1 to D6 are connected in relation to the switching circuits TH1 to TH6, respectively, in order to prevent backflow of current (charge).

FIGS. 11 (1) to 11 (6) show ON / OFF states of the switching circuits TH1 to TH6 shown in FIG. 3, and FIGS. 11 (7) and 11 (8) show picture elements E.
The voltage waveforms applied to LA and ELB are shown. The aging driving method described above is a driving method in which four fields are repeated as one set as shown in FIG.

In the first field, the metal electrode groups 6A and 6A
After applying a voltage VD equal to or lower than the light emission start voltage to B, using the transparent electrode group 2 as a reference potential, the transparent electrode group 2 is brought into a floating state, and a voltage VD is applied to the metal electrode group 6A using the metal electrode group 6B as a reference potential. . In the second field, after applying the voltage VD to the metal electrode groups 6A and 6B using the transparent electrode group 2 as a reference potential, the transparent electrode group 2 is brought into a floating state, and the voltage is applied to the metal electrode group 6B using the metal electrode group 6A as a reference potential. Apply VD. In the third field, the applied voltage has a polarity opposite to that of the first field, and in the fourth field, the applied voltage has polarity opposite to that of the second field.

Of the four fields described above, a voltage pulse higher than the light emission start voltage is applied to the odd electrode side in the first and third fields, but is lower than the light emission start voltage in the second field and the fourth field. Is applied. Similarly, on the even-numbered electrode side, a voltage pulse equal to or higher than the light emission start voltage is applied in the second field and the fourth field, but only a voltage pulse equal to or lower than the light emission start voltage is applied in the first field and the third field.

FIG. 12 is a waveform diagram showing a drive pulse waveform of the EL light emitting element. FIG. 12 (1) shows a basic drive pulse waveform, and FIGS. 12 (2) and 12 (3).
Shows a waveform when a pulse equal to or lower than the light emission start voltage is inserted between the drive pulses. Here, in FIG. 12 (2), the insertion pulse has the same polarity as the immediately preceding drive pulse, and in FIG. 12 (3), the insertion pulse has the opposite polarity to the immediately preceding drive pulse.

FIG. 13 is a graph showing a voltage-luminance characteristic when the EL light emitting element is driven by each drive pulse shown in FIG. In FIG. 13, a solid line L1 corresponds to FIG.
FIG. 12C is a characteristic curve when the drive pulse shown in FIG. 12A is used, a dashed line L2 is a characteristic curve when the drive pulse shown in FIG. 12B is used, and a broken line L3 is shown in FIG. It is a characteristic curve at the time of using the drive pulse shown.

As shown in FIG. 13, when the driving pulses shown in FIGS. 12 (2) and 12 (3) are used, compared with the case where the basic driving pulse shown in FIG. 12 (1) is used, The emission intensity is slightly reduced. In particular, when the insertion pulse has a polarity opposite to that of the immediately preceding drive pulse, the influence is great. As described above, in the driving method in which a pulse having a voltage lower than the light emission start voltage is inserted while a pulse having the voltage higher than the light emission start voltage is repeated, the light emission intensity usually decreases.

This is believed to be due to the following reasons. The EL element is a capacitive element, and a light-emitting current flows in the light-emitting layer when an applied voltage that is equal to or higher than the light-emission starting voltage, and as a result, polarization is formed. This polarization remains until the next application of the reverse polarity pulse and is applied to the light emitting layer in a manner superimposed on the external voltage, so that efficient light emission can be obtained even with a low applied voltage.

However, if there is an insertion pulse, small light emission occurs due to a low applied voltage, and the polarization becomes small.
Therefore, even if a high voltage pulse is applied thereafter, sufficient polarization cannot be obtained because the superposed polarization is small. As described above, although the number of light emission is increased by the insertion pulse, the polarization effect is reduced, so that the light emission intensity is reduced as a whole. When the emission intensity decreases, it takes time to stabilize the luminance characteristics, which is the purpose of the aging process.

It is an object of the present invention to provide an aging method for an EL panel which can perform a reliable aging process even for a large-sized and large-capacity EL panel.

[0020]

SUMMARY OF THE INVENTION According to the present invention, all of the above-mentioned transparent electrode groups of an EL panel having an EL light emitting layer interposed between a transparent electrode group and a metal electrode group which intersect each other are short-circuited. The first and second metal electrode groups were formed by short-circuiting every other group, and a voltage equal to or lower than the light emission start voltage of the EL light emitting layer was applied to the first and second metal electrode groups using the transparent electrode group as a reference potential. Thereafter, the first field in which the transparent electrode group is brought into a floating state and a voltage equal to or lower than the light emission start voltage is applied to the first metal electrode group with the second metal electrode group as a reference potential; A first period in which the field and a second field of opposite polarity are repeated;
After applying a voltage equal to or lower than the emission start voltage of the EL light emitting layer to the first and second metal electrode groups with the transparent electrode group as a reference potential, the transparent electrode group is brought into a floating state, and the first metal electrode group is set as a reference potential. A second field in which a voltage equal to or lower than the light emission start voltage is applied to the two metal electrode groups, and a second period in which a fourth field in which the voltage equal to or lower than the light emission start voltage has a polarity opposite to that of the third field are set. , First
An aging method for an EL panel, wherein a period and a second period are repeated at a predetermined cycle.

[0021]

According to the present invention, the picture element formed by the first metal electrode group and the transparent electrode group (hereinafter referred to as the picture element of the first metal electrode group) is composed of the first field of the first period and the second field. A pixel that emits light by applying a voltage equal to or higher than the emission start voltage of the EL light emitting layer in the field and is formed by the second metal electrode group and the transparent electrode group (hereinafter, referred to as a pixel of the second metal electrode group) In the third and fourth fields of the second period, light is emitted by applying a voltage equal to or higher than the light emission start voltage of the EL light emitting layer.

That is, in the first field, after a voltage VD equal to or lower than the light emission start voltage is applied to the first and second metal electrode groups using the transparent electrode group as a reference potential, the transparent electrode group is brought into a floating state. Since the voltage VD is applied to one metal electrode group with the second metal electrode group as a reference potential, (1 + α) · VD is applied to the picture elements of the first metal electrode group.
Is applied, and this voltage is equal to or higher than the light emission start voltage, so that the picture elements of the first metal electrode group emit light.

Here, assuming that the pixel capacitance at the time of no light emission is C _OFF and the pixel capacitance at the time of light emission is C _ON , the constant α
Is represented by Equation 1 below.

[0024]

Α = (2 · C _OFF −C _ON ) / (C _OFF + C _ON ) The second field is the same as the first field except that the polarity of the applied voltage VD is reversed. A voltage of-(1 + α) · VD is applied to the picture elements of one metal electrode group. Therefore, in the first period, the first field and the second field are repeated, so that a voltage pulse equal to or higher than the light emission start voltage is continuously applied to the picture elements of the first metal electrode group.

Similarly, since the third field and the fourth field are repeated in the second period, a voltage pulse equal to or higher than the light emission start voltage is continuously applied to the picture elements of the second metal electrode group. .

On the other hand, in the picture element of the first metal electrode group, only a voltage pulse equal to or lower than the light emission start voltage is applied in the second period, and in the second metal electrode group, the picture element of the first metal electrode group is lower than the light emission start voltage in the first period. Is applied, but during the light emission period of each picture element, the frequency is twice the light emission frequency in the conventional aging drive method. Therefore, by averaging the first and second periods, the light emission of each picture element is obtained. The number of times is the same as before.

[0027]

FIG. 1 is a plan view of an EL panel 11 to which the aging method of the present invention is applied, and FIG.
1 is a perspective view of FIG.

The thin-film EL panel 11 having a double insulating film structure
As shown in FIG. 2, an ITO (Indi)
um Tin Oxide), a plurality of strip-shaped transparent electrodes 2 are provided in parallel, and silicon nitride (Si
₃ N ₄₎ and dielectric material layer 3 such as, EL consisting manganese (Mn) doped zinc sulfide active substances such as (ZnS)
A light emitting layer 4 and a dielectric material layer 5 made of silicon nitride (Si ₃ N ₄ ) or the like are formed by a vacuum deposition method, a sputtering method, or the like to form a three-layer structure.
Aluminum (A) in a direction orthogonal to the transparent electrode 2
A plurality of strip-shaped metal electrodes 6 made of a metal such as l) are provided in parallel. Thin film EL panel 1 having such a structure
Numeral 1 denotes a capacitive element in terms of an equivalent circuit. By applying a predetermined alternating voltage to a desired transparent electrode and a metal electrode, a minute area portion sandwiched between intersections of both electrodes emits light, and , One symbol for displaying symbols, patterns, and the like.

The thin film E based on the structure shown in FIG.
The L panel 11 is used for the purpose of stabilizing a change with time in light emission luminance and the like, and removing a defective element due to an initial failure.
It is necessary to perform the aging process while applying an AC voltage between the transparent electrode group 2 and the metal electrode group 6 for a certain period after the production of the thin film EL panel.

As shown in FIG. 1, all of the transparent electrodes 2 are short-circuited, and every other metal electrode 6 is short-circuited to form two groups, ie, a first metal electrode group 6A and a second metal electrode group 6A.
And B are formed. Each of the electrode groups is connected to an aging drive circuit 10. The aging drive circuit 10 applies a voltage to each electrode group according to an operation described later.

FIG. 3 is a circuit diagram showing an example of the aging drive circuit 10. In FIG. 3, a capacitor ELA represents an odd-numbered metal electrode group, that is, a picture element of the EL panel 11 formed by the first metal electrode group 6A and the transparent electrode group 2, and a capacitor ELB represents an even-numbered metal electrode group. 5 shows a group, that is, a picture element of the EL panel 11 formed by the second metal electrode group 6 </ b> B and the transparent electrode group 2.

Each of the switching circuits TH1 to TH6 includes a thyristor, and includes a control signal S from a control circuit 9.
A thyristor control circuit that controls the thyristor to be turned on / off in response to 1 to S6 is included. The switching circuit TH1 is a circuit for applying a voltage (supplying a charge) to the first metal electrode group 6A, and the switching circuit TH2 is a circuit for grounding (discharging the charge) the first metal group 6A. The switching circuit TH3 is a circuit for applying a voltage to the second metal electrode group 6B.
H4 is a circuit for grounding the second metal electrode group 6B. The switching circuit TH5 is a circuit for applying a voltage to the transparent electrode group 2, and the switching circuit TH6 is a circuit for grounding the transparent electrode group 2.

In order to prevent a current (charge) from flowing backward, a diode D is connected with the switching circuits TH1 to TH6.
1 to D6 are connected respectively.

FIG. 4 is a timing chart illustrating the aging method of the EL panel according to the present invention. In the aging method of the present embodiment, as shown in FIG. 4A, the first and second periods T1 and T2 are repeated at a predetermined cycle.

In the first period T1, as shown in FIG. 4 (2), a first field F1 in which the picture element ELA emits light by applying a positive voltage to the transparent electrode 2, and a picture element ELA in which the And a second field F2 that emits light when a negative voltage is applied thereto, and these two fields F1 and F2 are repeated. The second period T2 is shown in FIG.
As shown in (2), the third field F3 where the picture element ELB emits light by applying a positive voltage to the transparent electrode 2
And a fourth field F4 in which the picture element ELB emits light when a negative voltage is applied to the transparent electrode 2, and these two fields F3 and F4 are repeated. Less than,
The operation of each field will be described.

FIG. 5 is a timing chart showing the operation of the aging drive circuit 10 during the first period T1.
FIGS. 5A to 5C show switching circuits TH1 to TH6.
5 (7) and 5 (8) show voltage waveforms applied to the picture elements ELA and ELB, respectively.

First Field F1 First, the switching circuits TH6 and TH3 formed of thyristors are turned on, and then the switching circuit TH1 is turned on.
As a result, the charges C _OFF and VD are applied to the picture elements ELA and ELB.
Is charged. FIG. 6A shows an equivalent circuit at this time. In this case, the charge C is applied to the picture elements ELA and ELB.
The current for charging _OFF / VD flows through the transparent electrode 2. The thyristor, which has a large driving capability as a switching element and can apply a steep waveform, is used. In the following, since the capacity of the picture element is about 2/5 or less of the case of a higher voltage,
Charge can be done in a short time.

Next, the switching circuits TH6 and TH3 are turned off, and the switching circuit TH4 is turned on to lower the metal electrode group 6B of the picture element ELB to 0V. FIG. 6 (2) shows an equivalent circuit at this time. As a result, the potential of the transparent electrode 2 becomes −α · VD due to the capacitor coupling between the picture elements ELA and ELB.
A voltage of (1 + α) · VD is applied to A. Since this voltage is equal to or higher than the light emission starting voltage, the picture element ELA emits light.

On the other hand, the voltage applied to the picture element ELB is α ·
VD, which is equal to or lower than the light emission starting voltage.
The picture element ELB does not emit light.

Here, assuming that the picture element capacity at the time of non-light emission is C _OFF and the picture element capacity at the time of light emission is C _ON , the constant α is expressed by Equation 1 as described above.

When the voltage VD is small and no light is emitted, α =
0.5 in the light emitting state. Assuming that the light emission start voltage of the picture element is Vth, the voltage VD is 2 · Vt
The picture element emits light when h / 3 or more.

In the state shown in FIG. 6B, since the switching circuit TH6 is in the OFF state, no current flows during the light emission of the picture element through the transparent electrode 2.

Second field F2 First, the switching circuits TH5 and TH4 formed of thyristors are turned on, and then the switching circuit TH2 is turned on.
As a result, the charges -C _OFF · are applied to the picture elements ELA and ELB.
VD is charged.

Next, the switching circuits TH5 and TH4 are turned off, the switching circuit TH3 is turned on, and the metal electrode group 6B of the picture element ELB is pulled up to the potential VD. As a result, the potential of the transparent electrode becomes (1 + α) · VD due to the capacitor coupling between the picture element ELA and the picture element ELB.
Therefore, − (1 + α) · VD is applied to the picture element ELA, and the picture element ELA emits light. On the other hand, the voltage applied to the picture element ELB is −α · VD, and the picture element ELB does not emit light.

As described above, in the first period T1, the first field F1 and the second field F2 are repeated, and the picture element E
LA continues to emit light due to sufficient polarization formation.
Since only a voltage lower than the light emission start voltage is applied to LB,
Does not emit light.

FIG. 7 is a timing chart showing the operation of the aging drive circuit 10 during the second period T2.
FIGS. 7 (1) to 7 (6) show switching circuits TH1 to TH6.
7 (7) and 7 (8) show voltage waveforms applied to the picture elements ELA and ELB, respectively.

Third Field F3 First, the switching circuits TH6 and TH1 constituted by thyristors are turned on, and then the switching circuit TH3 is turned on.
As a result, charges C _OFF and VD are applied to the pixels ELA and ELB.
Is charged.

Next, the switching circuits TH6 and TH1 are turned off, the switching circuit TH2 is turned on, and the metal electrode group 6A of the picture element ELA is lowered to 0V. As a result, the potential of the transparent electrode becomes −α · VD due to the capacitor coupling between the picture element ELA and the picture element ELB.
(1 + α) · VD is applied to LB, and since this voltage is equal to or higher than the light emission start voltage, the picture element ELB emits light. on the other hand,
The voltage applied to the picture element ELA is α · VD, and since this voltage is equal to or lower than the light emission start voltage, the picture element ELA does not emit light.

Fourth field F4 First, the switching circuits TH5 and TH2 constituted by thyristors are turned on, and then the switching circuit TH4 is turned on.
As a result, the charges -C _OFF · V are applied to the pixels ELA and ELB.
D is charged.

Next, the switching circuits TH5 and TH2 are turned off, the switching circuit TH1 is turned on, and the metal electrode group 6A of the picture element ELA is pulled up to VD.
Thereby, the potential of the transparent electrode is changed between the picture element ELA and the picture element EL.
The pixel ELB emits light because it becomes − (1 + α) · VD due to the capacitor coupling with B. On the other hand, the applied voltage of the picture element ELA is −α · VD, and the picture element ELA does not emit light.

As described above, in the second period T2, the third field F3 and the fourth field F4 are repeated, and the picture element ELB
Continues to emit light due to sufficient polarization formation, but the picture element ELA
Does not emit light because only a voltage lower than the light emission start voltage is applied.

The lengths of the first and second periods T1 and T2 are as follows:
Approximately 1 polarization change due to applied voltage change is completely stabilized
Seconds or more are sufficient.

As described above, according to the present embodiment, the light emission current for causing each picture element of the EL panel 11 to emit light is the first (second).
From the metal electrode group 6A (6B) through the transparent electrode group 2
(1) Since the current flows to the metal electrode group 6B (6A), the influence of the resistance of the transparent electrode group 2 can be sufficiently reduced. In addition, since a voltage pulse equal to or higher than the light emission start voltage is continuously applied to each picture element, the polarization in the EL light emitting layer is sufficiently formed, the light emission intensity is sufficiently obtained, and the aging processing time is reduced.

Therefore, the aging method described above has a great effect on the aging process of the thin-film EL panel 11, especially the large-sized large-capacity panel.

[0055]

As described above, according to the present invention, the emission current for emitting each picture element of the EL panel is changed from the first (second) metal electrode group to the second (first) metal electrode group via the transparent electrode group. Since the current flows through the metal electrode group, the influence of the resistance of the transparent electrode group can be sufficiently reduced. In addition, since a voltage pulse equal to or higher than the light emission start voltage is continuously applied, the polarization in the EL light emitting layer is also sufficiently formed,
A sufficient emission intensity can be obtained, which contributes to shortening of the aging processing time.

Therefore, the aging method of the present invention
This is particularly effective for aging treatment in the manufacturing process of L panels, especially large and large-capacity EL panels.

[Brief description of the drawings]

FIG. 1 is a plan view of an EL panel 11 to which an aging method for an EL panel according to an embodiment of the present invention is applied.

FIG. 2 is a perspective view showing the structure of the EL panel 11.

FIG. 3 is a circuit diagram showing a configuration of an aging drive circuit 10 shown in FIG.

FIG. 4 is a timing chart for explaining an aging method for an EL panel according to an embodiment of the present invention.

FIG. 5 is a timing chart for explaining an operation in a first period T1 in an aging method for an EL panel according to an embodiment of the present invention.

FIG. 6 is a circuit diagram showing an equivalent circuit of the aging drive circuit 10 shown in FIG.

FIG. 7 is a timing chart for explaining an operation in a second period T2 in the aging method of the EL panel according to one embodiment of the present invention.

FIG. 8 is a plan view for explaining a conventional EL panel aging method.

FIG. 9 is a circuit diagram showing an equivalent circuit of the EL panel.

FIG. 10 is a waveform diagram showing a voltage waveform applied to each picture element when a conventional aging method is used.

FIG. 11 is a timing chart for explaining a conventional aging method.

FIG. 12 is a waveform diagram showing a driving pulse of the EL panel.

13 is a graph showing voltage-luminance characteristics when an EL panel is driven by the driving pulse shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Glass substrate 2 Transparent electrode 3, 5 Dielectric material layer 4 EL light emitting layer 6 Metal electrode 10 Aging drive circuit 11 Thin film EL panel D1-D6 Diode ELA, ELB Capacitor (picture element) TH1-TH6 Switching circuit S1-S6 Control signal VD Applied voltage

Claims (1)

(57) [Claims] 1. An EL panel having an EL light emitting layer interposed between a transparent electrode group and a metal electrode group that intersect each other, all of the transparent electrode groups of the EL panel are short-circuited, and the metal electrode groups are alternately short-circuited. After the first and second metal electrode groups are formed by applying a voltage equal to or lower than the emission start voltage of the EL light emitting layer to the first and second metal electrode groups with the transparent electrode group as a reference potential, the transparent electrode group is brought into a floating state. A first field in which a voltage equal to or lower than the light emission start voltage is applied to the first metal electrode group with the second metal electrode group as a reference potential; and a second field in which the voltage equal to or lower than the light emission start voltage has a polarity opposite to that of the first field. A first period in which the field is repeated, and after applying a voltage equal to or lower than the emission start voltage of the EL light emitting layer to the first and second metal electrode groups with the transparent electrode group as a reference potential, the transparent electrode group is brought into a floating state; A third field in which a voltage equal to or lower than the emission start voltage is applied to the second metal electrode group using the first metal electrode group as a reference potential;
An aging method for an EL panel, comprising: setting a second period in which a field and a fourth field having the opposite polarity are repeated, and repeating the first period and the second period at a predetermined cycle.