JP2002072948A - Driving circuit for display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control brightness of a display device. SOLUTION: This display device driving circuit is provided with a battery as a power source, 8 driving transistor (14), a transformer (15), a display device (16) connected with a high voltage side (20, 22) of the transformer (15), a pulse oscillation circuit for generating a driving pulse, and a control circuit (10) receiving an output of the pulse oscillation circuit, and is characterized by that the collector of the transistor (14) is connected with the high potential side (17) of the battery, and the emitter is connected with the low potential side (21) of the transformer (15) or the collector of the driving transistor (14) is connected with the low potential side (19) of the battery, and the emitter is connected with the low potential side (21) of the transformer (15), and also the output terminal of the control circuit (10) is connected with the base of the driving transistor (14).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving circuit for a display device, and more particularly, to electroluminescence (hereinafter referred to as EL).
And a driving circuit for controlling the luminance of the EL of the display device.

[0002]

2. Description of the Related Art Since an EL consumes less current and emits light from a surface, it is often used as a backlight of a liquid crystal or the like of a small portable device using a battery as a power source. As a conventional EL driving circuit, a display device driving circuit as shown in FIG. 8 has been used.

In FIG. 8, an EL transformer (hereinafter referred to as ELT)
15) common terminal T1 (20) and secondary terminal T
3 (22), and connect EL16 to the common terminal T1.
(20) and the high-potential side Vbat (17) of the battery are connected via a brightness adjusting volume VR3 (42),
The collector of the driving transistor 14 is connected to the primary terminal T2 (21) of the ELT 15, the emitter of the driving transistor 14 is connected to the low potential side (GND) 19 of the battery,
The output terminal of the pulse oscillation circuit (not shown) is connected to the input terminal Pin (18) of the display device driving circuit, and the input terminal P
in (18) and the base of the driving transistor 14
4 (40), and the driving transistor 1
4 and GND 19 are connected via a resistor R5 (41).

As described above, in the conventional circuit configuration, the brightness adjusting volume Vbat (17) is connected between the high-potential side Vbat (17) of the battery and the collector of the driving transistor 14.
The low voltage side (common terminal T1 and primary terminal T2) of the ELT 15 is connected via R3 (42), and the driving transistor 14
The drive pulse generated by the pulse oscillation circuit is applied to the base of the ELT 15 to apply the driving pulse to the high voltage side of the ELT 15 (the common terminal T1 and the secondary terminal T1).
3) This is a common emitter system that generates a high voltage.
In this method, the brightness is controlled by adjusting the volume VR3 (42) connected in series to the LT15.

[0005]

However, in the above-mentioned conventional technique, the volume VR3 (42) and the ELT 15
Is a collector load of the driving transistor 14, and ELT
Since a current of several tens of mA flows through 15, the volume VR
3 (42) had to be used with a considerably large capacity, and was practically hardly used for reasons such as taking up space, high cost, and a shortened life.

[0006]

In order to solve the above problems, a display device driving circuit according to the present invention employs the following configuration.

A display device driving circuit according to the present invention uses a battery as a power source, a driving transistor, a transformer, a display device connected to a high voltage side of the transformer, a pulse oscillation circuit for generating a driving pulse, and a pulse oscillation circuit. A control circuit having an output terminal connected to the input terminal, the collector of the drive transistor being connected to the high potential side of the battery, the emitter of the drive transistor being connected to the low voltage side of the transformer, or the collector of the drive transistor being connected to The driving transistor is controlled by connecting to the low potential side of the battery, connecting the emitter of the driving transistor to the low voltage side of the transformer, and connecting the output terminal of the control circuit to the base of the driving transistor.

A display device driving circuit according to the present invention is characterized in that the control circuit includes at least one of a resistor, a volume, and a phototransistor for adjusting a driving pulse voltage generated by the pulse oscillation circuit.

In a display device driving circuit according to the present invention, the control circuit includes a volume, a first resistor, and a second resistor, and connects an output terminal of the pulse oscillation circuit to one terminal of the first resistor. The other terminal of the resistor 1 is connected to the first fixed terminal of the volume, the variable terminal of the volume is connected to the base of the drive transistor, and the second fixed terminal of the volume is connected to one terminal of the second resistor. The other terminal of the second resistor is grounded.

In the display device driving circuit according to the present invention, the control circuit includes a phototransistor and a resistor, the output terminal of the pulse oscillation circuit is connected to one terminal of the resistor, and the other terminal of the resistor is connected to one of the phototransistor. The terminal is connected to the base of the driving transistor, and the other terminal of the phototransistor is grounded.

In a display device driving circuit according to the present invention, the control circuit includes a phototransistor, a volume, a first resistor,
A second resistor; an output terminal of the pulse oscillation circuit;
, One terminal of the first resistor, one terminal of the phototransistor, and the first terminal of the volume.
, The variable terminal of the volume is connected to the base of the drive transistor, the second fixed terminal of the volume is connected to one terminal of the second resistor, and the other terminal of the phototransistor is connected to the second terminal. It is characterized in that the other terminal of the resistor is grounded.

In a display device driving circuit according to the present invention, the control circuit includes a phototransistor, a volume, a first resistor,
A second resistor; an output terminal of the pulse oscillation circuit;
One terminal of the resistor, the other terminal of the first resistor and the first fixed terminal of the volume, the variable terminal of the volume, one terminal of the phototransistor, and the base of the drive transistor, A second fixed terminal of the volume is connected to one terminal of the second resistor, and the other terminal of the second resistor and the other terminal of the phototransistor are grounded.

In a display device driving circuit according to the present invention, the control circuit includes a phototransistor, a transistor, a first volume, a second volume, a first resistor, and a second resistor. Connecting the high potential side to one terminal of the phototransistor, connecting the other terminal of the phototransistor to the first fixed terminal of the second volume, connecting the variable terminal of the second volume to the base of the transistor, Connecting the output terminal of the pulse oscillation circuit to one terminal of the first resistor, connecting the other terminal of the first resistor to the first fixed terminal of the first volume, and the collector of the transistor, Is connected to the base of the drive transistor, the second fixed terminal of the first volume is connected to one terminal of the second resistor, and the second fixed terminal of the second volume is Characterized by grounding the other terminal of the emitter and a second resistor of transistor.

In the display device driving circuit according to the present invention, the control circuit is a phototransistor, a transistor, a first volume, a second volume, a first resistor, a second resistor, and a third resistor. Connecting the high potential side of the battery to one terminal of the phototransistor, connecting the other terminal of the phototransistor to the first fixed terminal of the second volume, and connecting the variable terminal of the second volume to the transistor Connected to the output terminal of the pulse oscillation circuit and the first
One terminal of the first resistor, the other terminal of the first resistor, the first fixed terminal of the first volume, and one terminal of the third resistor, and the other terminal of the third resistor. And the collector of the transistor, the variable terminal of the first volume is connected to the base of the drive transistor, the second fixed terminal of the first volume is connected to one terminal of the second resistor, and the second The second fixed terminal of the volume, the emitter of the transistor, and the other terminal of the second resistor are grounded.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a display device driving circuit according to the present invention will be described below with reference to the drawings. FIG. 1 is a circuit configuration diagram of a display device driving circuit using the control circuit of the first embodiment of the present invention, FIG. 2 is a circuit configuration diagram of a second embodiment of the control circuit of the present invention, and FIG. FIG. 4 is a circuit configuration diagram of a control circuit according to a third embodiment of the present invention, FIG. 4 is a circuit configuration diagram of a fourth embodiment of the control circuit of the present invention, and FIG. FIG. 6 is a circuit configuration diagram of a control circuit according to a sixth embodiment of the present invention, and FIG. 7 is a graph showing experimental data of a display device driving circuit using the control circuit of the first embodiment. Hereinafter, description will be made with reference to FIGS. 1 to 7 as appropriate.

A display device driving circuit using the control circuit according to the first embodiment of the present invention will be described. In FIG. 1, a display device driving circuit includes a control circuit 10 including a first resistor R1 (11), a first volume VR1 (12), and a second resistor R2 (13), and an npn-type driving transistor (hereinafter, referred to as an npn-type driving transistor). The transistor is abbreviated as Tr) 14 and the ELT 15
, EL16, and a pulse oscillation circuit (not shown) for generating a drive pulse Vp. ELT1
5, the connection lines EL2 (24) and 2 of the common terminal T1 (20).
EL16 is connected to the connection line EL1 (23) of the next terminal T3 (22).
And a common terminal T1 (20) of the ELT 15
And the low potential side GND (19) of the battery. Collector of drive Tr14 and high potential side Vbat of battery
(17) to connect the emitter of the driving Tr14 to the ELT1.
5, the primary terminal T2 (21) is connected, and the base of the drive Tr 14 is connected to the output terminal Po (25) of the control circuit 10. An input terminal Pin (18) of the control circuit 10 which is also an output terminal of the pulse oscillation circuit and an input terminal of the display device driving circuit.
Connect. The input terminal Pin (18) and the first resistor R1
(11) is connected to the first resistor R1 (1
1) is connected to the first fixed terminal 30 of the first volume VR1 (12), and the first volume VR1
The variable terminal of (12) and the output terminal Po (2
5) and connect the second volume VR1 (12) to the second volume VR1 (12).
Is connected to one terminal of the second resistor R2 (13), and the other terminal of the second resistor R13 is connected to GND (1).
9) is connected.

The display device driving circuit shown in FIG. 1 uses the low voltage side of the ELT 15 (common terminal T1 and primary terminal T2) as a load between the low potential side GND (19) of the battery and the emitter of the npn type driving Tr14. And the collector of the driving Tr 14 is directly connected to the high-potential side Vbat (17) of the battery, and the output voltage of the emitter of the driving Tr 14 is substantially equal to the base input voltage. p
When an np-type drive Tr is used, the low-voltage side (common terminal T1 and primary terminal T2) of the ELT 15 is connected as a load between the high-potential side Vbat (17) of the battery and the emitter of the pnp-type drive Tr. , The collector of the pnp type driving Tr is directly connected to the low potential side GND (19) of the battery. That is, since the polarity of the power supply may be reversed, the case where the npn-type drive Tr 14 is used will be described here.

The drive Tr 14 is of a collector-grounded type, a drive pulse Vp is applied to the input terminal Pin (18) of the control circuit 10 connected to the output terminal of the pulse oscillation circuit, and the variable terminal of the volume VR1 (12) of the control circuit 10 is changed. To adjust the driving pulse V to the output terminal Po (25) of the control circuit 10.
When a control pulse in which the voltage peak value of p is changed is generated and the control pulse is input to the base of the driving Tr 14, the emitter output voltage of the driving Tr 14 becomes substantially equal to the control voltage. By changing the control voltage by changing the volume VR1 (12), the voltage generated on the high voltage side (common terminal T1 and secondary terminal T3) of the ELT 15 is changed,
The luminance of L16 can be changed.

Instead of using a brightness adjustment volume as a part of the load as a conventional emitter grounding method as in the prior art, a brightness adjustment first volume VR as a collector grounding method is used.
Since 1 (12) adjusts the input voltage of the base, a small-capacity volume can be used. Further, by using the collector grounding method, the input impedance of the base of the drive Tr 14 increases, and the first volume V
R1 (12) can be made a small volume with high resistance and lower capacity. The availability of low-volume volumes means less space, lower cost, and longer life.

In the circuit configuration of FIG. 1, a pulse oscillation circuit for generating a driving pulse Vp having a frequency of 3.3 kHz and a driving Tr1 are provided.
4, the npn-type 2SC3330Tr, the resistance value of the first resistor R1 (11) = 4.7 kΩ, the resistance value of the first volume VR1 (12) = 30 kΩ, and the second resistor R2
Using the resistance value of (13) = 4.7 kΩ, the first volume VR1 (12) is changed to change the power supply current (mA), EL
Voltage (Vrms), luminance (cd / m ² ) and the like were measured.

The results are plotted on the horizontal axis of FIG. 7 with the resistance value (the variable terminal and the second fixed terminal 31 of the first volume VR1 in FIG. 1).
(The resistance value of the sum of the resistance between the resistance and the second resistance). The brightness is controlled with a resistance value of 15 on the horizontal axis of the graph.
It was found from the curve of the luminance (cd / m ² ) 37 that it was possible with kΩ to 28.0 kΩ (MAX). It has been found that in order to control the luminance stably and proportionally, the resistance value on the horizontal axis should be 15 kΩ to 25 kΩ. The reason why the luminance is not low when the resistance value is 15 kΩ or less is that if the resistance value is less than 15 kΩ, the base voltage becomes low and the drive Tr 14 cannot operate, and the first resistor R1 (11) and the volume VR1
(12) The curve 37 can be shifted by changing each resistance value of the second resistor (13).

The EL voltage (Vrms) curve 36 is 3
The reason why the voltage waveform seems to be saturated at 2 Vrms is because the voltage waveform collapses, and the current waveform collapses when the voltage waveform collapses, and the power supply current (mA) increases when the power supply current (mA) increases. It can be seen from curve 35.

A control circuit according to a second embodiment of the present invention will be described. In FIG. 2, the control circuit 10 has a resistor R3 (2
6) and a phototransistor (hereinafter abbreviated as PTr) 2
7, the output terminal of the pulse oscillation circuit and the control circuit 10.
Input terminal Pin (18) is connected to the input terminal Pin
(18) is connected to one terminal of the resistor R3 (26), the other terminal of the resistor R3 (26) is connected to one terminal of the PTr 27 and the output terminal Po (25), and the other terminal of the PTr 27 is connected to a power supply. To the low potential side GND (19).

The PTr 27 has a very low resistance value when it is bright and a very low resistance value when it is dark. Therefore, FIG.
In the series circuit of the resistor R3 (26) and PTr27,
When bright, the resistance value of PTr27 becomes low, so that the drive pulse Vp of the input terminal Pin (18) is divided and becomes considerably small, and the output terminal Po (2) of the control circuit (10).
In 5), a control pulse having a low voltage peak value at which the drive Tr 14 cannot operate is generated and input to the base of the drive Tr 14. For this reason, the driving Tr 14 cannot be conducted, and no voltage is generated on the high voltage side of the ELT 15, so that the EL 16 is not turned on.

When dark, the resistance value of PTr 27 increases, and the drive pulse Vp of input terminal Pin (18) does not decrease even if the voltage is divided.
In 5), a control pulse having a high voltage peak value at which the drive Tr 14 can operate is generated and input to the base of the drive Tr 14. As a result, the drive Tr 14 becomes conductive and the ELT 15
, A high voltage is generated on the high voltage side, and the EL 16 is turned on.

As described above, when the PTr 27 is used, the EL 16 can be turned off when it is bright and turned on only when it is dark, so that the battery can last longer.

A control circuit according to a third embodiment of the present invention will be described. In FIG. 3, the control circuit 10 includes a first resistor R
1 (11), a first volume VR1 (12), a second resistor R2 (13), and a PTr 27, the output terminal of the pulse oscillation circuit and the input terminal Pin (18) of the control circuit 10.
And the input terminal Pin (18) and the first resistor R1
One terminal of (11) is connected, and the first resistor R1 (1
The other terminal of 1) is connected to one terminal of PTr 27 and the first fixed terminal 30 of the first volume VR1 (12), and the variable terminal of the first volume VR1 (12) is connected to the base of the drive Tr14. And the first volume VR1
The (12) second fixed terminal 31 and the second resistor R2 (1
3) One terminal is connected, and the other terminal of the PTr 27 and the other terminal of the second resistor R2 (13) are grounded.

The PTr 27 has a very low resistance value when it is bright, and has a very low resistance value when it is dark. Therefore, when bright, the resistance value of PTr27 decreases, and the resistance value of PTr27 and the first volume VR1 (1
Since the parallel combined resistance value of 2) and the resistance value of the sum of the second resistors R2 (13) is almost equal to the low resistance value of PTr27 and smaller than the first resistor R1 (11), the control circuit The drive pulse Vp input to the ten input terminals Pin (18) is divided and reduced, the potential of the first fixed terminal 30 of the first volume VR1 (12) becomes considerably low, and the first volume VR1 is reduced. At the output terminal Po (25) of the control circuit 10 connected to the variable terminal of (12), a control pulse having a low voltage peak value at which the drive Tr 14 cannot operate is generated and input to the base of the drive Tr 14. For this reason, the driving Tr 14 cannot be conducted, and no voltage is generated on the high voltage side of the ELT 15, so that the EL 16 is not turned on.

When dark, the resistance value of PTr27 increases, and the combined resistance value of the resistance value of PTr27 and the resistance value of the sum of the first resistor VR1 (12) and the second resistor R2 (13) connected in series is connected. Is the first volume VR1
Since the resistance value becomes almost equal to the sum of (12) and the second resistance R2 (13), the drive pulse Vp input to the input terminal Pin (18) of the control circuit 10 does not become too small even if the voltage is divided. The potential of the first fixed terminal 30 of the first volume VR1 (12) becomes considerably high, and the control circuit 1 connected to the variable terminal of the first volume VR1 (12)
0 at the output terminal Po (25), a control pulse having a high voltage peak value that allows the drive Tr 14 to operate sufficiently is generated.
14 is input to the base. As a result, the drive Tr 14 conducts, and a voltage is generated on the high voltage side of the ELT 15, and the EL 1
6 lights up. Here, the first volume VR1 (1
The brightness of the EL 16 can be changed by adjusting the variable terminal of 2) and changing the control pulse and inputting it to the base of the driving Tr 14.

With such a circuit configuration, the EL
16 can be turned off and on automatically, and
The brightness of the EL 16 at the time of lighting can be freely controlled manually.

A control circuit according to a fourth embodiment of the present invention will be described. In FIG. 4, the control circuit 10 includes a first resistor R
1 (11), a first volume VR1 (12), a second resistor R2 (13), and a PTr 27, the output terminal of the pulse oscillation circuit and the input terminal Pin (18) of the control circuit 10.
And the input terminal Pin (18) and the first resistor R1
One terminal of (11) is connected, and the first resistor R1 (1
1) and the first fixed terminal 30 of the first volume VR1 (12) is connected to the first volume VR1 (12).
(12) Variable terminal, one terminal of PTr27 and drive T
r14, connect the first volume VR1 (1
2) The second fixed terminal 31 is connected to one terminal of the second resistor R2 (13), and the other terminal of the PTr (27) is grounded to the other terminal of the second resistor R2 (13). I do.

The PTr 27 has a very low resistance value when it is bright and has a very low resistance value when it is dark. Therefore, when bright, the resistance value of PTr27 decreases, and the resistance value of PTr27 and the first volume VR1 (1
The parallel combined resistance of the resistance between the variable terminal of 2) and the second fixed terminal 31 and the resistance of the sum of the second resistance R2 (13) becomes almost equal to the low resistance of PTr27, Since the resistance value is smaller than the resistance value of the resistor R1 (11), the drive pulse Vp input to the input terminal Pin (18) of the control circuit 10 is divided and considerably reduced, and the control pulse connected to one terminal of the PTr 27 is controlled. The output terminal Po (2) of the circuit 10
In 5), a control pulse having a low voltage peak value at which the drive Tr 14 cannot operate is generated and input to the base of the drive Tr 14. For this reason, the driving Tr 14 cannot be conducted, and no voltage is generated on the high voltage side of the ELT 15, so that the EL 16 is not turned on.

When dark, the resistance of the PTr 27 increases, and the resistance of the PTr 27, the resistance between the variable terminal and the second fixed terminal 31 of the first volume VR1 (12) connected in series, and the second resistance R2 ( 13), the combined resistance value in parallel with the resistance value of the sum of the first volume VR1 (1)
Since the resistance value of the sum of the resistance between the variable terminal and the second fixed terminal 31 in (2) and the second resistance R2 (13) is equal to the resistance value, the drive pulse Vp of the input terminal Pin (18) is supplied to the control circuit 10.
Is not reduced even if the voltage is divided, and the first volume VR
At the output terminal Po (25) of the control circuit 10 connected to the variable terminal 1 (12), a control pulse having a high voltage peak value at which the drive Tr 14 can operate sufficiently is generated and input to the base of the drive Tr14. As a result, the drive Tr 14 becomes conductive, and E
A voltage is generated on the high voltage side of LT15, and EL16 is turned on. Here, the brightness of the EL 16 can be changed by adjusting the variable terminal of the first volume VR1 (12) to change the control pulse and inputting it to the base of the drive Tr (14).

With such a circuit configuration, the EL
It is possible to automatically turn off and turn on the EL 16, and furthermore, it is possible to manually control the brightness of the EL 16 when turned on.

A control circuit according to a fifth embodiment of the present invention will be described. In FIG. 5, the control circuit 10 includes a PTr 27
, Tr (Tr2) 28, and the first volume VR1
(12), the second volume VR2 (29), and the first volume VR2 (29).
And a second resistor R2 (13), and the high-potential side Vbat (17) of the battery and PTr
27 is connected to the other terminal of the PTr 27 and the first fixed terminal 32 of the second volume VR1 (29).
Is connected, the variable terminal of the second volume VR2 (29) is connected to the base of the Tr28, the output terminal of the pulse oscillation circuit is connected to one terminal of the first resistor R1 (11), and the first resistor is connected. The other terminal of R1 (11) is connected to the first fixed terminal 30 of the first volume VR1 (12) and the collector of Tr28, and the variable terminal of the first volume and the drive Tr are connected.
Connect the base of (14) to the first volume VR1
The (12) second fixed terminal 31 and the second resistor R2 (1
3) is connected to the second volume VR2.
The second fixed terminal 33 of (29), the emitter of Tr (28) and the other terminal of the second resistor R2 (13) are grounded.

When bright, the resistance value of PTr27 becomes low, and the second volume VR connected in series with PTr27.
2 (29), the potential of the first fixed terminal 32 increases, the potential of the variable terminal of the volume VR2 (29) also increases,
The base bias voltage of Tr28 rises and Tr28 becomes conductive. Therefore, the collector potential drops, and the potential of the first fixed terminal 30 of the first volume VR1 (12) also drops. Therefore, the output terminal Po (25) of the control circuit 10 connected to the variable terminal of the first volume VR1 (12)
The voltage peak value of the control pulse becomes smaller. Even if this control pulse is input to the base of the driving Tr14, the driving Tr1
No. 4 cannot operate, and therefore does not conduct. For this reason, ELT
No voltage is generated on the high voltage side of No. 15 and EL16 is not turned on. Further, by adjusting the second volume VR2 (29), it is possible to control how dark the lighting is not.

When dark, the resistance value of PTr27 increases, and the second volume VR2 connected in series with PTr27.
In (29), the potential of the first fixed terminal 32 decreases,
The potential of the variable terminal of the volume VR2 (29) also decreases, and the base bias voltage of the Tr (28) also decreases to T
r28 stops conducting. As a result, the collector potential increases, and the potential of the first fixed terminal 30 of the first volume VR1 (12) also increases. Therefore, the voltage peak value of the control pulse at the output terminal Po (25) of the control circuit 10 connected to the variable terminal of the first volume VR1 (12) also increases. When the control pulse is input to the base of the driving Tr 14, the driving Tr 14 can operate.
Conducts. A voltage is generated on the high voltage side of the ELT 15, and E
L16 lights up. In addition, the second volume VR2 (2
By adjusting 9), it is possible to control the brightness of the light.

By adjusting the variable terminal of the first volume VR1 (12), the luminance when the EL16 is turned on can be controlled. In addition, the second volume VR2 (2
9), as described above, how much light and dark
It is possible to control whether 16 is turned on or off.

A control circuit according to a sixth embodiment of the present invention will be described. In FIG. 6, the control circuit 10 includes a PTr 27
, Tr (Tr2) 28, and the first volume VR1
(12), the second volume VR2 (29), and the first volume VR2 (29).
, The second resistor R2 (13) and the third resistor R1 (11).
, And connects the high-potential side Vbat (17) of the battery to one terminal of PTr27,
The other terminal of the PTr 27 and the second volume VR1 (2
9), the first fixed terminal 32 is connected, the variable terminal of the second volume VR2 (29) is connected to the base of the Tr 28, the output terminal of the pulse oscillation circuit and the first resistor R1 (1) are connected.
1), the other terminal of the first resistor R1 (11), the first fixed terminal 30 of the first volume VR1 (12), and the collector of the Tr28 are connected to the third resistor R6.
(34), connects the variable terminal of the first volume and the base of the drive Tr (14), and connects the second fixed terminal 31 and the second resistor R of the first volume VR1 (12).
2 (13) is connected to the second volume V
The second fixed terminal 33 of R2 (29), the emitter of Tr (28), and the other terminal of the second resistor R2 (13) are grounded.

The control circuit of the sixth embodiment is composed of the collector of Tr28 and the first volume V of the control circuit of the fifth embodiment.
A third third connection between the first fixed terminal 30 of R1 (12) and
Since the circuit configuration of the other parts is the same as that of the fifth embodiment, detailed description is omitted. In the circuit configuration of the fifth embodiment, noise may occur at the first fixed terminal 30 depending on the position of the variable terminal of the first volume VR1 (12).
By providing the third resistor R6 (34) as in the sixth embodiment, generation of noise can be prevented.

[0041]

According to the present invention, the drive Tr for driving the ELT is of a grounded collector type, and the drive pulse input to the base of the drive Tr can be controlled by the first volume VR1 (12), so that a low-capacity volume can be used. , Space has become smaller, prices have become cheaper, and life has been extended.

By using the PTr 27, the EL 16 can be turned off when it is bright and turned on only when it is dark, so that the battery life can be extended.

By arranging the volume and the PTr 27 in parallel, it is possible to automatically switch between lighting and non-lighting of the EL 16 in a bright and dark state, and to manually control the brightness at the time of lighting.

By the volume and the configuration of PTr 27 and Tr 28, it is possible to control at what level of light and dark the EL 16 is turned on and off, and the brightness at the time of lighting can be controlled.

In the display device driving circuit of the present invention, the driving Tr
Although the npn-type transistor is used as (14), it is needless to say that a pnp-type transistor may be used without being limited to this.

In the display device driving circuit of the present invention, PTr2
Although 7 was used for detecting light and dark, it is a matter of course that other light detecting elements may be used without being limited to the PTr 27 in particular.

The ELT 15 according to the embodiment of the present invention includes:
The terminal is a common terminal T1 (20), a primary terminal T2 (21),
Although an example of a three-terminal single-winding transformer (so-called autotransformer) in which the low-voltage side and the high-voltage side of the secondary terminal T3 (22) are not separated has been described, the present invention is not limited to this. Of course, it can be applied to a general even-numbered terminal transformer whose side is separated.

As an embodiment of the present invention, a display device is an EL device.
Although the example using is described above, it is needless to say that a liquid crystal element or another display element can be used without being limited to this.

[Brief description of the drawings]

FIG. 1 is a circuit configuration diagram of an embodiment of a display device driving circuit using a control circuit according to a first example of the present invention.

FIG. 2 is a circuit configuration diagram of a second embodiment of the control circuit of the present invention.

FIG. 3 is a circuit configuration diagram of a third embodiment of the control circuit of the present invention.

FIG. 4 is a circuit configuration diagram of a fourth embodiment of the control circuit of the present invention.

FIG. 5 is a circuit configuration diagram of a fifth embodiment of the control circuit of the present invention.

FIG. 6 is a circuit diagram of a control circuit according to a sixth embodiment of the present invention.

FIG. 7 is a graph showing experimental data of a display device driving circuit using the control circuit according to the first embodiment of the present invention.

FIG. 8 is a circuit configuration diagram of a conventional display device driving circuit.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Control circuit 11 1st resistance 12 1st volume 13 2nd resistance 14 Drive transistor 15 ELT 16 EL 17 High potential side of battery 18 Input terminal of control circuit 19 Low potential side of battery 20 Common terminal of ELT 21 ELT Primary terminal 22 ELT secondary terminal 26 Resistance 27 Phototransistor 28 Transistor 29 Second volume 34 Third resistance 35 Power supply current (mA) 36 EL voltage (Vrms) 37 Luminance (cd / m ² )

Claims (8)

[Claims] 1. A power supply using a battery, a driving transistor, a transformer, a display device connected to a high voltage side of the transformer, a pulse oscillation circuit for generating a driving pulse, and an output terminal of the pulse oscillation circuit connected to an input terminal. The collector of the drive transistor is connected to the high potential side of the battery, and the emitter of the drive transistor is connected to the low voltage side of the transformer, or the collector of the drive transistor is connected to the low potential side of the battery. A display device driving circuit, wherein the driving transistor is controlled by connecting the emitter of the driving transistor to the low voltage side of the transformer and connecting the output terminal of the control circuit to the base of the driving transistor. 2. The display drive according to claim 1, wherein the control circuit includes at least one of a resistor, a volume, and a phototransistor for adjusting a drive pulse voltage generated by the pulse oscillation circuit. apparatus. 3. The control circuit includes a volume, a first resistor, and a second resistor. The control circuit connects an output terminal of the pulse oscillation circuit to one terminal of the first resistor. Connecting the other terminal to the first fixed terminal of the volume, connecting the variable terminal of the volume to the base of the drive transistor, connecting the second fixed terminal of the volume and one terminal of the second resistor, 3. The display device driving circuit according to claim 1, wherein the other terminal of the second resistor is grounded. 4. The control circuit includes a phototransistor and a resistor, connects an output terminal of the pulse oscillation circuit and one terminal of a resistor, and connects the other terminal of the resistor, one terminal of a phototransistor, and the drive 3. The display device driving circuit according to claim 1, wherein the base of the transistor is connected, and the other terminal of the phototransistor is grounded. 5. The control circuit includes a phototransistor, a volume, a first resistor, and a second resistor, and connects an output terminal of the pulse oscillation circuit to one terminal of the first resistor. Connecting the other terminal of the first resistor, one terminal of the phototransistor, and the first fixed terminal of the volume, connecting the variable terminal of the volume and the base of the drive transistor, and connecting the second fixed terminal of the volume. Second
3. The display device driving circuit according to claim 1, wherein one terminal of the first resistor is connected to the other terminal of the phototransistor, and the other terminal of the second resistor is grounded. 6. The control circuit includes a phototransistor, a volume, a first resistor, and a second resistor, and connects an output terminal of the pulse oscillation circuit to one terminal of the first resistor. Connecting the other terminal of the first resistor to the first fixed terminal of the volume, connecting the variable terminal of the volume, one terminal of the phototransistor and the base of the drive transistor, and connecting the second fixed terminal of the volume Second
3. The display drive circuit according to claim 1, wherein one terminal of the second resistor is connected, and the other terminal of the second resistor and the other terminal of the phototransistor are grounded. 7. The control circuit includes a phototransistor, a transistor, a first volume, a second volume, a first resistor, and a second resistor. Connecting one terminal of the phototransistor, connecting the other terminal of the phototransistor to the first fixed terminal of the second volume, connecting the variable terminal of the second volume to the base of the transistor, Is connected to one terminal of the first resistor, and the other terminal of the first resistor is connected to the first terminal of the first volume.
And a collector of the transistor, a variable terminal of the first volume is connected to the base of the driving transistor, and a second fixed terminal of the first volume is connected to one terminal of the second resistor. 3. The display device driving circuit according to claim 1, wherein the second fixed terminal of the second volume, the emitter of the transistor, and the other terminal of the second resistor are grounded. 8. The control circuit includes a phototransistor, a transistor, a first volume, a second volume, a first resistor, a second resistor, and a third resistor. Connect the high potential side of the battery to one terminal of the phototransistor, connect the other terminal of the phototransistor to the first fixed terminal of the second volume, and connect the variable terminal of the second volume to the base of the transistor An output terminal of the pulse oscillation circuit and one terminal of a first resistor are connected, and the other terminal of the first resistor, a first fixed terminal of the first volume, and one terminal of a third resistor. , The other terminal of the third resistor is connected to the collector of the transistor, the variable terminal of the first volume is connected to the base of the drive transistor, the second fixed terminal of the first volume is of Connect one terminal of the resistor and
3. The display device driving circuit according to claim 1, wherein the second fixed terminal of the volume, the emitter of the transistor, and the other terminal of the second resistor are grounded.