JPH0973282A - El display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simply constitute a circuit boosting with at least two steps by collecting electric charges and to stabilize modulation voltage without being affected by capacitor charges storage quantity. SOLUTION: In a EL display device which has scanning side drivers IC2, 3 and data side drivers IC4 and matrix-driving an EL display panel 1, a data voltage supplying circuit 7 is constituted with a capacitor 71 for collecting charges and switching elements 72, 73, the switching element 72 is turned off and the element 73 is turned on before driving light emission of an EL element, the EL element is charged by charges collected by the capacitor 71 for collecting charges, the switching element 72 is turned on and the element 73 is turned off at the time of driving light emission, and modulation voltage Vm is applied to the EL element. And the switching element 72 is turned off and the element 73 is turned on after driving light emission, charges charged in the EL element are collected to the capacitor 71 for collecting charges.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an EL display device including an EL display panel having an EL (electroluminescence) element that emits light in response to application of a voltage.

[0002]

2. Description of the Related Art Conventionally, there is a circuit shown in Japanese Patent Laid-Open No. 5-333815 as a circuit for driving the EL element to emit light.
In this device, EL elements are arranged in a matrix to form an EL display panel, and a scanning side driver IC and a data side driver IC are provided on the scanning side and the data side, respectively.
Then, the respective driver ICs apply drive voltage pulses having different polarities to the positive and negative fields to the EL element to emit light.

That is, in the positive field, the scan side driver IC outputs a voltage (Vr) corresponding to the EL drive voltage to the scan electrodes with the ground voltage (0 V) as the reference voltage, and the data side driver IC. , The ground voltage is output to the EL element that emits light, and the modulation voltage (denoted as Vm) is output to the data electrode to the EL element that does not emit light, and the voltage of the data electrode is grounded to the scan electrode to which the voltage of Vr is output. As a result, a voltage of Vr is applied to the EL element to cause it to emit light.

In the negative field, the scanning side driver IC outputs a voltage (-Vr + Vm) to the scanning electrodes with the ground voltage (0V) as the reference voltage, and the data driver IC outputs an EL element. Modulation voltage Vm
To the EL element which does not emit light, the ground voltage is output to the data electrode, and the voltage of the data electrode is used as the modulation voltage Vm for the scanning electrode to which the voltage of (-Vr + Vm) is output.
A voltage of -Vr is applied to the element to cause it to emit light.

[0005]

In the conventional driving method described above, the EL display panel is charged / discharged from the data side for each scanning line emission operation, resulting in an increase in driving power consumption per cycle. There's a problem. As a means for solving this problem, Japanese Patent Laid-Open No. 63-168998
The publication discloses that after the EL element emits light, the charge charged in the EL element is stored in a charge recovery capacitor and is reused at the next light emission to reduce the power consumption.

Specifically, as shown in FIG. 6, a data voltage supply circuit 7 for supplying the modulation voltage Vm to the data side driver IC 4 (reference numerals 4 and 7 are provided to correspond to the embodiment described later). The charge recovery capacitor 70
1, the switching elements 702 to 704 and the diodes 705 and 706, and Vm / 2 is used as the power supply voltage of these elements. The capacity of the charge recovery capacitor 701 is sufficiently larger than the charge capacity of the entire EL display panel, and it is assumed that the charge of Vm / 2 is charged in the initial state.

In the scanning line selection period for selecting a predetermined scanning line, the switching element 704 is first turned on and the voltage supplied to the data side driver IC is set to Vm / 2. Next, the switching element 702 is turned on, and the power supply voltage Vm /
Modulation voltage Vm obtained by adding Vm / 2 for capacitor charging to 2
Is supplied to the data side driver IC. At this time, in the positive field, the modulation voltage Vm is applied to the data electrode of the EL element that does not emit light, and in the negative field, the modulation voltage Vm is applied to the data electrode of the EL element that emits light.

After this, the switching elements 702, 704
Is turned off and 703 is turned on, and about half of the charge output from the data electrode via the data side driver IC 4 is recovered by the charge recovery capacitor 701 via the diode 705. The collected charges are consumed when the switching element 704 is turned on in the next scanning line selection period.
This operation is repeated until the final line.

According to this conventional structure, the power consumption can be reduced by the charge recovery by the charge recovery capacitor 701, but three switching elements and two diodes are required, and the structure and operation thereof. Is complicated. In addition, when the next scanning line is selected, the voltage obtained by adding the inter-terminal voltage of the charge recovery capacitor 701 and the power supply voltage is used as the modulation voltage. Therefore, the modulation voltage is affected by the capacitor charge accumulation amount, and the operation is performed. There is also the problem of instability.

As another conventional technique, Japanese Patent Laid-Open No. 60-
Japanese Patent No. 147990 discloses a structure in which both electrodes of one EL element are provided with capacitors for recovering charge to recover the charge charged in the EL element. When this is applied to a matrix display type EL display device, a capacitor for charge recovery is connected to each EL element, resulting in a problem that the configuration becomes very complicated.

The present invention has been made in view of the above problems, and it is a first object of the present invention to enable collection and reuse of charges charged in an EL element with a simple circuit configuration. A second object is to stably supply the modulation voltage without being affected by the capacitor charge accumulation amount when the modulation voltage is supplied.

[0012]

According to a first aspect of the present invention, a voltage switching circuit is provided in a power supply line between a power supply (81) and a data electrode drive circuit (4). (72), a connection point between the first switching means and the data electrode drive circuit, and a charge recovery capacitor (71) and a second switching means (73) provided in series between the grounds. are doing.

Then, by turning on and off the first and second switching means, the EL element is charged through the data electrode drive circuit by the charge collected in the charge collecting capacitor before the EL element is driven to emit light, Supplying the modulation voltage from the power supply to the data electrode drive circuit when the EL element is driven to emit light,
After the EL element is driven to emit light, the charge charged in the EL element is recovered by the charge recovery capacitor through the data electrode drive circuit.

Therefore, when driving the light emission, the modulation voltage is directly changed to E
Since the voltage is applied to the L element, it is not necessary to add the capacitor charge to the power supply voltage to create the modulation voltage, unlike the conventional one shown in FIG. 6, which simplifies the circuit configuration for that. By directly applying the modulation voltage, the modulation voltage can be stably supplied without being affected by the capacitor charge accumulation amount.

According to the second aspect of the invention, since the offset voltage (V ₀₁ ) is supplied to the scan electrode drive circuit in the positive field, the offset voltage and the charge recovery capacitor of the capacitor are collected before the light emission drive. The voltage difference between the terminals is applied to the EL element.
Since the voltage for light emission is applied to the element, the rising characteristics of the voltage applied to the EL element are improved, the emission brightness is improved, and the uneven brightness can be reduced.

According to the third aspect of the invention, since the offset voltage and the modulation voltage are obtained from one power source, the structure of the power source circuit can be simplified.
In the invention described in claim 4, since the modulation voltage is directly applied to the EL element at the time of driving the light emission, the modulation voltage can be stably supplied without being affected by the capacitor charge storage amount.

[0017]

FIG. 1 shows the overall structure of an EL display device showing an embodiment of the present invention. FIG. 2 shows a schematic cross-sectional configuration of the EL element. In FIG. 2, the EL element is a transparent electrode 1 formed by stacking on a glass substrate 101.
02, the first insulating layer 103, the light emitting layer 104, the second insulating layer 1
05, the back electrode 106, the transparent electrode 1
02, the EL element emits light by applying an alternating drive voltage pulse between the back electrode 106 and the back electrode 106. In this FIG.
Light is extracted from the glass substrate 101. If the back electrode 106 is a transparent electrode, light can be extracted from both upper and lower directions in the figure.

The EL display panel 1 shown in FIG. 1 is different from the structure shown in FIG. 2 in that a plurality of transparent electrodes 102 and back electrodes 106 are arranged in a matrix to form scanning electrodes and data electrodes, and matrix display is performed. Has been done. In particular,
The scan electrodes 201, 202, ..., And the even scan electrodes 301, 302, ... Are formed in the row direction, and the data electrodes 401, 402, 403 ,.

Scan electrodes 201, 301, 202, 30
, ... and the data electrodes 401, 402, 403 ,.
112, ... 121, .. Since the EL element is a capacitive element, it is represented by a capacitor symbol in the figure. To perform display driving of the EL display panel 1, scanning driver ICs 2 and 3 and a data driver IC 4 are provided.

The scan side driver IC 2 is a push-pull type drive circuit, and has odd scan electrodes 201, 202,
, Connected to the P-channel FETs 21a, 22a,.
And N-channel FETs 21b, 22b, ... And odd scan electrodes 201, 20 according to the output from the control circuit 20.
A scanning voltage is applied to 2,. In addition, FETs 21a, 2
A parasitic diode is formed in each of 1b, 22a, 22b, ... As shown in the drawing, and the scan electrode is set to a desired reference voltage.

The scanning side driver IC 3 has a similar structure and has a control circuit 30, P-channel FETs 31a, 32a, ... And N-channel FETs 31b, 32b, ... And supplies a scanning voltage to the even scanning electrodes 301, 302 ,. To do. Similarly, the data side driver IC 4 also has a control circuit 40, P channel FETs 41a, 42a, ... And N channel FETs.
Data electrodes 401, 40 having 41b, 42b, ...
A data voltage is supplied to 2, 403, ....

The scanning voltage is supplied from the scanning voltage supply circuits 5 and 6 to the scanning driver ICs 2 and 3. The scan voltage supply circuit 5 has switching elements 51 and 52, and supplies the write voltage Vr or the ground voltage to the positive voltage supply line L1 in the scan side driver ICs 2 and 3 according to the ON / OFF state thereof. The scanning voltage supply circuit 6 has switching elements 61 and 62, and the voltage (−Vr + Vm) or the offset voltage (V ₀₁ : the same as the modulation voltage Vm in the present embodiment, depending on the on / off state thereof, the Vm) will be supplied to the negative voltage supply line L2 in the scanning side driver ICs 2 and 3.

A data voltage is supplied from the data voltage supply circuit 7 to the data side driver IC 4. The data voltage supply circuit 7 applies a DC voltage (modulation voltage) to the P-channel FET source-side common line of the data-side driver IC 4.
Vm, and a ground voltage to the N-channel FET source-side common line. In the present embodiment, the data voltage supply circuit 7 includes a charge recovery capacitor 71 and switching elements 72 and 73. The capacity of the charge recovery capacitor 71 is sufficiently larger than the charge capacity of the entire EL display panel 1.

Next, the operation in the positive and negative fields in this embodiment will be described with reference to the timing chart shown in FIG. It is assumed that the charge recovery capacitor 71 is charged with Vm / 2, which is half the modulation voltage Vm, in the initial state. This is because the capacitor charge storage amount is Vm by repeating the following driving.
This is because it converges to / 2. In addition, it is assumed that the EL element is not charged with electric charges in the initial state. (Normal field) At the start of the operation of this normal field, the initialization operation is performed. That is, the switching elements 51 and 62 are turned on and the switching elements 52 and 61 are turned off. Further, the switching element 72 is turned off and 73 is turned on, and all P-channel FEs of the data side driver IC 4 are
Turn on T and bring all data electrodes to Vm / 2. By this initialization operation, a voltage of Vm / 2 is applied to each EL element.

After this, scanning of the first row is started. First,
The N-channel FET of the data-side driver IC4 connected to the data electrode of the EL element that emits light is turned on, the P-channel FET is turned off, and the P-side of the data-side driver IC4 connected to the data electrode of the EL element that does not emit light
Turn on the channel FET and turn off the N channel FET. At this time, the voltage of the data electrode of the EL element to emit light becomes 0V, and the voltage of Vm is applied to the EL element connected to the data electrode via the parasitic diode of the N-channel FET of the scan side driver IC. In addition, the voltage of the data electrode of the EL element that does not emit light remains Vm / 2.

Next, the P-channel FET 21 of the scan side driver IC 2 connected to the scan electrode 201 of the first row
The voltage of the scan electrode 201 is set to Vr by turning on a. At the same time, the switching element 72 is turned on and the switching element 73 is turned off to change the modulation voltage Vm to P of the data side driver IC 4.
The voltage is applied to the data electrode with the channel FET turned on, that is, the data electrode of the EL element that does not emit light.

At this time, (V
(r-Vm) voltage is applied, the EL element does not emit light, but the EL element for emitting light is applied with a voltage of Vr and emits light. FIG.
In the timing chart of, the P channel FET 41a of the data side driver IC4 is turned off and the N channel FET is
41b is turned on, the voltage of the data electrode 401 is set to 0V, the voltage of Vr is applied to the EL element 111, and the EL element 1
11 shows a state in which 11 is made to emit light.

After that, by turning off the P-channel FET 21a and turning on the N-channel FET 21b,
The electric charge accumulated in the EL element on the scanning electrode 201 is discharged. At this time, the switching element 72 is turned off and 73 is turned on to turn on the P-channel FET of the data-side driver IC 4 and the N-channel FET.
Half of the electric charge charged in the entire EL display panel 1 between the data electrode which is turned on is P of the data side driver IC4.
The charge is collected by the charge collecting capacitor 71 via the channel FET.

That is, as shown in FIG. 4, the modulation voltage V
By supplying m, a charging current flows between the data electrode in which the P-channel FET is turned on and the data electrode in which the N-channel FET is turned on as indicated by a solid arrow in the figure, and E
The L display panel 1 is charged, but at the time of charge recovery,
The discharge current flows as indicated by the dotted line in the figure, and the EL panel 1
The charge that is charged in the whole is collected by the charge collecting capacitor 71.

Since the charge capacity of the charge recovery capacitor 71 is sufficiently larger than that of the EL element, the inter-terminal voltage Vm / 2 hardly changes. Finally, all the P-channel FETs of the data side driver IC4 are turned on to set all the data side electrodes to Vm / 2. The operation after the scanning line in the second row is similar to that described above. In addition,
In the timing chart of FIG. 2, the P-channel FET 41 of the data-side driver IC4 is provided on the second scanning line.
By turning on a and turning off the N-channel FET 41b, the voltage of the data electrode 401 is set to Vm, and the EL element 1
A voltage of (Vr-Vm) is applied to the EL element 21 to
1 shows a state in which 1 is not emitted. (Negative field) The initializing operation is performed even when the operation of this negative field is started. That is, after performing the light emitting operation of all the rows in the positive field, the switching element 5
1, 62 are turned off, 52, 61 are turned on, all the scanning electrodes are dropped to the ground, and all N of the data side driver IC 4 are
The channel FET is turned on, all data electrodes are dropped to the ground, and the electric charges corresponding to about Vm / 2 accumulated in all the elements are discharged. As a result, the voltage of all data electrodes becomes 0V. Further, the switching element 72 is turned off and 73 is turned on to set the source voltage of the P-channel FET of the data side driver IC4 to Vm / 2.

After this, scanning of the first row is started. In this case, the N-channel FET of the data side driver IC4 connected to the data electrode of the EL element to emit light is turned off,
The data-side driver IC 4 connected to the data electrode of the EL element that turns on the P-channel FET and does not emit light
Turn off the P-channel FET and turn on the N-channel FET. At this time, the voltage of the data electrode of the EL element that emits light is Vm / 2, and the voltage of the data electrode of the EL element that does not emit light is 0V.

Next, the N-channel FET 21 of the scanning side driver IC 2 connected to the scanning electrode 201 of the first row
b is turned on to set the voltage of the scan electrode 201 to (-Vr + V
m). At the same time, the switching element 72 is turned on, 7
3 is turned off and the P-channel FET of the data side driver IC 4 is turned on (data electrode 401
Etc.) is applied with the modulation voltage Vm.

At this time, a voltage of Vr is applied to the EL element that emits light to emit light, and (V
A voltage of r-Vm) is applied and no light is emitted. After that, the P-channel FET 21a is turned on and the N-channel FET 21b is turned on.
Is turned off, the electric charge accumulated in the EL element on the scan electrode 201 is discharged. At this time, by turning off the switching element 72 and turning on 73, the entire EL display panel 1 is provided between the data electrode in which the P channel FET of the data side driver IC 4 is turned on and the data electrode in which the N channel FET is turned on. Half of the electric charge charged in the charge recovery capacitor C1 is recovered via the P channel FET of the data side driver IC4. Since the charge capacity of the charge recovery capacitor is sufficiently larger than that of the EL element,
The voltage Vm / 2 between the terminals hardly changes.

Finally, by turning on all N-channel FETs of the data side driver IC4, the voltage of all the data side electrodes becomes 0V. The operation after the scanning line in the second row is similar to that described above. By performing the driving as described above, the charges recovered by the charge recovery capacitor 71 are transferred to the data electrode 4 before the light emitting operation in the next scanning line.
It is used to bring the voltage of 01 to Vm / 2. Therefore,
Power consumption occurs only when the switching element 72 is turned on, and the amount of output charge from the power source Vm is 50% compared to the case where charge collection is not performed, that is, the power consumption is 50% compared to the conventional case.
Becomes

In this embodiment, the off voltage Vm is set in the scanning voltage supply circuits 6 and 7. In the conventional device, the voltage is set to the ground voltage, and the voltage Vr is applied to the scanning side driver ICs 2 and 3 in the positive field.
Is applied, the scanning side driver ICs 2 and 3 must secure the withstand voltage corresponding to the voltage. On the other hand, in the present embodiment, since the off voltage Vm is set, the voltage of (Vr-Vm) is applied to the scanning driver ICs 2 and 3 in both the positive and negative fields. Therefore, the withstand voltage of the scanning side driver ICs 2 and 3 can be made lower than that of the conventional one by the offset voltage, and the withstanding voltage of the scanning side driver ICs 2 and 3 can be reduced.

In the positive field, each EL element is initially charged to Vm / 2 by the initialization operation. Therefore, when the EL element is caused to emit light, the voltage applied to the EL element may be changed from Vm / 2 to Vr, so that the rising characteristic of the voltage applied to the EL element is higher than that in the case where initial charging is not performed. Can be good. As a result, the pulse width of the voltage applied to the EL element is widened, the brightness is improved, and the brightness unevenness can be reduced.

The offset voltage Vm is the modulation voltage V
However, in the configuration of the present embodiment, the offset voltage is the voltage V between the terminals of the capacitor.
If it is lower than m / 2, initial charging cannot be performed,
When performing the initial charging, the offset voltage needs to be higher than the inter-terminal voltage Vm / 2 of the capacitor. Also,
The initial charging may be performed similarly not only in the positive field but also in the negative field.

Next, the scanning voltage supply circuits 5, 6,
A specific configuration of the data voltage supply circuit 7 will be described. The configuration is shown in FIG. In FIG. 5, the charge recovery capacitor 71 and the switching elements 72 and 73 in the data voltage supply circuit 7 are omitted. The voltage supply circuits 5 to 7 have a first power supply 81 having a voltage of Vm and a second power supply 82 having a voltage of (Vr-Vm). The anode of the first power supply 81 and the cathode of the second power supply 82 are connected via a P-channel FET (first switching means) 84, and the second power supply 82
The anode of is grounded via an N-channel FET (second switching means) 83.

The P-channel FET 84 has an input terminal S
2 to coupling capacitor 85, input protection Zener diode 86, resistor 87, and filter circuit 8
A control signal is input via 8. A control signal is input to the N-channel FET 83 from the input terminal S1 via the filter circuit 89. In the positive field, a low level control signal is input to both the input terminals S1 and S2, the N-channel FET 83 turns off, and the P-channel F
ET84 turns on. At this time, the voltage Vm of the first power supply 81 is output from the cathode of the second power supply 82 to the negative voltage supply line L2 as an offset voltage, and the second power supply 82 is also supplied.
The voltage Vr (= Vr-Vm + Vm) is output from the anode of the positive voltage supply line L1.

Voltages Vm and 0V are supplied to the data side driver IC 4 from the anode and cathode of the first power supply 81, respectively. Therefore, the drive voltage in the positive field is created by the above voltage. Also, in the negative field,
High-level control signals are input to both the input terminals S1 and S2, the N-channel FET 83 is turned on, and the P-channel F
ET84 turns off.

As a result, the cathode of the second power supply 82 outputs the voltage (-Vr + Vm) to the negative voltage supply line L2, and the anode of the second power supply 82 outputs the ground voltage to the positive voltage supply line L1. To be done. Therefore, these voltages create a driving voltage in the negative field. In addition,
In the configuration shown in FIG. 5, a control signal for driving the scanning side driver IC is input to the scanning side driver ICs 2 and 3 via an isolation circuit (not shown) to perform line sequential scanning of the scanning side driver IC. . The isolation circuit has a role of performing level shift during signal transmission between circuits having different reference potentials and correctly transmitting logic.

Since the voltage supply circuits 5 to 7 are configured to obtain the offset voltage and the modulation voltage from the first power supply 81, the power supply circuit can be simplified. (Other Embodiments) The voltage applied to the scan electrodes is Vr, (-
Vr + Vm), 0V, the voltage applied to the data electrode is V
However, the voltage applied to the scan electrodes is, for example, (Vr-Vm / 2), (-Vr + V).
m / 2), the voltage applied to the data electrode is Vm / 2, -V
It may be m / 2.

Although the voltage applied to the data side is boosted in two steps, a plurality of charge recovery capacitors may be provided to increase the number of steps. In this case, the larger the number of stairs, the greater the effect of reducing power consumption. Further, the EL drive system is not limited to the field inversion drive system, and a field refresh drive system may be used.

Further, although the one in which the charge is collected from the data electrode side is shown, the charge may be similarly collected from the scan electrode side. Further, the scanning side driver IC
Although the one using FET for the output stage of 2, 3, 4 is shown,
A thyristor or a bipolar transistor may be used.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a configuration of an EL display device showing an embodiment of the present invention.

FIG. 2 is a schematic cross-sectional configuration diagram showing a configuration of an EL element.

FIG. 3 is a diagram showing a drive timing chart in the configuration of FIG.

FIG. 4 is an explanatory diagram for explaining charge recovery.

5 is a diagram showing specific configurations of voltage supply circuits 5 and 6 and a data voltage supply circuit 7. FIG.

FIG. 6 is a configuration diagram showing a conventional configuration of a data voltage supply circuit that performs charge recovery.

[Explanation of symbols]

1 ... EL display panel 2, 3 ... Scan side driver IC, 4
... Data side driver ICs 5, 6 ... Scan voltage supply circuit,
7 ... Data voltage supply circuit.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiroaki Himi 1-1-chome, Showa-cho, Kariya city, Aichi Nihon Denso Co., Ltd.

Claims (4)

[Claims] 1. A plurality of scan electrodes (201, 301, 20)
2, 302, ...) And a plurality of data electrodes (401, 40)
, 403 are arranged in rows and columns, and EL elements (111, 112, ... 1) are arranged at positions where the scan electrodes and the data electrodes intersect.
21, ..., and an EL display panel (1), and a scan electrode drive circuit (2, which sequentially applies a scan voltage to the plurality of scan electrodes with different polarities for positive and negative fields.
3), a data electrode drive circuit (4) for applying a data voltage to the plurality of data electrodes, and a voltage supply circuit for supplying the scan voltage and the data voltage to the scan electrode drive circuit and the data electrode drive circuit, respectively. In the EL display device including (5 to 7), wherein the EL element is selectively caused to emit light by the scanning voltage and the data voltage, the voltage supply circuit is configured to control the EL voltage in relation to the scanning voltage.
There is a circuit (7, 81) for supplying a modulation voltage (Vm) for causing the element to emit light or not emitting light to the data electrode driving circuit as one of the data voltages, and this circuit includes a power source (which outputs the modulation voltage. 81), a first switching means (72) provided on a power supply line between the power supply and the data electrode drive circuit, and a connection point between the first switching means and the data electrode drive circuit, A charge recovery capacitor (71) and a second switching means (7) provided in series between the grounds.
3) and driving the data electrode by the charge collected in the charge collecting capacitor by turning off the first switching means and turning on the second switching means before the EL element is driven to emit light. The EL element is charged via a circuit, and when the EL element is driven to emit light, the first switching means is turned on and the second switching means is turned off to apply the modulation voltage from the power source to the data electrode. After the EL element is driven to emit light, the first switching means is turned off and the second switching means is turned on, and a part of the electric charge charged in the EL element is supplied to the data electrode drive circuit. An EL display device, characterized in that the charge is recovered by the charge recovery capacitor via the. 2. The voltage supply circuit includes a circuit (5, 6) for supplying a positive scan voltage (Vr) and an offset voltage (V ₀₁ ) to the scan electrode drive circuit in the positive field. The scan electrode drive circuit sets the voltage of the scan electrode in the positive field to the offset voltage and outputs the positive scan voltage to the scan electrode when the EL element is driven to emit light. The EL display device according to claim 1. 3. The EL display device according to claim 2, wherein the modulation voltage and the offset voltage are output from the power supply. 4. A plurality of scan electrodes (201, 301, 20)
2, 302, ...) And a plurality of data electrodes (401, 40)
, 403 are arranged in rows and columns, and EL elements (111, 112, ... 1) are arranged at positions where the scan electrodes and the data electrodes intersect.
21, ..., and an EL display panel (1), and a scan electrode drive circuit (2, which sequentially applies a scan voltage to the plurality of scan electrodes with different polarities for positive and negative fields.
3) and a data electrode driving circuit (4) for applying a data voltage to the plurality of data electrodes, and an EL display device configured to selectively cause the EL element to emit light by the scanning voltage and the data voltage. In the above, a data voltage supply circuit (7) for supplying the data voltage to the data electrode drive circuit is provided, and the data voltage supply circuit is a modulation voltage for causing the EL element to emit light or not emit light in relation to the scanning voltage. (Vm)
Is supplied to the data electrode drive circuit as one of the data voltages, and a charge recovery capacitor (71) for recovering the charge charged in the EL element, and before the EL element is driven to emit light, The EL element is charged by the charge collected in the charge collecting capacitor via the data electrode driving circuit, and when the EL element is driven to emit light, the modulation voltage output from the power source (81) is directly output to the data. A switching means (72, 73) for supplying the electric charge to the EL element to the electrode drive circuit and, after the EL element is driven to emit light, recovering the electric charge charged in the EL element to the electric charge recovery capacitor via the data electrode drive circuit. EL display device characterized by: