JP2000294370A - Electroluminescence driving device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep constant the luminous intensity of a plurality of electroluminescence elements. SOLUTION: A constant current I0 is supplied from a constant-current circuit in a power supply circuit 9 to a self-exciting inverter 7. The self-exciting inverter 7 is connected to a plurality of electroluminescence elements 11A to 11E via a switching circuit 6 having a plurality of switching elements 6A to 6E. A controller 10 adjusts the constant current I0 based on a plurality of on/off pattern data expressing relationships between a plurality of on/off patterns stored in a memory circuit LUT and set-up current values of the constant- current circuit, and causes the electroluminescence elements turned on to emit light at a constant intensity if their total luminous area varies by on/off controlling the switching elements 6A to 6E. If the electroluminescence elements 11A to 11E are deteriorated in their characteristics, they are excited with an alternating-current voltage for making up for the characteristic deterioration, and the effect of the characteristic deterioration is thereby suppressed and the luminous intensity is kept constant.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electroluminescence driving device for flashing a plurality of electroluminescence elements, and more particularly, to an electroluminescence driving apparatus for maintaining a constant light emission luminance when each of the electroluminescence elements is turned on. It concerns the device.

[0002]

2. Description of the Related Art Display means is known which enables information to be provided visually by selectively turning on or off a plurality of electroluminescent elements.

Conventionally, a plurality of electroluminescence elements have been selectively turned on or off by an electroluminescence driving device having a circuit configuration shown in FIG.

In FIG. 1, the electroluminescence driving device includes a switching circuit 2, a self-excited inverter 3, a controller 4 and a DC power supply 5, and receives an AC voltage from the self-excited inverter 3 via the switching circuit 2. It is configured to selectively apply to a plurality of electroluminescent elements (hereinafter, referred to as EL elements) 1A to 1E.

That is, the DC power supply 5 applies a predetermined constant drive voltage to the self-excited inverter 3, and the self-excited inverter 3 excites an AC voltage based on the drive voltage. The switching circuit 2 includes a plurality of EL elements 1A to 1A.
And a plurality of switching elements 2A to 2E corresponding to E. These switching elements 2A to 2E open and close independently (O) according to a control signal from the controller 4.
N / OFF) operation.

The switching elements 2A to 2E are selectively turned on by a control signal from the controller 4.
When operated, the AC voltage from the self-excited inverter 3 is applied to the EL element connected to the selected switching element among the EL elements 1A to 1E. As a result, only the EL elements to which the AC voltage is applied are selectively turned on according to the blinking pattern set by the control signal, and the EL elements connected to the non-selected switching elements are turned off according to the blinking pattern.

More specifically, the switching elements 2A to 2A are controlled by binary control signals CA to CE as shown in FIG.
2E is turned on / off, and the EL elements 1A to 1E are selectively turned on during a period in which the control signals CA to CE are at logic "H", and EL is turned on during a period in which the control signals CA to CE are at logic "L". The elements 1A to 1E were selectively turned off.

[0008]

However, according to the above-described conventional electroluminescence driving device, the EL
In some cases, the light emission luminance of the device was not kept constant. For example, when a plurality of EL elements having different light-emitting surfaces (hereinafter, referred to as light-emitting areas) are driven by the above-described conventional electroluminescence driving device, an EL element having a large light-emitting area and an EL element having a small light-emitting area are driven. In such a case, there is a problem that the light emission luminance is different and a screen having luminance unevenness or the like results. Further, when the number of EL elements that are simultaneously turned on (emit light) changes, there is a problem that the entire screen becomes brighter or darker depending on the number of EL elements that are turned on.

In general, an EL element can be equivalently regarded as a capacitance element (capacitor) because of its structural characteristics. Therefore, if the light emitting area of the EL element is different, its capacitance is naturally different. Self-excited inverter
Since the capacitance of the EL element self-oscillates as a part of the resonance circuit, the oscillation characteristic changes if the capacitance changes according to the light emitting area of the EL element. That is, as the light emitting area of the EL element increases, the capacitance increases and the impedance decreases. As a result, the self-excited oscillation frequency decreases, and the output voltage (AC voltage applied to the EL element) decreases. As a result, the emission luminance of the EL element is reduced.

Due to such characteristics, for example, based on rectangular wave control signals CA to CE as shown in FIG. 4, EL elements 1A to 1E having different light emitting areas are turned on and off in one or two or more combinations. In this case, the total light emitting area TA that is turned on
Since R changes at the timings T1 to T5, the emission luminance fluctuates, causing a problem that image unevenness and flicker occur.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-mentioned problems of the prior art, and it is an electro-optical device capable of maintaining a constant luminous luminance even when the total luminous area of an EL element changes due to a blinking pattern. It is an object to provide a luminescence driving device.

[0012]

According to the present invention, there is provided an electroluminescence driving apparatus for emitting a plurality of electroluminescent elements by applying an AC voltage, wherein each of the plurality of electroluminescent elements is provided. At the time of arbitrarily turning on or off, a configuration is provided in which a control circuit for controlling light emission luminance of one or more of the electroluminescent elements to be turned on is provided.

In addition, the AC voltage is generated by supplying power from a power supply circuit having a constant current circuit to a self-excited inverter, and the set current of the constant current circuit is automatically controlled, so that the plurality of electronic devices are controlled. The light emission luminance of the luminescence element was kept constant.

According to this configuration, the light emission luminance of the electroluminescent element becomes constant under the control of the control circuit. That is, even when the total light emitting area of the electroluminescent element changes, for example, when a plurality of electroluminescent elements having different light emitting surface areas emit light in one or two or more combinations, the electroluminescent element becomes the light emitting state. The light emission luminance of the device is always kept constant.

[0015]

FIG. 1 is a block diagram showing an embodiment of the present invention.
This will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of the electroluminescence driving device 12 according to the present embodiment.

Referring to FIG. 1, the electroluminescence driving device 12 includes a switching circuit 6, a self-excited inverter 7, a DC power supply 8, a power supply circuit 9, and a controller 10.

Here, the DC power supply 8 applies a constant voltage Vcc to the power supply circuit 9. The power supply circuit 9 has a built-in constant current circuit (not shown) for variably adjusting a set current value in accordance with a control signal Sc from a controller 10. The current I ₀ is supplied as supply power.

The self-excited inverter 7, by self-oscillation based on the constant current I _0, it generates an AC voltage V _D of the self-oscillation frequency.

The switching circuit 6 has a plurality (arbitrary number) of switching elements 6A to 6E connected to the plurality of EL elements 11A to 11E to be driven. 6E are independently opened and closed (ON / OFF) in accordance with control signals SA to SE from the controller 10. The inputs of the switching elements 6A to 6E and the output of the self-excited inverter 7 are commonly connected.

The controller 10 has a storage circuit LUT formed of a read only memory (ROM) or the like. The storage circuit LUT has a plurality of blinking patterns (switching elements 6A to 6E) set by the control signals SA to SE.
And a plurality of blinking pattern data indicating the relationship between the current value and the set current value of the constant current circuit. These blinking pattern data are set in advance by experiments, and are used to keep the emission luminance of the EL elements 11A to 11E constant for all of one or more combinations of the plurality of EL elements 11A to 11E. It is set as a set current value.

For example, the total light emitting area when the EL elements 11A and 11B emit light and the EL elements 11A, 11B and 1
When the total light emission area when 1C emits light is different, the light emission luminance of the combination of the EL elements 11A and 11B and the light emission luminance of the combination of the EL elements 11A, 11B and 11C are kept constant. data of the set current value of the constant current I ₀ in the combination is stored as blinking pattern data. Similarly, for each of one or two or more combinations of the plurality of EL elements 11A to 11E, the data of the set current value for keeping the emission luminance of the EL elements 11A to 11E constant at all times is represented by each combination. It is stored as blinking pattern data every time.

Then, the controller 10 outputs a control signal S
The flash pattern data in the storage circuit LUT is accessed based on the flash pattern set by A to SE.
By transferring one blinking pattern data obtained as a control signal Sc to the power supply circuit 9,
The L element 11A~11E always to output the constant current I ₀ to emit light at a constant luminance.

Next, the function and operation of the electroluminescence driving device 12 having such a configuration will be described.

Generally, the EL element has a characteristic that the higher the voltage value of the applied voltage or the frequency of the applied voltage, the higher the light emission luminance.

Further, the EL element has a characteristic that it changes over time as the lighting time becomes longer, and the light emission luminance decreases. Further, in the case of aging, the emission luminance is reduced even if a voltage having the same voltage value and frequency as before the aging is applied.

Further, the EL element has such a characteristic that its capacitance decreases and its impedance rises with aging.

By focusing on these electrical characteristics, the electroluminescence driving device 12 of the present invention and the present embodiment suppresses a decrease in light emission luminance when the EL element changes over time.

That is, when the self-excited inverter is operated at a constant voltage as in the prior art, the light emission luminance gradually decreases in accordance with the change in the electrical characteristics of each EL element over time. become.

[0029] However, according to the present electroluminescent drive 12, for driving the EL element 11A~11E in self-excited inverter 7 which operates by the constant current I _0, the EL element 11A~11E even if ages The characteristics of the self-excited inverter 7 automatically change so as to keep the emission luminance of the EL elements 11A to 11E constant. Specifically, when the capacitance of the EL elements 11A to 11E decreases due to aging, the oscillation frequency of the self-excited inverter 7 increases. When the impedance of the EL elements 11A to 11E increases due to aging, the self-excited inverter 7 increases. the voltage value of the AC voltage V _D generated by the inverter 7 is increased.

The characteristics of this manner, when the frequency and voltage value of the AC voltage V _D which along with the aging of the EL element 11A~11E generated by self-excited inverter 7 rises, the EL element 11A~11E Since the deterioration (decrease in light emission luminance) is compensated for, the light emission luminance of the EL elements 11A to 11E can be kept constant.

In particular, since the self-excited inverter 7 operates by supplying the constant current I ₀ , the above-described effect of suppressing the decrease in light emission luminance is improved. That is, EL
When the characteristics of the elements 11A to 11E deteriorate, the EL element 11
The impedance of A to 11E increases, and the load viewed from the self-excited inverter 7 decreases. In addition, the current consumption of the self-excited inverter 7 is reduced. At this time, the self-excited inverter 7 outputs the constant current I ₀ supplied through the constant current circuit.
, The power supply voltage of the self-excited inverter 7 rises in order to allow a constant current to flow.
The voltage value of the AC voltage V _D which is excited by the self-excited inverter 7 also increases, and thus act to increase the luminous intensity of the EL element 1 IA to.

As described above, according to the electroluminescence driving device 12 of the present embodiment, the self-excited inverter 7 is supplied to the self-excited inverter 7 in accordance with the combination of the EL elements 11A to 11E based on the blinking pattern data stored in the storage circuit LUT in advance. because automatically adjust the set current value of the constant current I _0, it is possible to maintain the emission luminance of EL elements 11A~11E constant.

Furthermore, even EL element 11A~11E is changed over time, since the AC voltage V _D to obtain supplement the characteristic deterioration of the EL element 11A~11E is excited by self-excited inverter 7, E
Without being affected by the characteristic deterioration of the L elements 11A to 11E, the EL element 11A
The emission brightness of ~ 11E can be kept constant.

In this embodiment, the case has been described in which the purpose is to keep the emission brightness of the plurality of EL elements 11A to 11E constant even if the blinking pattern changes variously. Even when the light emission luminance is changed, the light emission luminance after the change can be maintained at an appropriate luminance.

[0035]

As described above, according to the present invention, when a plurality of electroluminescent elements are driven to blink, the luminous brightness varies due to a difference in the total luminous area of the lit electroluminescent elements or deterioration of characteristics. The light emission luminance can be kept constant.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an electroluminescence driving device according to an embodiment.

FIG. 2 is a block diagram showing a configuration of a conventional electroluminescence driving device.

FIG. 3 is a timing chart for explaining a problem of a conventional electroluminescence driving device.

FIG. 4 is a timing chart for explaining a problem of the conventional electroluminescence driving device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 6 ... Switching circuit 6A-6E ... Switching element 7 ... Self-excited inverter 8 ... DC power supply 9 ... Power supply circuit 10 ... Controller 11A-11E ... Electroluminescence element 12 ... Electroluminescence drive device LUT ... Storage circuit

Claims (6)

[Claims] 1. An electroluminescence driving device for emitting a plurality of electroluminescence elements by applying an AC voltage, wherein at least one or more of the plurality of electroluminescence elements are turned on when each of the plurality of electroluminescence elements is turned on or off arbitrarily. An electroluminescence driving device comprising a control circuit for controlling the light emission luminance of the electroluminescence element. 2. The control circuit according to claim 1, wherein the control circuit controls the lighting 1 or 2
2. The electroluminescence driving device according to claim 1, wherein the light emission luminance of the total light emission area of the electroluminescence element is controlled to be always constant. 3. The electroluminescence driving device according to claim 1, wherein the AC voltage is generated by a self-excited inverter. 4. A power supply circuit for supplying power to the self-excited inverter, wherein the control circuit automatically adjusts the power supplied from the power supply circuit to the self-excited inverter, thereby turning on or off the light. 4. The electroluminescence driving device according to claim 3, wherein the light emission luminance of two or more electroluminescence elements is controlled. 5. The power supply circuit includes a constant current circuit that supplies power supplied to the self-excited inverter as a constant current, and the control circuit varies a current set value of the constant current in the constant current circuit. The electroluminescence driving device according to claim 4, wherein the power supplied to the self-excited inverter is automatically adjusted by controlling. 6. The lighting device according to claim 1, wherein the control circuit is configured to control the lighting 1 or 2
A storage circuit that stores control data in which the relationship between the light emission luminance of the total light emission area in the above-described electroluminescence element and the power supplied from the power supply circuit to the self-excited inverter is stored, based on the control data. The electroluminescence driving device according to claim 4, wherein the power is automatically adjusted.